JP5722715B2 - Cooker - Google Patents

Description

  The present invention relates to a cooking device that detects a spill of a heated object.

  In the related art, for example, “the electrode provided under the top plate and a capacitance measuring means for measuring a capacitance between the electrode and a predetermined potential, the control circuit includes: An induction heating cooker is proposed in which, when the capacitance between the electrode and a predetermined potential is increased above a predetermined value while the heating coil is being driven, it is determined that a spill has occurred. " (For example, refer to Patent Document 1).

  Further, for example, “the capacitance detecting unit spills on the top plate where the cooking object is connected to the reference potential, and moisture contained in the cooking object functions as a dielectric. A heating cooker is proposed that detects a change in the capacitance of the electrode by utilizing the fact that the connection between the electrode and the reference potential is increased by the increase in the amount of spillage of the object. (For example, refer to Patent Document 2).

JP 2008-159494 A (Claim 18) WO2010 / 084752 (Claim 1)

  However, in the conventional technology, since the electrodes are locally arranged near or around the heating means, even if spilling occurs where no electrodes are arranged, this cannot be detected. There was a point.

  Also, since the occurrence of spillage is detected by the capacitance of the electrode, is the material placed on the electrode water (contents) or a material with a different dielectric constant such as a pan or human body? I do not understand. For this reason, even when a pan is placed on the electrode, there is a problem in that the capacitance changes and erroneous detection of spillage occurs.

  Further, when water is spilled on the electrode, the detected capacitance value varies depending on the ratio of water to the electrode. For this reason, in the method of detecting spillage using the amount of change in capacitance, if the spread of water after spilling is gradual, the spillage cannot be detected, or the detection timing is delayed. There was a problem.

  The present invention has been made in order to solve the above-described problems, and provides a cooking device capable of improving the accuracy of detection of overflowing.

  The heating cooker according to the present invention is provided with a coating on the upper surface, a top plate on which the object to be heated is placed, and a heated object placed on the top plate, provided below the top plate. Heating means that detects the presence or absence of spillage from the heated object in a predetermined detection area on the top plate, and control means that controls the heating means based on the detection result of the spillage detection means And, in the coating provided on the top surface of the top plate, the density state of the content introduction region including at least the detection region is different from the surrounding coating, the content introduction region is the It is formed wider than the detection region.

  In the present invention, among the coatings provided on the top surface of the top plate, the density state of the content introduction region including at least the detection region is different from that of the surrounding coating, and the content introduction region is made wider than the detection region. Formed. For this reason, the detection accuracy of spilling can be improved.

FIG. 3 is a top view showing the heating cooker in the first embodiment. It is a cross-sectional conceptual diagram which shows the heating cooker in Embodiment 1. FIG. FIG. 3 is a configuration diagram of a spill detector in the first embodiment. It is the figure which showed the absorption spectrum of water. 4 is a transmission characteristic diagram of the top plate used in Embodiment 1. FIG. It is a permeation | transmission characteristic figure of a visible region cut-off coating material. FIG. 6 is an explanatory diagram of output when a spill is detected by a spill detector according to the first embodiment. This is the refractive index of a typical substance. It is a top view which shows the heating cooker in Embodiment 2. FIG. It is a top view which shows the heating cooker in Embodiment 3. It is a figure which shows the other shape of the slit part in Embodiment 3. FIG. It is a top view which shows the heating cooker in Embodiment 4. It is a figure which shows the other shape of the slit part in Embodiment 4. FIG. It is a figure which shows the shape of the slit part in Embodiment 5. FIG. It is a disassembled perspective view which shows the heating cooker in Embodiment 6. FIG. It is a cross-sectional conceptual diagram which shows the heating cooker in Embodiment 6. FIG.

Embodiment 1 FIG.
(overall structure)
In this embodiment, an IH cooking heater that performs induction heating will be described as an example of a cooking device.
FIG. 1 is a top view showing a heating cooker in the first embodiment.
FIG. 2 is a cross-sectional conceptual diagram showing the heating cooker in the first embodiment.
FIG. 3 is a block diagram of the overflow detection means in the first embodiment.
As shown in FIGS. 1 to 3, the induction heating cooker is provided on the main body 1, the top board 2 on which the heated object 11 such as a pan is placed, and below the top board 2. A heating coil 12 for heating the object to be heated 11 placed on the top plate 2, a drive unit 17 configured by an inverter circuit for supplying a high-frequency current to the heating coil 12 and driving the heating coil 12, The controller 16 that controls the operation of the drive unit 17 to control the input power (output) to the object 11 to be heated and the infrared rays emitted from the object 11 to be heated are detected, and the temperature of the pan is detected from the amount of infrared rays. Infrared temperature detection means 13, contact-type temperature detection means 14 that contacts the lower surface of the top plate 2 and detects the temperature of the top plate 2, an operation unit 3 that inputs an operation from a user, an operation state and an operation And a display unit 4 for displaying input / operation contents from the unit 3.
Further, below the top plate 2, a spill detection unit 7 that emits light toward a transmission part (described later) of the top plate 2 and detects reflected light incident from the transmission unit, and this spill detection unit 7. And a detection unit 15 that determines the occurrence of spillage of the contents from the object to be heated 11 based on the detection result. The details and arrangement position of the overflow detection means 7 will be described later.
Further, at the rear of the upper surface of the main body 1, there are an intake port 6 that communicates with the inside of the main body 1 and takes cooling air into the main body 1, and an exhaust port 5 that discharges cooling air taken inside the main body 1. Is provided.

The “operation unit 3” corresponds to “operation means” in the present invention.
The “heating coil 12” corresponds to the “heating means” in the present invention.
The “spillover detection means 7” and the “detection unit 15” correspond to the “spillover detection means” in the present invention.
The two heating coils 12 arranged on the front side of the main body 1 constitute a heating port having a relatively large heating output in which the inner coil and the outer coil are arranged concentrically. Further, the heating coil 12 disposed on the center rear side of the main body 1 constitutes a heating port having a relatively small heating output.
The present invention is not limited to this, and an arbitrary number of heating coils 12 can be arranged.
In addition, although this Embodiment demonstrates the induction heating cooking appliance which supplies a high frequency current to the heating coil 12, and performs induction heating, this invention is not limited to this. For example, an electric heater (for example, a nichrome wire, a halogen heater, or a radiant heater) using a radiant heat source that is heated by radiation may be used as the heating means.

(Configuration of the top plate 2)
The top plate 2 is made of a material such as heat-resistant glass such as Neoceram, and transmits light in a predetermined wavelength band.
On the bottom surface of the top plate 2, top plate bottom surface coatings 21a and 21b are applied by coating or printing.
The top plate lower surface coating 21a is for applying a coating that does not transmit visible light to hide the internal structure in order to hide the components in the main body 1 and improve the design.
The top plate lower surface coating 21b is formed at a position above the spill detector 7 and uses a paint having a high light transmittance in a predetermined wavelength band. The top plate lower surface coating 21b and the top plate 2 constitute a transmission part that transmits light of a predetermined wavelength. The wavelength will be described later.

Further, a top plate top surface coating 20 is applied to the top surface of the top plate 2 by coating or printing of paint for the purpose of preventing the lateral displacement of the object to be heated 11 and protecting the top plate 2. 2 and 3, the top plate top surface coating 20 is applied in a stripe shape. However, the present invention is not limited to this, and dot-like or uniform application (solid coating) may be used.
Furthermore, the slit part 19 is formed in the area | region (contents introduction | transduction area | region) including at least the upper part (part facing a permeation | transmission part) of the spill detection means 7 among the top-plate upper surface coating 20. FIG.
The slit portion 19 is formed by making the density of the top plate upper surface coating 20 different from the surrounding coating.
For example, the slit part 19 is formed by omitting the top plate upper surface coating 20.
For example, the slit part 19 is formed by making the thickness of the top plate upper surface coating 20 thinner than the periphery.
Further, for example, the slit portion 19 is formed by making the coating density of the top plate upper surface coating 20 rougher than the periphery (increasing the aperture ratio).

The area where the “slit portion 19” is formed corresponds to the “content introduction area” in the present invention.
The “transmission part” corresponds to the “detection region” in the present invention.
In addition, when the top plate upper surface coating 20 is applied to the upper surface of the transmission part, a paint having a high light transmittance in a predetermined wavelength band described later is used.

The slit portion 19 serves as a water channel that facilitates the flow of the content of the heated object 11 over the top plate 2 when the content of the heated object 11 spills over the top plate 2, and the top of the overflow detection unit 7. There is a role as a reservoir to be held in.
Thereby, the speed until the spilled content reaches above the spill detector 7 can be increased. Further, it is possible to prevent the spilled contents from passing over the spillage detection means 7 without accumulating, and the spillage can be reliably detected.
Further, by forming the slit part 19 wider than the transmission part (above the overflow detection means 7), it becomes possible to guide the contents flowing on the slit part 19 above the overflow detection means 7. In addition, it is possible to expand an area in which detection of spillage is possible.

(Structure of the overflow detection means 7)
In this embodiment, a case where the occurrence of spillage is determined using a plurality of lights having different transmittances for water will be described, but the present invention is not limited to this.
The overflow detection means 7 includes light emitting means 8 and 9 that emit light having peak wavelengths in different wavelength bands, and a light detection means 10 that detects the amount of incident light.
The light emitting means 8 and 9 are constituted by light emitting elements having a narrow emission wavelength such as a light emitting diode (LED) or a laser diode (LD), for example, each having a peak wavelength in a wavelength band having a different transmittance for water. . The light emitting means 8 and 9 are arranged such that the incident angle of light with respect to the transmission part of the top plate 2 is a predetermined angle. Hereinafter, the peak wavelength of light emitted from the light emitting means 8 is referred to as “first wavelength”, and the peak wavelength of light emitted from the light emitting means 9 is referred to as “second wavelength”.

  The light detection means 10 is disposed at a position for detecting light incident from the transmission part of the top plate 2 and outputs an output value (for example, voltage) corresponding to the energy (light quantity) of the incident light. The light detection means 10 is composed of a photodiode, for example, and has sensitivity to the peak wavelengths of the light emission means 8 and 9. Further, for example, the light detecting means 10 may use a thermopile having sensitivity to all the wavelength bands regardless of the wavelength bands of the light emitting means 8 and 9.

  The light emitting means 8 and 9 and the light detecting means 10 are attached to the same case, and when the object to be heated 11 is placed above the light emitting means 8 and 9 (the transmission part of the top plate 2), The installation angle is managed at a predetermined angle so that the light transmitted through the transmission part is reflected and the reflected light is incident on the light detection means 10.

Further, a light guide tube 18 is provided between the top plate 2 and the spill detector 7.
The light guide tube 18 is formed in a cylindrical shape and is disposed so as to surround a path of light emitted from the spill detector 7 toward the transmission part and a path of light incident on the spill detector from the transmission part. ing.
By providing such a light guide tube 18, the internal structure of the main body 1 can be made invisible from the transmission part of the top plate 2, and the design can be improved. Further, by providing the light guide tube 18, thermal infrared rays emitted from internal structures such as the heated top plate 2 and the heating coil 12, sunlight or illumination light from other than the transmission part of the top plate 2, etc. The disturbance light can be blocked.
Furthermore, by making the light guide tube 18 made of resin, the heating coil 12 and the object to be heated 11 which are components inside the main body are heated, and the infrared radiation generated by the top plate 2 being heated by heat conduction is generated. By receiving with a resin cylinder having a large heat capacity and low thermal conductivity, the light detection means 10 is not directly affected and the noise resistance is enhanced.

In the present embodiment, a case where two light emitting means 8 and 9 having different peak wavelengths are provided will be described, but the present invention is not limited to this. For example, a multi-wavelength LED having peak wavelength components in a plurality of wavelength bands may be used. Moreover, you may make it provide two or more light emission means for every wavelength range mentioned later.
In addition, since the spill detector 7 detects spill from the detection result of light having different transmittance to water as will be described later, the light emitted from the light emitters 8 and 9 has an emission wavelength similar to that of an LED or LD. It is desirable to use an element that can squeeze and emit light.

(Explanation of wavelength)
Next, the wavelength of light emitted by the light emitting means 8 and 9 will be described.
The light emitted by the light emitting means 8 and 9 has a peak wavelength in a wavelength band that transmits the top plate 2 and the top plate lower surface coating 21b (transmission portion).
The second wavelength light emitted by the light emitting means 9 is light in a wavelength band having a higher transmittance for water than the first wavelength light emitted by the light emitting means 8.
An example of the transmittance of water and the transmittance of the top plate 2 will be described with reference to FIGS.

FIG. 4 is a diagram showing an absorption spectrum of water.
FIG. 5 is a transmission characteristic diagram of the top plate used in the first embodiment.
As shown in FIG. 4, the wavelength bands with low light transmittance to water and easy light absorption by water are 1.3 to 1.5 μm, 1.8 to 2.0 μm, 2.5 to 3.0 μm. Is the wavelength band.
In addition, the wavelength bands where the light transmittance to water is high and the light is not easily absorbed by water are the wavelength bands of 0.5 to 1.3 μm, 1.5 to 1.8 μm, and 2.0 to 2.5 μm. .
As shown in FIG. 5, the wavelength band having a high light transmittance with respect to the top 2 is a wavelength band of 0.5 to 2.85 μm and 3.0 to 4.5 μm.

In the above example, in consideration of the transmittance of water and the transmittance of the top plate 2, the light of the first wavelength emitted by the light emitting means 8 (light that is easily absorbed by water) is 1.3 μm or more and less than 1.5 μm. , And emits light having a peak wavelength in the range of 1.8 μm or more and less than 2.0 μm, or 2.55 μm or more and less than 2.85 μm. For example, the light emitting means 8 uses an LED having a peak wavelength at 1.470 μm.
In addition, the second wavelength light (light that is hardly absorbed by water) emitted from the light emitting means 9 is 0.5 μm or more and less than 1.3 μm, 1.5 μm or more and less than 1.8 μm, or 2.0 μm or more and 2.5 μm. Emits light having a peak wavelength in the range of less than. For example, the light emitting means 9 uses an LED having a peak wavelength at 0.700 μm.

(Painting of top plate 2)
As described above, the emission wavelength bands of the light emitting means 8 and 9 are limited by the transmittance of the top plate 2 and the water absorption spectrum, but the transmission characteristics of printing on the top and bottom surfaces of the top plate 2 also transmit the emission wavelength. Must have characteristics.
For this reason, the top plate lower surface coating 21b of the top plate 2 uses a paint or the like that substantially transmits light of the first wavelength and the second wavelength. For example, the top plate lower surface coating 21b of the top plate 2 uses a paint having a high transmittance between 0.5 and 4.5 μm in consideration of the transmission characteristics of the top plate 2.
However, it is not necessary for all of the transmission wavelengths of the top plate 2 to be high, and it is only necessary that the transmittance is high in the peak wavelength band of the two light emitting means used particularly between the wavelength bands.
For example, when a light emitting means having a peak wavelength of 1.470 μm for the first wavelength and 0.700 μm for the second wavelength is used, a paint having a high transmittance in the wavelength band may be used.

For example, when a wavelength in the visible light band such as 0.700 μm is used, if the paint that transmits the wavelength band is used as the paint on the lower surface of the top plate 2, the structure inside the main body 1 can be seen by the user. It will end up.
Therefore, the light emitted from the light emitting means 8 and 9 is applied with a coating for cutting the wavelength of the visible light band as the top plate lower surface coating 21b of the top plate 2 using a wavelength band from which visible light is removed. The structure may be made invisible.
For example, the transmission characteristics of the paint shown in FIG. 6 are characteristics of a visible light region cut-off paint that does not transmit the visible light region, and in this case, a light emitting means that emits a wavelength having a peak in a wavelength band that excludes the visible light region. Is used.

  Further, when the slit portion 19 is formed by making the thickness or density of the top plate upper surface coating 20 different from that of the periphery, it is necessary to apply at least the facing surface above the spill detector 7 (transmission portion). Similarly to the top plate lower surface coating 21b, a coating that transmits the light emission wavelength of the light emitting means 8, 9 is used.

(Heating operation)
Next, the operation of the heating cooker in the present embodiment will be described.
First, in order to heat the object to be heated 11, the user places the object to be heated 11 on the top plate 2, sets the thermal power so that cooking is performed with the desired thermal power by the operation unit 3, a heating start switch, etc. Press.
When a heating start command is input from the operation unit 3, the control unit 16 determines the output of the inverter of the driving unit 17 and causes a high-frequency current to flow through the heating coil 12. Then, when a high-frequency current flows through the heating coil 12, an induced current flows through the object to be heated 11 placed on the top plate 2, and the object to be heated 11 itself generates heat from resistance heat generation. Due to heat generation, the contents such as food, water, and oil loaded in the object to be heated 11 are heated by heat conduction.

When the object to be heated 11 is heated, the heat of the object to be heated 11 is conducted to the top plate 2. The contact-type temperature detection means 14 detects the heat conducted to the top plate 2 as the top plate temperature and inputs it to the control unit 16.
Moreover, the infrared temperature detection means 13 installed under the heating coil 12 captures the infrared rays radiated from the bottom of the object 11 to be heated and transmitted through the top plate 2, and outputs the output corresponding to the amount of infrared rays to the control unit 16. input.
The control unit 16 controls the drive unit 17 in accordance with the temperatures detected by the contact-type temperature detection unit 14 and the infrared temperature detection unit 13 to perform power control so that the designated thermal power is obtained.

In such heat cooking, for example, when boiling noodles such as raw noodles and pasta, contents such as hot water may be spilled from the pan if the cooking temperature is high and the heating power is strong.
This way of spilling is not the same every time due to differences in the shape, inclination, heating power, etc. of the pan, and it may take time for the water to flow over the spill detection means 7.
Therefore, in the present embodiment, the slit portion 19 is formed by making the density state of the top plate top surface coating 20 on the top plate 2 different from that of the surrounding coating, and the spilled content of the spill detection means 7 is detected. Leads upward.
In the example of FIG. 1, the slit portion 19 is formed outside the outermost diameter of the heating coil 12 and in the front-rear direction or the left-right direction from directly above the spill detection means 7.
When the spilled contents are placed on the slit part 19, the slit part 19 becomes a flow path, and water accumulates in the slit part 19 and is guided upward of the spillage detection means 7.
Further, the inside of the outermost diameter of the heating coil 12 is a place where the pot is highly likely to be placed, and when the spilled water or food material accumulates on the inner upper surface of the heating coil 12, it is heated on the surface of the pot bottom. Since the burn-in and the scale become sticky and cause a decrease in detection accuracy, the spill detection means and the slit portion 19 are formed outside the outermost diameter of the heating coil 12.

During cooking, the detection unit 15 applies water to the top plate 2 above the overflow detection unit 7 based on the detection result of the overflow detection unit 7 whose contents are guided upward by the slit unit 19. The placement of the contents of the heated object 11 is detected to determine the occurrence of spillage.
When the detection unit 15 determines that a spill has occurred, the control unit 16 stops the operation of the drive unit 17 or controls the drive unit 17 to reduce the current flowing through the heating coil 12 to reduce the output. .

(Blowout detection operation)
Next, the details of the operation of detecting the overflow by the overflow detector 7 will be described.
FIG. 7 is an explanatory diagram of output at the time of detection of overflow by the overflow detection means in the first embodiment.
FIG. 7 (i) shows a state in which the content 30 of the heated object 11 mainly composed of water is placed above the overflow detection means 7 (the transmission part of the top plate 2).
FIG. 7 (ii) shows a state in which an object to be heated 11 such as a pan is placed above the overflow detection means 7 (the transmission part of the top plate 2).
FIG. 7 (iii) shows a state where there is no object placed above the overflow detection means 7 (the transmission part of the top plate 2).
Moreover, the upper stage (a) of (i)-(iii) of FIG. 7 has shown the state in which the light emission means 8 light-emits the light of the 1st wavelength (light which is easy to be absorbed in water).
Moreover, the middle stage (b) of (i)-(iii) of FIG. 7 has shown the state in which the light emission means 9 light-emits the light of the 2nd wavelength (light which is hard to be absorbed in water).
Further, the lower part of (i) to (iii) of FIG. 7 shows the output value (voltage V) of the light detection means 10 and the output timing thereof in the above (a) and (b).
In the present embodiment, the light emitting means 8 and 9 make the light amount of the first wavelength light and the light amount of the second wavelength light substantially the same, and the light of the first wavelength and the light of the second wavelength Alternately emit light.

(I) Water Placement As shown in FIG. 7 (i), when the contents 30 mainly composed of water is placed above the overflow detection means 7 due to the occurrence of overflow, Most of the light having the first wavelength (light that is easily absorbed by water) is absorbed by the content 30 mainly composed of water, and hardly transmits or reflects. For this reason, the light of the first wavelength hardly enters the light detection means 10.

On the other hand, (b) the light of the second wavelength from the light emitting means 9 (light that is difficult to be absorbed by water) is not absorbed by the content 30 mainly composed of water, and part of the light is transmitted through the content 30 and is heavenly. It slips out above the plate 2. A part of the light of the second wavelength is reflected from the difference in refractive index between the boundary surface between the top plate 2 and water and the boundary surface between water and air.
Here, typical refractive indexes of the top plate 2 (glass), water, and air are shown in FIG.
As shown in FIG. 8, the relationship of refractive index is glass>water> air, and reflection occurs when light crosses the boundary from the larger refractive index to the smaller one. For this reason, the light of the second wavelength is mainly water by arranging the light emitting means 9 so that the incident angle of the light to the contents 30 (transmission part) is a predetermined angle smaller than the critical angle. The content 30 is transmitted and reflected, and the reflected light enters the light detection means 10.
As a result, when the content 30 mainly composed of water due to spillage is placed above the spillage detection means 7, (a) the detected value of the first wavelength light by the light detection means 10 is (b) It becomes smaller than the detection value of the light of the second wavelength.
For this reason, when the detection value of the light of the first wavelength by the light detection means 10 is smaller than the detection value of the light of the second wavelength, the detection unit 15 determines that a spill has occurred. For example, when the detection value at the light emission timing (a) of the light emitting means 8 is less than the threshold value and the detection value at the light emission timing (b) of the light emission means 9 is greater than or equal to the threshold value, the occurrence of spilling is determined.

  Here, the occurrence of spillage is determined based on the magnitude of the detected value, but the present invention is not limited to this. As described above, since the light of the first wavelength is hardly reflected, the spillage may be determined based on the presence or absence of output at the light emission timings (a) and (b).

(Ii) Placement of pan As shown in FIG. 7 (ii), when a heated object 11 such as a pan is placed above the spill detection means 7, (a) the first wavelength from the light emission means 8 Most of the light is reflected by the bottom surface of the object to be heated 11 and enters the light detection means 10.
Further, (b) most of the light of the second wavelength from the light emitting means 9 is reflected by the bottom surface of the object to be heated 11 and enters the light detecting means 10.
Thereby, when the to-be-heated object 11 such as a pan is placed above the spill detector 7, (a) the detected value of the first wavelength light by the light detector 10, and (b) the second wavelength. The detected value of light is substantially the same value.
For this reason, when the detection value of the light of the 1st wavelength by the light detection means 10 and the detection value of the light of the 2nd wavelength are substantially the same value, the detection part 15 determines with no overflowing. For example, if the difference between the detection value at the light emission timing (a) of the light emission means 8 and the detection value at the light emission timing (b) of the light emission means 9 is equal to or less than a threshold value, it is assumed that no overflow has occurred. judge.

  In the above description, the case where both the first and second wavelengths of light are reflected from the bottom surface of the object to be heated 11 is described. However, depending on the material of the object to be heated 11, the light may be absorbed. Even in this case, the light of the first wavelength and the second wavelength are not reflected and do not enter the light detection means 10, so that the detection values of the light of the first wavelength and the light of the second wavelength are substantially the same value, and the overflow is generated. It can be determined that it is not.

(Iii) No placement As shown in FIG. 7 (iii), when there is no placed object above the overflow detection means 7, (a) the first wavelength light from the light emitting means 8, and (b) the light emitting means The light of the second wavelength from 9 is transmitted through the transmission part of the top plate 2 and escapes above the top plate 2.
As a result, when there is no mounted object above the spill detector 7, the light detection means 10 detects (a) the first wavelength light detection value and (b) the second wavelength light detection value is substantially zero. It becomes.
For this reason, when the detection value of the light of the 1st wavelength by the light detection means 10 and the detection value of the light of the 2nd wavelength are substantially the same value, the detection part 15 determines with no overflowing. For example, if the difference between the detection value at the light emission timing (a) of the light emission means 8 and the detection value at the light emission timing (b) of the light emission means 9 is equal to or less than a threshold value, it is assumed that no overflow has occurred. judge.

In the above description, the amount of light of the first wavelength and the amount of light of the second wavelength are substantially the same, and the first wavelength light and the second wavelength light are emitted alternately. Although the case where the different light beams are alternately irradiated in a pulse shape has been described, the present invention is not limited to this. For example, the occurrence of spilling may be determined by simultaneously irradiating light of the first and second wavelengths and detecting the wavelength component and the size of the light incident on the light detection means 10. .
The light amount of the first wavelength light may be different from the light amount of the second wavelength light. In this case, for example, when the ratio of the reflected light with respect to the irradiation light of the first wavelength light is smaller than the ratio of the reflected light with respect to the irradiation light of the second wavelength, occurrence of spilling is determined.

  In the above description, the case where two lights having different transmittances for water are emitted and the reflected light is detected has been described. However, the present invention is not limited to this, and three or more light transmittances for water are different. Light (wavelength component) may be emitted. Also in this case, it is possible to detect the occurrence of spilling by comparing the output values of the reflected light of each wavelength. In addition, by increasing the wavelength of the light to be irradiated, for example, even when the transmittance with respect to the pan for some wavelengths and the transmittance with respect to water are approximated, it is possible to detect the occurrence of spilling using light of other wavelengths. And detection accuracy can be further improved.

As described above, in the present embodiment, in the top plate top surface coating 20 provided on the top surface of the top plate 2, the slit portion 19 (content introduction region) including at least a portion facing the transmission portion is in a dense state. , The surrounding paint was different.
For this reason, the speed until the contents 30 spilled on the top plate 2 reaches above the spill detector 7 can be increased. Further, it is possible to prevent the spilled contents 30 from passing through without being accumulated above the spill detector 7, and to reliably detect the spill. Therefore, the detection accuracy of spilling can be improved.

In the present embodiment, the slit portion 19 (content introduction region) is formed wider than the transmission portion.
For this reason, the contents flowing on the slit portion 19 can be guided to the upper part of the spillage detection means 7, and the region where the spillage can be detected can be expanded. Therefore, the detection accuracy of spilling can be improved.

In the present embodiment, the first wavelength light transmitted through the transmission part of the top plate 2 and the second wavelength light transmitted through the transmission part and having a higher transmittance for water than the first wavelength light , And the light of the first wavelength and the second wavelength incident from the transmission part of the top plate 2 is detected. And when the detection value of the light of the 1st wavelength by the light detection means 10 is smaller than the detection value of the light of the 2nd wavelength, it determines with the spilling having generate | occur | produced.
For this reason, when the content 30 mainly composed of water is spilled above the spill detector 7, the occurrence of the spill can be detected. Further, when a heated object 11 such as a pot is placed above the spillage detection means 7 or when there is no placement object above the spillage detection means 7, the occurrence of spillage is not detected. Therefore, erroneous detection of spillage can be reduced.
Further, since the occurrence of spillage is determined by detecting light from the transmission part of the top plate 2, the occurrence of spillage can be detected even when the spilled content 30 is gently spread. .
In addition, even when the spreading speed is slow when spilling, which is difficult with the method of detecting spilling using the amount of change in capacitance, it is possible to detect spillage. Therefore, the cooking device with further improved safety and convenience can be provided.

Moreover, in this Embodiment, when it determines with the spilling having generate | occur | produced, the output of the heating coil 12 is reduced or stopped.
For this reason, hot contents 30 such as hot water spread on the upper surface of the top plate 2, avoiding dangers such as burns to the user, and avoiding the danger of water entering the main body 1 and causing breakdown. Is possible. Therefore, safety and convenience can be provided to the user.

In the present embodiment, the light amount of the first wavelength and the light amount of the second wavelength are made substantially the same, and the light of the first wavelength and the light of the second wavelength are emitted alternately.
In this way, by alternately irradiating light having different wavelengths in the form of pulses, the output value of the light detection means 10 distinguishes the reflected light of the first wavelength and the reflected light of the second wavelength. Since they can be output separately, the reflected lights are not interfered and output, and the occurrence of spilling on the top 2 can be accurately detected.
In addition, noise such as ambient light and thermal infrared rays generated from internal structures can be distinguished from reflected light, and the occurrence of spilling on the top 2 can be detected with high accuracy.

Further, in the present embodiment, the light emitting means 8 and 9 are arranged so that the incident angles of the light of the first wavelength and the second wavelength with respect to the transmission part are a predetermined angle.
For this reason, when the content 30 mainly composed of water is spilled above the spill detector 7, the second wavelength light is transmitted and reflected by the content 30, and the reflected light is incident on the light detector 10. Can do. Moreover, when the to-be-heated object 11 is mounted, the light of the 1st and 2nd wavelength can be reflected (absorbed) together. Therefore, the occurrence of spillage on the top plate 2 can be detected with high accuracy.

When a thermopile having a wide detectable wavelength band is used as the light detection means 10, the temperature of the top plate 2 is detected by detecting the amount of thermal infrared rays emitted from the top plate 2 by the light detection means 10. Also good. That is, the temperature of the top 2 can be measured from the output of the thermopile having sensitivity over a wide wavelength band.
When the spilling occurs and the hot water is spilled, the top plate temperature also rises. Therefore, in addition to the reflected light output of the two wavelength bands described above, the temperature information of the top plate 2 is also used as a determination element. The possibility of false detection in cases other than spilling can be reduced.

In the present embodiment, the case where the occurrence of spillage is determined using a plurality of lights having different transmittances for water has been described, but the present invention is not limited to this.
The spill detector 7 may be any device that emits light toward the transmissive portion and detects the light incident from the transmissive portion, and may use light having a peak wavelength in one wavelength band.
Even in such a configuration, the detection range of the spilled contents can be expanded, and the effect of improving the detection accuracy of the spilling can be obtained.

Embodiment 2. FIG.
FIG. 9 is a top view showing the cooking device according to the second embodiment.
As shown in FIG. 9, the heating coil 12 is formed in a substantially circular shape in plan view. And the slit part 19 in this Embodiment is formed in circular arc shape so that a part of outer periphery of the circular heating coil 12 may be followed.
For example, each heating coil 12 is formed on the front side of the outermost outer shape.
Also in the present embodiment, the slit portion 19 is formed so as to be included above (the transmission portion) of the overflow detection means 7.
The other configuration and the operation for determining the occurrence of spilling are the same as those in the first embodiment.

  As described above, in the present embodiment, the slit portion 19 is formed in an arc shape so as to be along a part of the outer periphery of the heating coil 12, so that in addition to the effects of the first embodiment, the spillage is not generated. When it occurs, since the distance from the heating coil 12 becomes the same distance, it is possible to detect the spilling quickly regardless of the direction of the spilling.

In addition, the overflow detection means 7 is disposed outside the heating coil 12 in plan view. That is, the overflow detection means 7 is disposed outside the outermost diameter of the heating coil 12.
For this reason, the spill detector 7 is separated from the heating coil 12, and when the heating coil 12 and the top plate 2 are at a high temperature, it is possible to prevent adverse effects on the components of the spill detector 7. Moreover, it can reduce that the infrared rays radiated | emitted from the heating coil 12 and the top plate 2 used as high temperature inject into the light detection means 10, and can improve the generation | occurrence | production precision of a spill.

Embodiment 3 FIG.
FIG. 10 is a top view showing the heating cooker in the third embodiment.
As shown in FIG. 10, the heating coil 12 is formed in a substantially circular shape in plan view. The slit portion 19 in the present embodiment is formed concentrically outside the circular heating coil 12.
Also in the present embodiment, the slit portion 19 is formed so as to be included above (the transmission portion) of the overflow detection means 7.
The other configuration and the operation for determining the occurrence of spilling are the same as those in the first embodiment.

  As described above, in the present embodiment, since the slit portion 19 is formed concentrically outside the heating coil 12, in addition to the effects of the first embodiment, the contents spilled from the object 11 to be heated. Regardless of the direction in which 30 flows, the contents 30 can be guided upward of the overflow detection means 7.

In addition, as shown in the said FIG. 9, FIG. 10, when the slit part 19 is formed between the operation part 3 and the heating coil 12, when it spills in the direction which goes to the operation part 3 from the to-be-heated object 11, The occurrence of spilling can be detected quickly.
Further, the content 30 that flows in the direction toward the operation unit 3 flows along the slit portion 19, becomes difficult to move toward the operation unit 3, and the content 30 spilled in the slit portion 19 accumulates, so that the operation unit 3 It is possible to make it difficult for the contents to reach 3.
As a result, it is possible to prevent the occurrence of spillage and prevent the hot water from flowing into the place where the user tried to operate the operation unit 3 in order to stop the thermal power, thereby giving the user a risk of burns and ensuring safety. Become.
In addition, the shape of the slit part 19 is not restricted to this. For example, as shown in FIG. 11, the slit portion 19 formed between the operation portion 3 and the heating coil 12 may be substantially rectangular. Even if it is such a structure, when it spills in the direction which goes to the operation part 3 from the to-be-heated material 11, generation | occurrence | production of a spill can be detected quickly and reliably.

Embodiment 4 FIG.
FIG. 12 is a top view showing the heating cooker in the fourth embodiment.
As shown in FIG. 12, the slit portion 19 in the present embodiment is formed between the heating coil 12 and the heating coil 12.
Further, a slit portion 19 is formed between the heating coil 12 disposed at the center rear of the main body 1 and the intake port 6. For example, it forms in circular arc shape along the outer periphery of the heating coil 12 arrange | positioned in the center back.
A slit 19 on the arc is formed on the front side of the heating coil 12 disposed on the front side of the main body 1 as in the second embodiment.
The other configuration and the operation for determining the occurrence of spilling are the same as those in the first embodiment.

In addition, in the example of FIG. 12, although the slit part 19 is formed between the heating coil 12 arrange | positioned in the center back, and the inlet port 6, this invention is not limited to this.
For example, as shown in FIG. 13, a slit portion 19 may be formed between the heating coil 12 and the exhaust port 5 in addition to or instead of the configuration of FIG. 12.
Moreover, although the case where the slit part 19 was circular arc shape was demonstrated in FIG. 12, it does not restrict to this. For example, as shown in FIG. 13, the slit portion 19 formed between the heating coil 12 and the intake port 6 or between the heating coil 12 and the exhaust port 5 may be formed to be substantially rectangular. . Even in such a configuration, the same effect can be obtained.

As described above, in the present embodiment, the slit portion 19 is formed between the heating coil 12 and the heating coil 12.
For this reason, in addition to the effect of the first embodiment, the slit portion 19 that induces the spillage of the two heating coils 12 (two heating ports) can also be used as one slit portion 19. Therefore, the effective use of the installation space and the effect of cost reduction can be obtained.
Further, it is only necessary to provide one overflow detection means 7 corresponding to one slit portion 19 formed between the heating coils 12 and 12, and the two heating coils 12 ( It is possible to detect spillage at the two heating ports. Therefore, the effective use of the installation space and the effect of cost reduction can be obtained.

In the present embodiment, the slit portion 19 is formed between the heating coil 12 and the intake port 6 or between the heating coil 12 and the exhaust port 5. When spilling in the direction toward the exhaust port 5, the occurrence of spilling can be detected quickly.
Further, the content 30 that flows in the direction toward the intake port 6 or the exhaust port 5 flows along the slit portion 19, becomes difficult to move toward the intake port 6 or the exhaust port 5, and the content that has been spilled into the slit portion 19. The accumulation of 30 can make it difficult for the contents to reach the intake port 6 and the exhaust port 5.
As a result, it is possible to avoid the possibility that when water spills, water enters one of the exhaust port 5 and the intake port 6 and the water is guided to the inside of the device to cause a malfunction or short circuit. Become.

Embodiment 5 FIG.
In the present embodiment, an embodiment in which a stripe-shaped groove extending in the longitudinal direction of the slit portion 19 is formed will be described.

FIG. 14 is a diagram showing the shape of the slit portion in the fifth embodiment.
As shown in FIG. 14, the slit portion 19 is formed by a concentric circumference with the heating coil 12 as in the third embodiment (FIG. 10).
Furthermore, the slit part 19 in this Embodiment is formed by varying thickness by application | coating of the top plate upper surface coating 20, and forms the stripe-shaped groove part 19a extended in a longitudinal direction (circumferential direction).
For example, when the slit portion 19 is formed without being coated, the groove portion 19a is formed by applying the coating in stripes. Further, for example, when the slit portion 19 is formed with a different coating thickness or coating density, the groove portion 19a is formed by not coating in a stripe shape.
The configuration of the groove portion 19a is not limited to this, and for example, a plurality of grooves may be provided in a stripe shape, or the depth (thickness) of each stripe groove may be changed.
The other configuration and the operation for determining the occurrence of spilling are the same as those in the first embodiment.

As described above, in the present embodiment, stripe-shaped grooves extending in the longitudinal direction of the slit portions 19 are formed by the top plate top surface coating 20.
For this reason, in addition to the effect of the said Embodiment 1, the flow of the water to the longitudinal direction of the slit part 19 can be improved. Therefore, it is possible to quickly detect spillage.

Embodiment 6 FIG.
(overall structure)
In this embodiment, an IH cooking heater that performs induction heating will be described as an example of a cooking device.
FIG. 15 is an exploded perspective view showing a heating cooker according to the sixth embodiment.
FIG. 16 is a cross-sectional conceptual diagram showing a heating cooker in the sixth embodiment.
In addition, the same code | symbol is attached | subjected to the part of the same function as the said Embodiment 1-5.
As shown in FIGS. 15 and 16, the induction heating cooker is provided on the main body 1, the top plate 2 on which the heated object 11 such as a pan is placed, and below the top plate 2. The heating coils 12a to 12c (hereinafter simply referred to as 12) for heating the object 11 to be heated placed on the top plate 2 and an inverter circuit are provided to supply high-frequency current to the heating coil 12. Then, a drive unit 17 that drives the heating coil 12, a control unit 16 that controls the operation of the drive unit 17 to control the input power (output) to the object to be heated 11, and an operation that inputs an operation from the user The display unit 4 includes a display unit 4 that displays an operation state, input / operation contents from the operation unit 3, and the like.
The top plate 2 has ring-shaped heating ports 40a to 40c (hereinafter, simply referred to as 40) indicating positions where the article to be heated 11 is placed at positions corresponding to the heating coils 12a to 12c on the top surface thereof. Are provided by printing or the like. In addition, on the rear side of the upper surface of the main body 1, an intake port 6 that communicates with the inside of the main body 1 and takes cooling air into the main body 1 and cooling air taken into the main body 1 are provided. An exhaust port 5 for discharging is provided.

Moreover, the position corresponding to the inside (inner periphery side) and the outside of the area (outer periphery side) of each heating port 40a to 40c below the top plate 2 is in contact with the lower surface of the top plate 2, and the top plate 2 The temperature detection parts 41 and 42 which detect the temperature of the to-be-heated object 11 mounted in the heating ports 40a-40c by detecting temperature are provided.
As shown in FIG. 16, the temperature detectors 41 and 42 are provided by being held by a coil base 43 for holding the heating coil 12 in the main body 1 so as to come into contact with the lower surface of the top plate 2 in the assembled state. It is configured. In this way, the temperature detectors 41 and 42 can detect the temperature of the object to be heated 11 placed on the heating port 40 by heat conduction through the top plate 2, and the controller 16 can detect the temperature based on the information. Then, the drive unit 17 is controlled to drive the heating coil 12.
In the present embodiment, at least one of the temperature detectors 41 and 42 constitutes the overflow detector 7. The detection unit 15 according to the present embodiment determines the occurrence of spillage of contents from the heated object 11 based on the detection result of at least one of the temperature detection units 41 and 42.

The “operation unit 3” corresponds to “operation means” in the present invention.
The “heating coil 12” corresponds to the “heating means” in the present invention.
The “detection unit 15” and the “temperature detection units 41 and 42” correspond to “spillover detection means” in the present invention.

In the present embodiment, the heating coil 12 is wound in a triple ring shape and a space is provided between the rings. However, the present invention is not limited to this. For example, a single layer that does not provide a space between the rings is provided. A ring-shaped one or a plurality of non-concentric rings arranged in one heating coil 12 may be used, and the shape is not limited to the ring shape. Good. Furthermore, although the case where the three heating coils 12 were provided in the main body 1 was shown, one or four or more may be sufficient, and a resistance heater etc. may be provided in one part.
Moreover, although the case where the heating port 40 was enclosed by the ring was shown, another shape may be sufficient.

In order to prevent the heated object 11 from coming into close contact with the top board 2 on the top surface of the top board 2 and to prevent the top board 2 from being damaged by dropping of the heated object 11, An upper surface coating 20 is provided to form dots and stripe-shaped grooves.
In the present embodiment, the density of the top surface coating 20 on the position (detection region) corresponding to the temperature detection units 41 and 42 provided in the main body 1 and its surroundings (hereinafter, this portion is referred to as the slit portion 19). The surface is rougher (sparsely) than the periphery, or the top plate upper surface coating 20 in this portion is omitted.

The slit portion 19 serves as a water channel that facilitates the flow of the content above the temperature detection units 41 and 42 when the content of the object to be heated 11 is spilled on the top plate 2, and the temperature detection unit 41. , 42 serves as a reservoir portion that is retained above 42.
Thereby, the speed until the spilled content reaches above the temperature detection units 41 and 42 can be increased. In addition, it is possible to prevent the spilled contents from passing through without being accumulated above the temperature detectors 41 and 42, and to reliably detect the spill.
Moreover, the slit part 19 is formed wider than the detection area that is the area facing the temperature detection parts 41 and 42, thereby guiding the content that has flowed on the slit part 19 to above the overflow detection means 7. Thus, it is possible to expand the area where the detection of spillage is possible.
In addition, the slit part 19 in this Embodiment can be made into the same shape and position as any slit part 19 of the said Embodiment 1-5. Moreover, you may combine arbitrarily the shape and position of the slit part 19 of the said Embodiment 1-5.

Next, the operation of the present embodiment configured as described above will be described.
When the object to be heated 11 is being heated, the temperature detectors 41 and 42 detect the temperature of the object to be heated 11 by detecting the heat transferred through the top plate 2 and the top plate upper surface coating 20. . For example, when the content is water, in the state where there is no spillage, when the water in the heated object 11 is in a boiling state, the bottom temperature of the heated object 11 rises to about 120 ° C. with respect to the boiling 100 ° C. water. Can be detected.
On the other hand, when spilling occurs, the content lower than the temperature of the object to be heated 11 flows out on the top plate 2 and reaches above the temperature detection unit 42 provided on the outer peripheral side of the heating port 40. Further, the spilled contents were provided on the inner peripheral side of the heating port 40 through the space between the dots or stripe-shaped grooves of the top plate top surface coating 20 provided on the top plate 2 and the heated object 11. It also reaches above the temperature detector 41. For example, when boiling water is spilled, the water that has dropped to a temperature of 100 ° C. or less spreads on the top plate 2 and flows into the detection region on the top plate 2 that faces the temperature detection units 41 and 42.
For this reason, the temperature which the temperature detection parts 41 and 42 detect falls rapidly.
The detection unit 15 according to the present embodiment causes the spilling when the detected temperature of at least one of the temperature detection units 41 and 42 rapidly decreases based on the information on the temperature change detected by the temperature detection units 41 and 42. It is determined that it has occurred. For example, when a temperature drop value for a predetermined time, a differential value of the detected temperature, or the like exceeds a preset threshold value, it is determined that a spill has occurred.

  In the induction heating cooker provided with such a spill detection means 7, when the user turns on the power switch and operates the operation unit 3, the control unit 16 drives the drive unit 17, and high-frequency current is applied to the heating coil 12. The object to be heated 11 is started to be heated by the high frequency magnetic field supplied and generated in the heating coil 12.

While the object to be heated 11 is being heated, the control unit 16 detects temperature changes by the temperature detection units 41 and 42 at regular time intervals, and determines whether or not spilling has occurred. When the temperature rapidly decreases, the control unit 16 determines that a spill has occurred, and controls the drive unit 17 to stop or reduce the current supplied to the heating coil 12 based on this information. At this time, the control unit 16 may issue an alarm.
When one or both of the temperature detection units 41 and 42 facing the inner and outer peripheral sides of the heating port 40 detect a sudden temperature drop, the control unit 16 determines that a spill has occurred. To do.

  In addition, the temperature detection parts 41b and 42b provided corresponding to the heating port 40b adjacent to the heating port 40a that is heating detect the temperature together with the temperature detection units 41a and 42a even when the heating port 40b is not used. If the temperature detectors 41b and 42b detect a sudden temperature change while the heating port 40a is being used, the control unit 16 determines that spillage has occurred, and the control unit 16 uses this information. Therefore, the drive unit 17 may be controlled so as to stop or reduce the current supplied to the heating coil 12a.

  As another example of the top plate top surface coating 20, as the top plate top surface coating 20 (including the slit portion 19) on the top plate 2, a stripe-shaped groove is provided so as to cross in the left-right direction, or before the slit portion 19. On the side, a top plate upper surface coating 20 (peripheral region) having a denser coating density may be further provided.

As described above, according to the present embodiment, the slit 19 on the top surface of the top plate 2 is provided with a rough top plate coating from the periphery, or the top plate coating of the slit portion 19 is omitted. The liquid that has flowed easily flows and exists in the slit portion 19.
For this reason, it is possible to increase the speed until the content 30 spilled on the top plate 2 reaches above the spill detector 7 (temperature detectors 41 and 42). Further, it is possible to prevent the spilled contents 30 from passing through without being accumulated above the spill detector 7, and to reliably detect the spill. Therefore, the detection accuracy of spilling can be improved.
Further, even when the level of the top plate 2 is not maintained at the time of assembly or when the main body 1 is tilted when being assembled into the kitchen, it is possible to reliably detect spillage.

  Further, according to the present embodiment, the liquid spilled on the top plate 2 is more likely to flow into the slit portion 19 where the top plate coating is rougher than the peripheral top plate top surface coating 20 or the top plate coating is omitted. Therefore, the detection accuracy of spilling can be improved.

  Further, according to the present embodiment, when the contact area of the spill detector 7 (temperature detectors 41, 42) to the top plate 2 is small, or when the number of temperature detectors 41, 42 is small, or spills Even when the amount of the content (liquid) is small, the coating of the slit portion 19 is roughened or omitted as compared with the peripheral top plate top surface coating 20, so that the content is surely placed on the temperature detectors 41 and 42. Can lead. For this reason, the temperature detection parts 41 and 42 can be reduced in size or the number of installation can be reduced, and cost can be reduced.

  In addition, according to the present embodiment, the overflow detection means 7 (temperature detection units 41 and 42) are arranged both inside and outside the area of the heating port 40. When the object 11 is used, the object to be heated 11 is not arranged above the temperature detection unit 42 outside the area, but since the spilled liquid easily flows above the slit part 19, the temperature detection unit only in the area. It is possible to more reliably detect spillage than when 41 is arranged.

  Furthermore, according to the present embodiment, one heating port 40 is in a heating operation state for detection by the overflow detection means 7 (temperature detection units 41, 42) provided corresponding to the plurality of adjacent heating ports 40, respectively. Even when the other is in the stopped state, the temperature detection units 41 and 42 corresponding to the heating port 40 in the stopped state are also performed. If it is obtained, it is determined that spilling has occurred. For this reason, the spilled liquid spread on the top plate 2 a little away from the heated object 11 used at the heating port 40 during heating, and reached the temperature detection part 41 or 42 of the heating port 40 in the stopped state. Even in this case, it will be possible to detect spills.

  In the present embodiment, the same shape and position as those of any of the slit portions 19 in the first to fifth embodiments can be adopted, and the top plate 2 can be formed as in the first to fifth embodiments. The liquid spilled on the top can be easily guided to the slit portion 19 and the detection accuracy can be further improved. The operation portion 3 provided on the front side of the top plate 2 and the cooling air intake port 6 provided on the rear side. Since it becomes difficult to turn to the exhaust port 5b, it is possible to prevent malfunctions and failures of heating by the operation unit 3 and to improve reliability.

In the first to fifth embodiments, a configuration is described in which the overflow detection means 7 emits light toward the transmissive portion and detects the light incident from the transmissive portion, and the sixth embodiment. In the above description, the structure for detecting the temperature of the top plate 2 as the overflow detection means 7 has been described, but the present invention is not limited to this.
For example, one or a plurality of electrodes may be installed around the heating coil 12 and the capacitance between the electrodes and a predetermined potential may be measured. In this case, the spill detector 7 applies an AC voltage between the electrode and a predetermined potential (for example, ground potential). The applied AC voltage has a small amplitude when the capacitance (parasitic capacitance) is large, and the capacitance is measured from the attenuation of the amplitude. When there is no spillage, air with a relative dielectric constant of 1 exists mainly between the electrode and the predetermined potential, but when the spillage occurs, the content mainly composed of water with a relative dielectric constant of 80 enters. The capacitance changes. Therefore, by checking the presence or absence of a change in capacitance, it is possible to detect spillage.
In addition, by disposing the electrode in a part of the slit portion 19, it is possible to guide the contents flowing on the slit portion 19 to the upper side of the electrode, and to expand a region where the overflow can be detected. be able to.

  DESCRIPTION OF SYMBOLS 1 Main body, 2 Top plate, 3 Operation part, 4 Display part, 5 Exhaust port, 6 Intake port, 7 Overflow detection means, 8 Light emission means, 9 Light emission means, 10 Light detection means, 11 Heated object, 12 Heating coil, 13 Infrared temperature detection means, 14 Contact-type temperature detection means, 15 Detection section, 16 Control section, 17 Drive section, 18 Light guide tube, 19 Slit section, 19a Groove section, 20 Top plate top surface coating, 21a Top plate bottom surface coating, 21b Top plate bottom surface coating, 30 contents, 40 heating port, 41 temperature detector, 42 temperature detector, 43 coil base.

Claims (22)

The top plate is provided with a coating, and the top plate on which the object to be heated is placed,
A heating means that is provided below the top plate and heats an object to be heated placed on the top plate;
Overflow detection means for detecting the presence or absence of overflow from the heated object in a predetermined detection area on the top plate,
Control means for controlling the heating means based on the detection result of the overflow detection means;
With
Of the coating provided on the top surface of the top plate, the density state of the content introduction region including at least the detection region is different from the surrounding coating,
The cooking device according to claim 1, wherein the content introduction region is formed wider than the detection region. The cooking device according to claim 1, wherein painting of the content introduction region is omitted. The cooking device according to claim 1, wherein the coating of the content introduction region is formed thinner than the thickness of the surrounding coating. The cooking device according to claim 1, wherein the coating of the content introduction region is formed to be rougher than the surrounding coating. The heating means is formed in a substantially circular shape in plan view,
The content introduction area is
The cooking device according to any one of claims 1 to 4, wherein the cooking device is formed in an arc shape along a part of an outer periphery of the heating means. The heating means is formed in a substantially circular shape in plan view,
The content introduction area is
The heating cooker according to any one of claims 1 to 4, wherein the cooking device is formed concentrically outside the heating means. Provided on the same plane as the top plate, comprising operating means for inputting an operation for controlling the heating power of the heating means,
The content introduction area is
The cooking device according to any one of claims 1 to 4, wherein the cooking device is formed between the operation unit and the heating unit. A plurality of heating means,
The content introduction area is
The cooking device according to any one of claims 1 to 4, wherein the cooking device is formed between the heating unit and the heating unit. An air inlet that is provided on the same plane as the top plate and takes cooling air into the cooking device;
An exhaust port provided on the same plane as the top plate, for discharging the cooling air into and out of the heating cooker;
With
The content introduction area is
The cooking device according to any one of claims 1 to 4, wherein the cooking device is formed between the heating unit and the intake port or between the heating unit and the exhaust port. The content introduction area is
The cooking device according to any one of claims 1 to 4, wherein a stripe-shaped groove extending in a longitudinal direction of the content introduction region is formed by painting the upper surface. The control means includes
The cooking device according to any one of claims 1 to 10, wherein when it is determined that the spilling has occurred, the output of the heating means is reduced or stopped. The top plate forms a transmission part that transmits at least light of a predetermined wavelength as the detection region,
The spill detection means is provided below the top plate, emits light toward the transmissive part, detects light incident from the transmissive part, and detects the occurrence of spillage based on the detected light The heating cooker according to any one of claims 1 to 11, wherein: The spill detection means is
A light emitting means that emits light of a first wavelength that is transmitted through the transmission part, and light of a second wavelength that is transmitted through the transmission part and has a higher transmittance to water than the light of the first wavelength;
A light detecting means for detecting light of the first wavelength and the second wavelength incident from the transmission part;
Have
The control means includes
The cooking device according to claim 12, wherein when the detection value of the light of the first wavelength by the light detection means is smaller than the detection value of the light of the second wavelength, it is determined that the spilling has occurred. The light emitting means includes
The cooking device according to claim 13, wherein the light is incident so that incident angles of the light having the first wavelength and the second wavelength with respect to the transmission portion are a predetermined angle. The light emitting means includes
The light having the peak wavelength in the range of 1.3 μm or more and less than 1.5 μm, 1.8 μm or more and less than 2.0 μm, or 2.5 μm or more and less than 2.8 μm is emitted as the first wavelength light. The heating cooker according to claim 13 or 14. The light emitting means includes
The light having the peak wavelength in the range of 0.5 μm or more and less than 1.3 μm, 1.5 μm or more and less than 1.8 μm, or 2.0 μm or more and less than 2.5 μm is emitted as the second wavelength light. The cooking device according to any one of claims 13 to 15. The light emitting means includes
The cooking device according to any one of claims 13 to 16, wherein the cooking device comprises a light emitting diode or a laser diode. The light detection means includes
The cooking device according to any one of claims 13 to 17, wherein the cooking device is configured by a photodiode or a thermopile. The spillover detection means is provided below the top plate, and comprises temperature detection means for detecting the temperature of the top plate,
The region of the top plate facing the temperature detection means is defined as the detection region, and the occurrence of spilling is detected based on a change in the temperature of the top plate in the detection region. The cooking device according to claim 1. A plurality of the temperature detection means are arranged on the inner peripheral side and the outer peripheral side of the heating port indicating the position where the object to be heated is placed,
The spill detection means is
Based on at least one of the detection temperature of the temperature detection means arranged on the inner circumference side and the detection temperature of the temperature detection means arranged on the outer circumference side, from the object to be heated placed on the heating port 20. The cooking device according to claim 19, wherein occurrence of spilling is detected. The top plate is provided with a plurality of heating ports indicating positions where the object to be heated is placed,
The temperature detection means is provided in each heating port,
The spill detection means is
21. The presence or absence of spillage at any heating port among the plurality of heating ports is detected based on a temperature detected by the temperature detection unit corresponding to a heating port other than the heating port. Cooking device. The spill detection means is
The presence or absence of spillage at the heating port during the heating operation among the plurality of heating ports is detected based on the temperature detection unit of the heating port and the detection temperature of the temperature detection unit corresponding to the heating port while heating is stopped. The cooking device according to claim 21, wherein the cooking device is a cooking device.

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