JP6896414B2 - Range hood equipment and system kitchen - Google Patents

Description

The present disclosure relates to a range hood device and a system kitchen used in a kitchen such as a kitchen, and more particularly to a range hood device and a system kitchen equipped with a fan.

With the increase in airtightness of houses, a ventilation device called a microwave oven equipped with a fan for discharging hot air, steam or oily smoke generated during cooking in a kitchen to the outside has become widespread. Such a range hood has been proposed by, for example, Patent Document 1 (Japanese Patent Laid-Open No. 2013-137155), Patent Document 2 (Japanese Patent Laid-Open No. 2003-329249) and Patent Document 3 (Japanese Patent Laid-Open No. 4-68941). There is.

Japanese Unexamined Patent Publication No. 2013-137155 Japanese Unexamined Patent Publication No. 2003-329249 Jikkenhei 4-68941

In recent years, a means of incorporating a projection device such as a projector into a range hood and projecting an image on a projection surface around the range hood has been proposed. Since a projector generally uses a light source that generates a large amount of heat, when the projector is used, the projector itself is cooled in order to prevent the internal temperature from rising and causing thermal failure. When the projector is incorporated in the range hood, it is necessary to release the heat generated from the projector itself to the outside of the range hood, and it is desired to provide a means for that purpose.

An object of one aspect of this disclosure is to provide a range hood device and a system kitchen capable of cooling a projection unit built into a range hood.

The range hood device according to this disclosure includes a range hood main body installed above the cooking cooker, a fan having an action of sucking external air into the range hood main body, and a ventilation path for external air inside the range hood main body. It includes an installed image projection unit and a control unit that controls a range hood device, and the control unit is configured to operate a fan when the projection unit is turned on.

Preferably, the range hood device further comprises a temperature detection unit that detects the ambient temperature of the projection unit, and the control unit can change the suction amount of external air based on the ambient temperature when the projection unit is turned on. The operation of the fan is controlled so as to be.

Preferably, the temperature detector comprises a thermistor or thermostat.
Preferably, the control unit further controls the operation of the fan so that the suction amount of the external air becomes variable based on the heating amount by the cooking cooker when the projection unit is turned on.

Preferably, a motion detection unit configured to detect the movement of a person is further provided, and the control unit further controls a projection unit to turn on the power when the movement of the person is detected by the motion detection unit. To do.

Preferably, the motion detection unit includes a detection unit configured to detect the movement of the person based on the strength of the signal received from the terminal carried by the person.

Preferably, the range hood body has a housing, the range hood device further comprises an opening formed on the outer peripheral surface of the housing, and the fan draws external air into the range hood body through the opening. Includes a working opening fan.

Preferably, the range hood body has a housing, and the range hood device further includes an opening formed on the outer peripheral surface of the housing and a damper for changing the opening of the opening, and is a control unit. Controls the damper so that the opening is variable when the power is turned on in the projection unit.

According to other aspects of this disclosure, a system kitchen is provided that comprises a cooker and a range hood device as described above.

The above system kitchen further includes a recipe acquisition unit for acquiring cooking recipe data, and the cooking recipe data includes heating control data for changing the heating amount of the cooking cooker according to the progress of cooking, and cooking progress. The image projected by the projection unit includes the image data representing the cooking recipe, and includes an image according to the image data of the data of the cooking recipe.

According to this disclosure, it is possible to cool the projection unit incorporated in the microwave oven hood.

FIG. 5 is an external view of a system kitchen including the range hood device according to the first embodiment as viewed from the side. It is an external view which looked at the system kitchen of FIG. 1 from the front. It is a figure which shows the cross-sectional structure which follows the arrow line of FIG. It is an external view which looked at the range hood main body 1 from the outer peripheral surface 1a side. It is a block diagram which shows an example of the hardware composition of the range hood apparatus 100 which concerns on Embodiment 1. FIG. It is a schematic block diagram of the cooking apparatus 200 which concerns on Embodiment 1. FIG. It is a schematic block diagram of the terminal 400 which concerns on Embodiment 1. FIG. It is a flowchart of the process for controlling the ventilation fan 6 which concerns on Embodiment 1. FIG.

Hereinafter, each embodiment will be described in detail with reference to the drawings. The same or corresponding parts in the figure are designated by the same reference numerals, and the explanation is not repeated in principle.

[Embodiment 1]
(Structure of system kitchen)
FIG. 1 is an external view of a system kitchen including the range hood device according to the first embodiment as viewed from the side. FIG. 2 is an external view of the system kitchen of FIG. 1 as viewed from the front. With reference to FIGS. 1 and 2, the system kitchen includes a cooker cabinet with a cooker 2 and a stove hood device 100 with a stove hood body 1. The range hood main body 1 has a hood suction port formed on the lower side. The range hood main body 1 is installed so that the hood suction port is located above the cooking cooker 2. The cooker cabinet includes a cooker 200 that controls the cooker 2. The cooker cabinet and the range hood device 100 are arranged so as to be in contact with the wall surface 3a of the kitchen, and the upper surface of the range hood device 100 is in contact with the ceiling 3b.

The system kitchen may be an island type system kitchen arranged away from the wall surface 3a. Further, the range hood main body 1 is a type that is hung from the ceiling 3b, but is not limited to the hanging type. Further, the heating cooker 2 may be a gas stove, an IH (Induction Heating) or an oven range, or a combination thereof.

The range hood device 100 further includes a ventilation fan 6 to which a ventilation duct 7 is connected, a projector 5 which is an embodiment of the “projection unit”, and a control unit 10 for controlling the range hood device 100. The projector 5 is provided inside the range hood main body 1.

By driving the lamp, which is a light source, the projector 5 irradiates the projection surface 53 such as the wall surface 3a with the projected light 51 composed of the light emitted from the lamp according to the image data. As a result, the projected image 52 according to the image data is displayed on the projection surface 53. The projected image 52 may include a still image or a moving image (video).

The ventilation fan 6 has an action of sucking external air into the range hood main body 1. The ventilation fan 6 includes, for example, a centrifugal fan and the like. The suction portion of the ventilation fan 6 communicates with the ventilation path 111 (described later) and the inside 117 (described later) of the range hood main body 1, and the blowout portion is connected to the duct 7 side. The air sucked by the ventilation fan 6 is exhausted to the outside (more specifically, outdoors or outdoors) of the range hood device 100 through the duct 7.

Further, the outer peripheral surface of the housing of the range hood main body 1 is an outer peripheral surface 1c in contact with the wall surface 3a, an outer peripheral surface 1d opposite to the outer peripheral surface 1c, an outer peripheral surface 1b facing the ceiling 3b, and a surface facing the heating cooker 2. The outer peripheral surface 1a on the side opposite to the outer peripheral surface 1b, the outer peripheral surface 1e on the left side and the outer peripheral surface 1f on the right side when viewed from the front are included.

FIG. 3 is a diagram showing a cross-sectional structure according to the arrow line of FIG. FIG. 4 is an external view of the range hood main body 1 as viewed from the outer peripheral surface 1a side. With reference to FIG. 3, the range hood body 1 includes a projector 5 arranged inside 117 of the range hood body 1 and a temperature sensor 118 for measuring the ambient temperature of the projector 5. The temperature sensor 118 is an embodiment of a “temperature detection unit” that detects the ambient temperature of the projector 5. Further, the range hood main body 1 is provided with a human detection sensor 119 on the outer peripheral surface 1d. The temperature sensor 118 includes a thermistor or thermostat. The human detection sensor 119 is an embodiment of a “movement detection unit” configured to detect the movement of a person. The human detection sensor 119 is composed of, for example, a pyroelectric infrared sensor, and detects the movement of a person within a predetermined range from the system kitchen. The temperature sensor 118 may be provided inside the projector 5.

With reference to FIG. 4, the range hood device 100 includes a speaker 120 at the edge of the housing of the range hood main body 1. Further, the range hood device 100 includes a straightening vane 4 in association with the range hood main body 1. The ventilation path 111 is formed between the peripheral edge of the straightening vane 4 and the outer peripheral surface 1a of the range hood main body 1 corresponding to the annular air suction gap. This suction gap corresponds to the hood suction port and is formed to be narrow. As a result, when the ventilation fan 6 is operated, the air flowing from the heating cooker 2 side to the hood suction port hits the rectifying plate 4 and flows into the ventilation path 111 at high speed through the suction gap.

Further, the range hood device 100 has a window 112, an intake port 113, and an exhaust port 114 formed on the outer peripheral surface of the housing of the range hood main body 1. The window 112 is formed at a position where the projection light 51 from the projector 5 can be applied to the projection surface 53. The window 112 is formed of a material that allows the light of the projected light 51 to pass through.

The intake port 113 has an action of sucking external air into the inside 117 of the range hood main body 1. Specifically, the intake port 113 corresponds to an opening formed for taking in the air on the ceiling 3b side into the inside 117 of the range hood main body 1. The exhaust port 114 corresponds to an opening formed for exhausting the air inside 117 of the range hood main body 1 to the outside of the range hood main body 1. The range hood device 100 includes a filter 8, a fan 115, and a damper 115a in relation to the intake port 113. The filter 8 has a function of removing dust and the like from the air taken in from the intake port 113. The fan 115 and the damper 115a have a function of adjusting the amount of air (air volume) taken in from the intake port 113. Further, the range hood device 100 includes a fan 116 and a damper 116a having a function of adjusting the exhaust amount (air volume) from the exhaust port 114 in relation to the exhaust port 114. The fan 115 or the fan 116 is an embodiment of an "opening fan" provided in an opening formed on the outer peripheral surface of the housing of the range hood main body 1.

(Cooling the ambient air of the projector 5)
As a background of the embodiment, in general, when power is supplied (power is turned on), self-heating is generated in the projector, such as a lamp, peripheral mechanical parts, a power supply unit for lighting the lamp or displaying an image. Large parts are placed. Against this background, in order to ensure the quality of the image display, a means for cooling the projector itself is required.

In the first embodiment, for this cooling, the air around the projector 5 is forcibly convected by operating a fan. Due to the convection of the ambient air, heat is dissipated from the device surface of the projector 5 to the ambient air, and the projector 5 itself is cooled.

With reference to FIG. 3, when the ventilation fan 6 is operated, the air inside 117 flows in the direction toward the suction portion side of the ventilation fan 6. As a result, this air convection occurs around the projector 5, and the projector 5 can be cooled.

Further, when the ventilation fan 6 is operated, the vicinity of the exhaust port 114 becomes a negative pressure from the inside 117 due to the flow of the ventilated air, and the outside air from the intake port 113 is taken in and is directed toward the exhaust port 114. A flow path is formed. The projector 5 is installed at a place where this ventilation path can occur. This can result in greater air convection around the projector 5 and promote cooling of the projector 5.

Further, the range hood device 100 controls the operation of the fan 115 of the intake port 113 or the fan 116 of the exhaust port 114, and changes the flow rate of the outside air taken in from the intake port 113 toward the exhaust port 114. Specifically, the range hood device 100 adjusts the rotation speed (air volume) of the fan 115 and the fan 116 by changing the supply voltage to the fan motor, and is formed in the direction from the intake port 113 to the exhaust port 114. The amount of convective air in the ventilation path to be made is changed. Further, the range hood device 100 changes the degree of opening of the damper 115a of the intake port 113 or the damper 116a of the exhaust port 114, and changes the flow rate of the outside air taken in from the intake port 113 toward the exhaust port 114. Let me. Specifically, the range hood device 100 adjusts the opening degrees of the damper 115a and the damper 116a by changing the supply voltage to the damper motor, and in the ventilation path formed in the direction from the intake port 113 to the exhaust port 114. Change the amount of convective air. The range hood device 100 can adjust the degree of cooling of the projector 5 by changing the air flow rate in the ventilation path in this way.

(Hardware configuration of range hood device 100)
FIG. 5 is a block diagram showing an example of the hardware configuration of the range hood device 100 according to the first embodiment. With reference to FIG. 5, the range hood device 100 is composed of a control unit 10 having a CPU (Central Processing Unit) 11, a power supply unit 12 for supplying power to each unit, a temperature sensor 118, and a human detection sensor 119 as main components. Sensor I / F (abbreviation of Interface) 13, the first communication I / F14 for communicating with the cooking device 200, the second communication I / F15 for communicating with the terminal 400, and the range hood device 100. An operation unit 16 for receiving a user's operation on the device is provided.

Further, the range hood device 100 includes a ventilation fan 6, a fan 15, a fan 16, a fan / damper driver 18 for controlling the damper 15a and the damper 16a, and a projector for outputting control data including image data to the projector 5. It includes an I / F 19, a storage unit 20, a speaker I / F (Interface) 21 that outputs audio data for driving the speaker 120, and a display unit 22 for displaying information related to the operation of the range hood device 100.

The CPU 11 functions as a control unit that controls each unit of the range hood device 100 by reading and executing the program stored in the storage unit 20.

The storage unit 20 is realized by a RAM (Random Access Memory), a ROM (Read-Only Memory), a flash memory, or the like. The storage unit 20 stores a program executed by the CPU 11, data used by the CPU 11, and the like.

The fan damper driver 18 supplies a motor drive signal, which is a voltage signal, to a ventilation fan motor (not shown) of the ventilation fan 6 in accordance with a command from the CPU 11. The ventilation fan motor rotates according to the motor drive signal, and the ventilation fan 6 rotates in conjunction with this rotation.

The operation unit 16 includes, for example, a button, a switch, and the like. The operation unit 16 may include a button and a switch for receiving an operation on the ventilation fan 6.

The first communication I / F 14 wirelessly communicates with the cooking apparatus 200 via an antenna (not shown). As the wireless communication method, for example, AirPlay (registered trademark), Miracast (registered trademark) and the like are used. The communication method with the cooking apparatus 200 is not limited to wireless and may be wired. Moreover, the wireless communication method is not limited to AirPlay, Miracast, etc.

The second communication I / F 15 wirelessly communicates with the terminal 400 via an antenna (not shown). As the wireless communication method, Wi-Fi (registered trademark) or the like capable of transmitting image data is used, but the communication method is not limited to this.

Further, the fan / damper driver 18 controls the fan 115, the fan 116 or the damper 115a, the damper 116a in accordance with the command from the CPU 11. Specifically, the fan / damper driver 18 supplies a motor drive signal, which is a voltage signal, to the fan motors of the fan 115 and the fan 116, and the motors of the damper 115a and the damper 116a in accordance with a command from the CPU 11. The fan motors of the fan 115 and the fan 116 rotate according to the motor drive signal, and the fan 115 and the fan 116 rotate in conjunction with this rotation. Further, the motors of the damper 115a and the damper 116a rotate according to the motor drive signal, and the damper 115a and the damper 116a open and close in conjunction with this rotation.

(Hardware configuration of cooking apparatus 200)
FIG. 6 is a schematic configuration diagram of the cooking apparatus 200 according to the first embodiment. With reference to FIG. 6, the cooking apparatus 200 includes a CPU 20 for controlling the entire apparatus. Further, the cooking apparatus 200 includes a heating control unit 21, a storage unit 23, a display unit 24 such as a liquid crystal display or an LED, an operation unit 25, and a communication I / F 26 for communicating with the range hood device 100, which are connected to the CPU 20. And a speaker 27. The operation unit 25 includes switches, buttons, and the like for receiving user operations on the cooking apparatus 200. These switches and buttons include, for example, a heating power adjusting switch for adjusting the heating power of the cooking cooker 2.

When the cooking cooker 2 is, for example, a gas stove, combustion gas is supplied to the cooking cooker 2 via a gas solenoid valve (not shown). The heating cooker 2 is supplied with an amount of gas corresponding to the opening degree of the gas solenoid valve and burns (heats). The CPU 20 receives the operation content of the thermal power adjustment switch of the operation unit 16 and outputs a current signal according to the received operation content to the gas solenoid valve via the heating control unit 21. The opening degree of the gas solenoid valve is changed by the current supplied from the heating control unit 21. In this way, the CPU 20 changes the amount of combustion gas supplied to the cooking cooker 2, that is, the amount of heating (or the amount of heat generated) by the cooking cooker 2, according to the operation content of the heating power adjustment switch.

<Communication between the cooking device 200 and the microwave oven device 100>
The CPU 20 of the cooking apparatus 200 transmits a ventilation command for carrying out the ventilation operation to the range hood apparatus 100 via the first communication I / F14. The ventilation command includes a ventilation start command instructing the start of the ventilation operation and a ventilation end command instructing the end of the ventilation operation.

Further, the CPU 20 generates thermal power data indicating the amount of heating by the heating cooker 2 based on the operation content of the thermal power adjustment switch, and transmits the thermal power data to the range hood device 100 via the first communication I / F14.

(Hardware configuration of terminal 400)
FIG. 7 is a schematic configuration diagram of the terminal 400 according to the first embodiment. With reference to FIG. 7, the terminal 400 is an external server device (not shown) via a CPU 401, a touch screen 402, a camera 403, a memory 404, a button (operation unit) 405 for turning the power on / off, and a network NT. Alternatively, it includes a communication I / F 406, a speaker 407, and a memory I / F 408 for communicating with the range hood device 100.

The memory I / F 408 corresponds to a memory driver that reads and writes data from a memory card 409 that is detachably attached from the outside. Here, the type of storage medium to be mounted is a memory card, but the present invention is not limited to this.

The touch screen 402 constitutes a display-integrated input device composed of a display 410 and a touch panel (tablet) 411.

The memory 404 is realized by various RAMs, ROMs, flash memories, hard disks, and the like. The memory 404 stores various programs executed by the CPU 401 and various data read by the CPU 401. The CPU 401 executes various information processing and the like by executing various programs stored in the memory 404.

(Control of projector 5)
The terminal 400 transmits the image data for projection by the projector 5 and the projection command to the range hood device 100 via the communication I / F 406. The projection command includes a projection start command for instructing the start of projection according to the image data by turning on the power of the projector 5 (turning on the power) and a projection end command for instructing the end of projection by turning off the power of the projector 5. .. Further, the terminal 400 transmits voice data to the range hood device 100 via the communication I / F 406. The projector 5 supplies electric power to each part in accordance with a projection start command from the terminal 400, turns on a lamp, and starts projection. Further, the projector 5 turns off the lamp according to the projection end command from the terminal 400, stops the supply of electric power to each part, and ends the projection.

The image data or audio data transmitted by the terminal 400 to the range hood device 100 includes image data or audio data received by the terminal 400 from an external server via the network NT.

The range hood device 100 receives the image data, the voice data, and the projection command from the terminal 400 via the second communication I / F15. The CPU 11 of the range hood device 100 generates the received image data and control data including the projection command, and outputs the control data to the projector 5 via the projector I / F19. The projector 5 starts or ends the projection according to the image data based on the control data from the CPU 11. Further, when the CPU 11 receives the voice data from the terminal 400, the CPU 11 outputs the voice data to the speaker I / F 21. The speaker I / F 21 controls the speaker 120 according to the voice data. As a result, sound is output from the speaker 120. The projection command may follow the operation content received from the operation unit 16 of the range hood device 100.

The image data projected by the projector 5 is not limited to the image data received from the server device via the terminal 400, and may be the image data captured by the camera 403 of the terminal 400. Alternatively, the image data of the storage unit 20 of the range hood device 100 or the image data received by the range hood device 100 from the cooking device 200 may be used.

The image data includes images of cooking recipes or images of switches, buttons, and the like for operating the cooking apparatus 200, but the types of images are not limited thereto.

(Processing flowchart)
FIG. 8 is a flowchart of a process for controlling the ventilation fan 6 according to the first embodiment. The program according to the flowchart of FIG. 8 is stored in the storage unit 20 of the range hood device 100. The processing shown in FIG. 8 is realized by the CPU 11 executing the program of the storage unit 20.

In the process of FIG. 8, the rotation speed of the ventilation fan 6 is switched between two stages of "high speed" and "low speed", but the number of switchable stages is not limited to two stages. Further, although the determination of the ambient temperature of the projector 5 is based on one type of threshold value as to whether or not it is "high temperature", it may be determined using a plurality of types of threshold values.

With reference to FIG. 8, first, the CPU 11 determines whether or not to turn on the power of the projector 5 (step S1). Specifically, the CPU 11 determines whether or not the projector 5 has turned on the power and started the projection (the lamp lights up and the projection starts) based on whether or not the projection start command is received from the terminal 400 (step). S1).

When the CPU 11 determines that the projector 5 is not turned on (NO in step S1), the CPU 11 repeats step S1.

When the CPU 11 determines that the projector 5 is powered on (YES in step S1), the CPU 11 outputs a command to the fan / damper driver 18 to drive the motor of the ventilation fan 6 (step S3). This command is, for example, a command to rotate the ventilation fan 6 at a'low speed'. As a result, the ventilation fan 6 starts operation at a low speed'.

When the operation of the ventilation fan 6 is started, the outside air is sucked into the range hood main body 1 through the ventilation path 111 as the fan rotates. With the suction of the outside air, the convection of air described above occurs around the projector 5 inside 117, and the projector 5 can be cooled.

The CPU 11 determines whether the rotation speed of the ventilation fan 6 is "high speed" or "low speed" (step S5). Specifically, the CPU 11 detects the voltage value of the motor drive signal output by the fan / damper driver 18, and if the detected voltage value is equal to or higher than the threshold value, determines that the speed is'high speed', and the voltage value is the threshold value. If it is less than, it is judged as'low speed'.

When the CPU 11 determines that the rotation speed of the ventilation fan 6 is'high speed'('high speed' in step S5), the CPU 11 compares the temperature detected from the temperature sensor 118 with the threshold value, and based on the comparison result. , It is determined whether or not the surroundings of the projector 5 are hot (step S12). When the CPU 11 determines that the surroundings of the projector 5 are hot (YES in step S12), the process proceeds to step S11 described later, but when it is determined that the surroundings of the projector 5 are not hot (NO in step S12), the CPU 11 is a ventilation fan. A command for lowering the rotation speed of No. 6 is output to the fan / damper driver 18 (step S13). After that, the process proceeds to step S11, which will be described later.

As a result, the ventilation fan 6 reduces the rotation speed in accordance with the above command from the CPU 11. Therefore, when the surroundings of the projector 5 are not hot, the rotation speed of the ventilation fan 6 is lowered to suppress the noise caused by the rotation and to continue the convection of the air around the projector 5 to cool the projector 5. It will be possible to continue to do so.

On the other hand, if it is determined that the rotation speed of the ventilation fan 6 is'low speed'('low speed' in step S5), the CPU 11 determines whether or not the surroundings of the projector 5 are hot, as in step S12. Determine (step S7).

When the CPU 11 determines that the surroundings of the projector 5 are not hot (NO in step S7), the CPU 11 proceeds to step S11.

On the other hand, when the CPU 11 determines that the surroundings of the projector 5 are hot (YES in step S7), the CPU 11 outputs a command for increasing the rotation speed of the ventilation fan 6 to the fan / damper driver 18 (step). S9).

The ventilation fan 6 increases the rotation speed in accordance with the above command from the CPU 11. As a result, the amount of outside air sucked into the range hood main body 1 through the ventilation path 111 increases, and the flow rate of the ambient air of the projector 5 increases accordingly, so that the projector 5 can be cooled.

In step S11, the CPU 11 determines whether or not to turn off the power (turn off the lamp and end the projection) based on whether or not the projection end command is received from the terminal 400 (step S11).

When the projector 5 does not determine that the power is turned off and the projection is finished (NO in step S11), the CPU 11 returns to step S5 and repeats the subsequent processing in the same manner as described above. When the CPU 11 determines that the projector 5 turns off the power and ends the projection (YES in step S11), the CPU 11 ends a series of processes.

In FIG. 8, when the power of the projector 5 is turned on, the ventilation fan 6 starts rotating, and thereafter, the rotation speed is switched according to the ambient temperature of the projector 5, but the ventilation fan 6 is switched according to the ambient temperature. May be switched between running and stopping. For example, when the power of the projector 5 is turned on and the ventilation fan 6 starts to rotate, if the temperature detected by the temperature sensor 118 is lower than a predetermined low temperature (low threshold value), the ventilation fan 6 is used for ventilation. The operation of the ventilation fan 6 may be restarted when the operation of the fan 6 is stopped and then the temperature detected by the temperature sensor 118 becomes equal to or higher than the low threshold temperature.

According to the first embodiment, the image of the cooking recipe displayed on the terminal 400 carried by the user can be projected on the projection surface 53 near the heating cooker 2 by the projector 5. Therefore, it is possible to eliminate the troublesomeness of the user of operating the terminal 400 by touching the ingredients being cooked (for example, a touch operation for displaying the cooking recipe on the touch screen 402), which is convenient. It becomes possible to provide a cooking environment.

[Embodiment 2]
The second embodiment shows a modification of the first embodiment. In the process of FIG. 8, the CPU 11 changes the rotation speed of the ventilation fan 6 based on the ambient temperature of the projector 5, but the change of the rotation speed is not limited to the method performed based on the ambient temperature of the projector 5.

In the second embodiment, for example, the CPU 11 changes the rotation speed of the ventilation fan 6 based on the heating amount indicated by the thermal power data received from the cooking cooker 2. In the second embodiment, the thermal power data is obtained in the'large'mode in which the amount of heat supplied by the cooker 2 is large, that is, the amount of heat generated by gas combustion is large, and the amount of heat supplied is small, that is, the amount of heat generated by gas combustion is small'. Includes two modes of'mode. The mode of thermal power data is not limited to these two types, and may be three or more types. When the heating cooker 2 is a high-frequency heating cooker, the heating amount can be changed based on the high-frequency current supplied to the heating coil of the high-frequency heating cooker.

In the second embodiment, the CPU 11 controls the ventilation fan 6 to rotate at a'high speed'when it is determined that the thermal power data indicates a'large mode'. As a result, it is possible to increase the amount of outside air sucked into the range hood main body 1 through the ventilation path 111, increase the flow rate of the air around the projector 5, and promote the cooling of the projector 5. ..

Further, when it is determined that the thermal power data indicates "small mode", the ventilation fan 6 is controlled to rotate at "low speed". As a result, it is possible to continue the convection of the air around the projector 5 and continue to cool the projector 5 while suppressing the noise caused by the rotation of the ventilation fan 6.

Further, also in the second embodiment, when the power of the projector 5 is turned on, the ventilation fan 6 starts to rotate, and after that, the ventilation fan 6 is operated or operated according to the heating amount indicated by the thermal power data of the heating cooker 2. The stop may be switched. For example, when there are three modes of thermal power data, "large mode", "small mode", and "minimal mode" in descending order of heating amount, the projector 5 turns on the power and the operation of the ventilation fan 6 starts. After that, when the thermal power data indicates'minimum mode', the CPU 11 suspends the operation of the ventilation fan 6, and then the thermal power data changes from'minimum mode'to'small mode'(or'large mode'). When the data shifts to, the operation of the ventilation fan 6 may be restarted.

The rotation speed of the ventilation fan 6 may be changed by combining the thermal power data of the heating cooker 2 and the ambient temperature of the projector 5 detected by the temperature sensor 118 shown in the first embodiment. ..

According to the first and second embodiments, the convection of air generated in the range hood main body 1 by ventilation using the ventilation fan 6, which is the original function of the range hood device 100, is utilized in the range hood main body 1. The installed projector 5 can be cooled. Therefore, a new cooling facility (new fan or the like) for cooling the projector 5 is unnecessary, and the cost can be reduced.

(Modified Example of Embodiment 2)
The system kitchen of each embodiment acquires a cooking recipe for automatic cooking and controls each part according to the acquired cooking recipe. As an example of the "recipe acquisition unit" for acquiring cooking recipe data, a means for receiving cooking recipe data transmitted from the terminal 400 by the second communication I / F15 of the range hood device 100, or a storage unit of the cooking device 200. The means for reading the cooking recipe stored in 23 and the like are included. The method of acquiring cooking recipe data is not limited to these means.

The cooking recipe data includes heating control data for changing the heating amount of the cooking cooker 2 according to the progress of cooking, and image data for showing the progress of the cooking. The CPU 20 of the cooking apparatus 200 adjusts the heating power of the cooking apparatus 2 via the heating control unit 21 according to the heating control data of the acquired cooking recipe data. Further, in this case, the CPU 20 transmits the thermal power data according to the heating control data to the range hood device 100. Therefore, the CPU 11 of the range hood device 100 can change the rotation speed of the ventilation fan 6 in conjunction with the progress of cooking by the cooking cooker 2 according to the cooking recipe.

Further, the CPU 10 of the range hood device 100 controls the projector 5 so as to project an image according to the image data of the acquired cooking recipe data. For example, an image showing the progress of cooking is projected on the projection surface 53. As a result, the user can grasp the progress of automatic cooking according to the cooking recipe from the projected image 52.

[Embodiment 3]
The third embodiment shows a modification of each of the above-described embodiments. In the third embodiment, the projector 5 is cooled by using the convection of the external air taken in from the intake port 113 in the direction of the exhaust port 114.

In the third embodiment, the CPU 11 determines the rotation speed (air volume) of the fan 115 of the intake port 113 or the fan 116 of the exhaust port 114, or the damper 115a or the damper 115a, based on the thermal power data of the heating cooker 2 or the detected temperature of the temperature sensor 118. The degree of opening of 116a is changed respectively. Specifically, when the CPU 11 outputs a command based on the detected temperature to the fan damper driver 18, the fan damper driver 18 outputs a motor drive signal according to the command to the fan 115, the fan motor of the fan 116, or the damper 115a, damper. It is supplied to the motor of 116a. As a result, the fan 115 and the fan 116 rotate at a speed according to the detected temperature. Further, the damper 115a and the damper 116a operate so as to have an opening degree according to the detected temperature.

Further, the rotation speed (air volume) of the fan 115 of the intake port 113 or the fan 116 of the exhaust port 114, or the degree of opening of the damper 115a or 116a can be controlled in combination with the rotation speed of the ventilation fan 6. ..

[Embodiment 4]
The fourth embodiment shows a modification of each of the above-described embodiments. In each of the above embodiments, the CPU 11 controls the power-on or power-off of the projector 5 based on the projection command, but the power-on or power-off of the projector 5 is performed by another method that does not depend on the projection command. May be good.

In the fourth embodiment, for example, the CPU 11 controls the projector 5 to turn on the power when the movement of a person is detected in the kitchen based on the output from the human detection sensor 119, and the movement of the person is moved to the kitchen. If it is not detected, the projector 5 is controlled so that the power is turned off.

Further, as the movement detection of a person, a method based on the reception intensity (unit: dB) of the radio wave from the terminal 400 received by the CPU 11 via the second communication I / F15 may be used. For example, when the CPU 11 detects the reception strength of the signal from the terminal 400 carried by the user and determines that the reception strength exceeds the threshold value (for example, the user carrying the terminal 400 has entered the kitchen), the CPU 11 determines that the reception strength exceeds the threshold value. , Control the projector 5 to turn on the power. Further, when it is determined that the reception intensity does not exceed the threshold value (that is, the user carrying the terminal 400 is not in the kitchen or has left), the projector 5 is controlled to turn off the power.

According to the fourth embodiment, the CPU 11 can control the projector 5 so that the power is turned on when it is detected that a person is present in the kitchen and the power is turned off when the person is not present. Therefore, the operation of each part (ventilation fan 6, fan 115 or fan 116, or damper 115a or 116a) for convection of ambient air for cooling the projector 5 is limited to the time when it is detected that there is a person in the kitchen. It becomes possible to carry out. This makes it possible to suppress noise caused by the operation of a fan or the like and reduce power consumption.

It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is shown not by the above description but by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

1 Range hood body, 1a, 1b, 1c, 1d, 1e, 1f outer peripheral surface, 2 cooker, 3a wall surface, 3b ceiling, 4 rectifying plate, 5 projector, 6 ventilation fan, 7 duct, 8 filter, 10 control Unit, 12 power supply unit, 16, 25 operation unit, 120 speaker, 18 fan / damper driver, 20, 23 storage unit, 21 heating control unit, 51 projected light, 52 projected image, 53 projection surface, 100 range hood device, 111 Ventilation path, 112 windows, 113 intake port, 114 exhaust port, 115,116 fan, 115a, 116a damper, 117 inside, 118 temperature sensor, 119 person detection sensor, 200 cooking device, 400 terminals.

Claims (10)

It ’s a range hood device,
The main body of the microwave oven installed above the cooking cooker and
Provided outside the range hood body, a fan having a suction effect of the external air into the hood body,
An image projection unit installed in the ventilation path of the external air in the range hood main body, and
A control unit for controlling the range hood device is provided.
The control unit is a range hood device configured to operate the fan when the projection unit is powered on. A temperature detection unit for detecting the ambient temperature of the projection unit is further provided.
The range hood according to claim 1, wherein the control unit controls the operation of the fan so that the suction amount of the external air becomes variable based on the ambient temperature when the projection unit is turned on. apparatus. The range hood device according to claim 2, wherein the temperature detection unit includes a thermistor or a thermostat. The control unit further controls the operation of the fan so that the suction amount of the external air becomes variable based on the heating amount by the heating cooker when the projection unit is turned on. The range hood device according to any one of 1 to 3. Further equipped with a motion detection unit configured to detect the movement of a person,
The range hood device according to any one of claims 1 to 4, wherein the control unit further controls the projection unit so as to turn on the power when the movement of the person is detected by the motion detection unit. .. The range hood device according to claim 5, wherein the motion detection unit includes a detection unit configured to detect the movement of the person based on the strength of a signal received from the terminal carried by the person. The range hood body has a housing and
The range hood device further
Further provided with an opening formed on the outer peripheral surface of the housing,
The range hood device according to any one of claims 1 to 6, wherein the fan includes an opening fan having an action of sucking external air into the range hood main body through the opening. The range hood body has a housing and
The range hood device further
An opening formed on the outer peripheral surface of the housing and
Further provided with a damper for changing the opening degree of the opening.
The range hood device according to any one of claims 1 to 7, wherein the control unit controls the damper so that the opening degree is variable when the projection unit is turned on. With the cooker
A system kitchen comprising the range hood device according to any one of claims 1 to 8. It also has a recipe acquisition department that acquires cooking recipe data.
The cooking recipe data includes heating control data for changing the heating amount of the cooking device according to the progress of cooking, and image data showing the progress of cooking.
The system kitchen according to claim 9, wherein the image projected by the projection unit includes an image according to the image data of the cooking recipe data.

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