JP5397104B2 - Infrared sensor unit and electromagnetic induction heating cooker using this infrared sensor unit - Google Patents

Description

  The present invention relates to an induction heating cooker having an infrared sensor that detects infrared rays emitted from a heated container.

Conventionally, there is an electromagnetic induction heating cooker that detects the temperature of a heated container using an infrared sensor. Such an infrared sensor is arranged on a printed wiring board (hereinafter referred to as a board) together with a connector for connecting a signal line for transmitting an output signal output by detecting infrared rays to a main body control board (microcomputer). ing.
And the board | substrate with which each component is arrange | positioned is accommodated in the case formed with the material which has light-shielding property, and is used as a unit. An opening is formed behind the case so that a signal line can be connected to the connector on the board from the outside.

Moreover, the opening part for allowing the infrared rays radiated | emitted from the to-be-heated container to pass is formed also in the part facing the infrared sensor of the upper surface of a case.
The infrared sensor unit configured as described above is attached to the coil base by screwing the case toward the top plate so that the infrared sensor can detect the temperature of the heated container (for example, a patent) Reference 1).

No. 2008-226574

However, since the infrared sensor unit disclosed in Patent Document 1 has a configuration in which a connector can be directly connected from an opening formed at the rear of the case, the infrared sensor unit is attached to the coil base and each part. When assembling the cable, the signal line may fall out of the connector by pulling the signal line.
Even if the signal line does not fall out of the connector, a tensile stress acts directly on the board, which may damage the board itself and components mounted on the board.

  Accordingly, the present invention has been made to solve the above-described problem, and when the infrared sensor unit is mounted at a predetermined position, the induction heating having the infrared sensor unit that can be mounted without damaging the infrared sensor unit. The purpose is to provide a cooker.

In order to solve the above problems, an infrared sensor device having a substrate on which an infrared sensor and a first connector are mounted, a signal line provided with a second connector connected to the first connector, An opening for passing a signal line and a sensor hole facing the infrared sensor are formed, and a case for housing the infrared sensor device is formed therein, a through hole is formed in the substrate, and the first connector includes the substrate Is mounted on the substrate in a state in which a connection portion connected to the second connector is directed outward with respect to the substrate,
In a state where the second connector is connected to the first connector, an end surface of the second connector positioned in a direction to be removed from the first connector has a positional relationship that does not overlap with the substrate. The case includes an upper case and a lower case, and the upper case is formed with a positioning portion and a pin that protrude substantially vertically toward the inside of the case , and the positioning portion includes the infrared device attached to the case. In the attached state, it fits into the through hole, determines the position of the substrate with respect to the upper case, and the pin contacts the end face in the state where the infrared device is attached to the case. Or using an infrared sensor unit for an induction heating cooker, characterized in that the infrared sensor unit is positioned with a slight clearance between the end face Bayoi.

  If each part is configured as described above, when the infrared sensor unit is mounted at a predetermined position, even if the signal line is pulled, it can be prevented from falling off the connector, and the effect of tensile stress on the board can be prevented. It becomes possible to prevent the substrate from being damaged.

The perspective view of the state which decomposed | disassembled some electromagnetic induction heating cooking appliances concerning embodiment The perspective view of the state which removed the top plate part of the electromagnetic induction heating cooking appliance of FIG. Plan view of the electromagnetic induction heating cooker of FIG. The perspective view of the state which removed the component inside the main body of the electromagnetic induction heating cooking appliance of FIG. The perspective view which shows the air path unit, infrared sensor unit, and heating coil holding member of the electromagnetic induction heating cooking appliance of FIG. 5 is an exploded perspective view (front side) of the infrared sensor unit of FIG. FIG. 6 is an exploded perspective view of the infrared sensor unit (back side). The perspective view of the state which mounted | wore the upper case with the infrared sensor unit of FIG. A perspective view of the infrared sensor unit of FIG. 6 as seen from the rear (upper case side) Cross section of infrared sensor unit Plan view showing the positional relationship between pins and connectors A perspective view of the infrared unit attached to the heating coil unit

Embodiments of the present invention will be described below with reference to the drawings.
As shown in FIG. 1, the electromagnetic induction heating cooker 1 according to the present embodiment is configured by providing a top plate portion B on a main body portion A in which various components are accommodated in a substantially rectangular main body case 2. Has been. The top plate portion B includes an upper frame 20 and a top plate 21 attached to the opening of the upper frame 20.

The upper frame 20 is formed in a frame shape from a non-magnetic stainless steel plate or a metal plate made of aluminum, and has a size that closes the upper surface opening of the main body case 2 and is fixed to the main body case 2 with a fixing tool such as a screw. Has been.
The top plate 21 is placed so as to cover a large opening provided in the center of the upper frame 20. The entire top plate 21 is made of a translucent material that transmits infrared rays, such as heat-resistant tempered glass or crystallized glass, and is formed in a rectangular shape or molded shape according to the shape of the opening of the upper frame 20.

Further, the upper frame 20 includes a right ventilation port 20R, a central ventilation port 20C, and a left ventilation port 20L that are simultaneously punched by a press machine when the upper frame 20 is formed. The right vent 20R, the central vent 20C, and the left vent 20L serve as an intake port or an exhaust port of the main body A.
On the right ventilation port 20R, the central ventilation port 20C, and the left ventilation port 20L, a metal flat plate-like cover 27 in which countless small communication ports are formed so as to cover the entire upper part is detachably mounted. ing. The cover 27 may be a metal mesh or a fine lattice shape, in addition to a metal plate formed with small holes for communication openings by pressing (also called punching metal).
In any case, it is only necessary that the user's finger or a foreign object does not enter the right vent 20R, the central vent 20C, and the left vent 20L from above.

On the top surface of the top plate 21, circular guide marks 3LM, 3RM, 5M indicating rough positions of the left heating port, the right heating port, and the central heating port are displayed by a method such as printing.
An integrated liquid crystal display unit 16 is provided on the front side in the front-rear direction at the center in the left-right direction on the top plate 21, and liquid crystal display screens 15L and 15R are provided on the left and right. The integrated liquid crystal display unit 16 can check the energized state (heating power, time, etc.) of the left and right heating ports, the central heating port, and a heater of the grill heating chamber 7 described later.
On the liquid crystal display screens 15L and 15R, the elapsed time from the start of the timer count when the left and right heating ports are cooked by the timer is measured and displayed in numbers. Various electric / electronic components and light emitting elements (LEDs) (hereinafter referred to as electric components 43) constituting the liquid crystal display screens 15L and 15R are housed in a front component case 42.

On the front surface of the main body case 2, there are provided a door 9 that can be pulled out and a front operation unit 12 provided on both the left and right sides of the door 9.
A window plate made of heat-resistant glass is installed in the central opening 9A of the door 9 so that the inside of the grill heating chamber 7 described later can be visually recognized. The opening / closing operation of the door 9 is performed by pulling out or pushing the handle 9B protruding forward.

  The front operation unit 12 sets the main power switch 13 that turns on / off all the power sources of the heating sources for heating each heating port and the grill heating chamber 7 at the same time, and energization of the left heating port and its energization amount (thermal power) And a right operation dial 14R for setting the energization of the right heating port and the energization amount (thermal power).

  In FIG. 2, the inside of the main body case 2 is roughly divided into a left cooling chamber 6L, a right cooling chamber 6R, a box-shaped grill heating chamber 7, an upper component chamber 8, and a rear exhaust at the rear center. A chamber 10 is defined. These rooms are not completely isolated from each other. For example, the left cooling chamber 6L, the right cooling chamber 6R, the upper part chamber 8, and the rear exhaust chamber 10 communicate with each other.

The front opening of the grill heating chamber 7 is covered by a door 9 so as to be freely opened and closed, and the door 9 is held by a support mechanism of the grill heating chamber 7 so as to be movable in the front-rear direction.
An exhaust duct 11 is provided between the left and right rear exhaust chambers 10. The exhaust duct 11 is connected to an exhaust port (not shown) provided at the rear of the grill heating chamber 7, and discharges air with hot air or odor inside the grill heating chamber 7 to the outside.

The upper and lower partition plates 22L are left partition plates that are installed substantially vertically, and serve as partition walls that separate the left cooling chamber 6L and the grill heating chamber 7 from each other. The upper and lower partition plates 22 </ b> R are also right upper and lower partition plates and serve as a partition wall that separates the right cooling chamber 6 </ b> R from the grill heating chamber 7. Note that the upper and lower partition plates 22L and 22R are installed with a distance of several millimeters from the outer wall surface of the grill heating chamber 7.
The upper and lower partition plates 22L and 22R are each formed with a notch 23 so as not to collide with an air passage unit 300 described later when it is horizontally installed.

Further, a horizontal partition plate 24 that partitions the left and right upper and lower partition plates 22L and 22R into two upper and lower spaces is provided. The upper part chamber 8 is above the horizontal partition plate 24. The horizontal partition plate 24 is installed with a predetermined gap of several mm to 1 cm from the ceiling surface of the grill heating chamber 7.
In the present embodiment, the horizontal partition plate 24 is horizontally attached to the inside of the main body case 2, but as long as the inside of the main body case 2 is vertically divided at the upper surface position of the grill heating chamber 7, A part or all of the horizontal partition plate 24 may be provided to be inclined with respect to the main body case 2.

  A rear partition plate 25 is provided so as to partition the upper part chamber 8 and the rear exhaust chamber 10. The lower part of the rear partition plate 25 has a height dimension so as to be in contact with the horizontal partition plate 24 and the upper end part thereof in contact with the upper frame 20. Two exhaust holes 26 are formed in the rear partition plate 25, and these exhaust holes 26 are for exhausting the cooling air that has entered the upper part chamber 8 to the rear exhaust chamber 10.

  The electromagnetic induction heating cooker according to the present embodiment includes a left heating source 3L, a right heating source 3R, and a radiant central electric heating source 5 (hereinafter referred to as a heating source 5) as heating sources in the upper component chamber 8. I have. Further, a pair of upper and lower radiant electric heating sources (not shown) for the grill heating chamber 7 are provided. The left heating source 3L is provided on the left side of the main body A, the right heating source 3R is provided on the right side of the main body A, and the heating source 5 is provided on the left and right center lines of the main body A near the rear.

The constituent members appearing in the appearance described in FIG. 1 correspond to the constituent members in the main body case 2 described in FIG. 2, as shown in the plan view of FIG. That is, the left heating source 3L, the right heating source 3R, and the heating source 5 are respectively arranged in the main body case 2 below the guide marks 3LM, 3RM, and 5M.
A rear exhaust chamber 10 and an exhaust duct 11 are disposed below the central vent 20C, and suction ports 32B described later are respectively disposed below the left vent 20L and the right vent 20R.

  FIG. 4 is a view showing a state in which main components are removed from the inside of the main body case 2 shown in FIG. As shown in FIG. 4, a fan case 32 and a component case 33 are installed in the left cooling chamber 6L and the right cooling chamber 6R, respectively. Each of the left heating source 3L and the right heating source 3R includes a heating coil unit 100 having a heating coil 110 and a heating coil holding member 120 that holds the heating coil 110. Below the heating coil unit 100, an infrared sensor unit 200 and an air path unit 300 are provided.

The fan case 32 includes a blower 30 therein. The blower 30 uses a centrifugal multi-blade blower (typically, there is a sirocco fan), and uses a blade having a blade 31 fixed to the tip of the rotating shaft of a drive motor.
The fan case 32 is formed with a blower chamber 32A so as to surround the wing portion 31 of the blower 30, the suction port 32B is formed at the upper end of the blower chamber 32A, and the exhaust port 32C is formed at the lower end. The fan case 32 is formed as an integral structure by combining two plastic cases 32D and 32E, for example, and connecting them with a fixing tool such as a screw.

  The component case 33 contains a circuit board 41 on which an inverter circuit for supplying predetermined high frequency power to the heating coil 110 is mounted. The circuit board 41 is mounted with a driving power source / driving circuit for the driving motor of the blower 30 together with the inverter circuit portion.

The component case 33 has a horizontally long rectangular shape as a whole, and is provided with an introduction port 36 for introducing cooling air discharged from the exhaust port 32 </ b> C of the fan case 32 into the component case 33. The component case 33 is installed in the left cooling chamber 6L and the right cooling chamber 6R so that the exhaust port 32C of the fan case 32 and the introduction port 36 of the component case 33 are in close contact with each other.
In the top view of the component case 33, the first exhaust port 34 is separated from the upstream side of the circuit board 41 and the second exhaust port 35 is separated from the downstream side along the direction in which the cooling air discharged from the fan case 32 flows. It is formed in the position.
The second exhaust port 35 is located on the most downstream side of the flow of the cooling air in the component case 33 and has an opening area larger than that of the first exhaust port 34.

  The fan case 32 and the component case 33 configured as described above are inserted and fixed from above into the right cooling chamber 6R and the left cooling chamber 6L in close contact with each other. Then, when the fan case 32 is driven and the blade portion 31 is rotated, air is sucked from the suction port 32B of the fan case 32 and is discharged from the exhaust port 32C as cooling air. The cooling air discharged from the fan case 32 enters the inside of the component case 33 from the inlet 36 of the component case 33, cools the circuit board 41 and is discharged from the second exhaust port 35, and the first exhaust port 34. Are also discharged.

  An air path unit is arranged above the component case 33 so as to overlap the first exhaust port 34 and the second exhaust port 35. A heating coil unit 100 to which the infrared sensor unit 200 is attached is disposed above the air path unit 300.

(Heating coil unit 100)
FIG. 5 is a perspective view showing configurations of the heating coil unit 100, the infrared sensor unit 200, and the air path unit 300. The heating coil unit 100 includes a heating coil 110 and a heating coil holding member 120.
The heating coil 110 is formed by winding a bundle of about 30 thin wires of about 0.1 mm in a spiral shape and winding one or more bundles (hereinafter referred to as “collection wires”) so that the outer shape is circular. Finally, it is formed into a disk shape.
In the present embodiment, an example of a double heating coil having an inner heating coil 110a in which a collecting wire is formed into a disk shape and an outer heating coil 110b provided concentrically on the outside of the inner heating coil 110a is provided. Explained.

  The heating coil holding member 120 is a member that holds the heating coil 110 and has a substantially circular shape with a slightly larger diameter than the heating coil 110. The heating coil holding member 120 has a leg 121 for fixing to the air path unit 300.

(Airway unit 300)
The entire air path unit 300 is molded of plastic and has a step on its upper surface. The high part is referred to as a high part 301 and the low part is referred to as a low part 302. In the present embodiment, the difference in height between the high portion 301 and the low portion 302 is about 10 mm.
The high portion 301 is formed with a plurality of jet ports 303 for jetting cooling air discharged from the component case 33 disposed below. In addition, a wind direction plate 305 is formed at the outlet 303 so as to cover approximately half of the opening. The wind direction plate 305 is provided to control the direction in which the cooling air is blown in order to guide the cooling air blown from the jet outlet 303 toward the rear exhaust chamber 10.
A plurality of jet holes 304 for jetting cooling air discharged from the component case 33 disposed below are formed in the low portion 302. Unlike the jet outlet 303 of the high part 301, the wind direction plate 305 is not provided at the jet outlet 304 of the low part 302.

  In addition, a vent hole 306 having a quadrangular opening is formed at the end of the high portion 301. The ventilation openings 306 are formed so as to be positioned below the liquid crystal display screens 15L and 15R of the top panel B in a state where all the parts are assembled in the main body case 2. Then, the liquid crystal display screens 15L and 15R are cooled by the cooling air blown from the ventilation openings 306.

Inside the air path unit 300, ribs (projections) shaped partition walls 307 and 308 formed in a straight line or a curve by integral molding are formed. By the partition walls 307 and 308, the interior of the air path unit 300 is partitioned into ventilation spaces 311, 312, and 313.
The ventilation space 311 is formed so as to overlap the first exhaust port 34 of the component case 33. Therefore, the cooling air ejected from the first exhaust port 34 is ejected from the ejection port 304 via the ventilation space 311.

  The ventilation space 312 and the ventilation space 313 are partitioned by a partition wall 308. Since a communication port 308A is formed in a part of the partition wall 308, air can flow through each other. The ventilation space 313 is disposed so as to be located above the second exhaust port 35 of the component case 33. Therefore, the cooling air blown out from the second exhaust port 35 is blown out from the ventilation port 306 via the ventilation space 313, while being developed in the ventilation space 312 via the communication port 308 </ b> A. Erupted from.

In addition, on the outer peripheral portion of the air path unit 300, protruding leg holding portions 309 are provided at three locations. The leg holding unit 309 couples the air path unit 300 and the heating coil unit 100 by fixing the leg 121 of the heating coil holding member 120.

(Infrared sensor unit 200)
Next, the infrared sensor unit 200 will be described with reference to FIGS.
The infrared sensor unit 200 includes a sheet metal 210, a case 250 including an upper case 220 and a lower case 240, and an infrared sensor device 230 housed in the case 250.

  The sheet metal 210 is a plate-like member made of a member having high heat dissipation such as aluminum, and is provided on the uppermost part of the infrared sensor unit 200 so as to be in close contact with the upper case 220. The sheet metal 210 is a member for obtaining noise resistance and a heat shielding effect. The sheet metal 210 is provided with a sensor hole 211 through which the infrared sensor device 230 takes in infrared rays. Further, holes 212 and 213 through which screws for screwing the infrared sensor unit 200 to the heating coil unit 100 are formed are formed.

Next, the infrared sensor device 230 includes an infrared sensor 231, a connector 233 (in the present embodiment, a female connector is used), a substrate 232, and a signal line 400.
The substrate 232 is formed with a through hole 232a for positioning with respect to an upper case 220 described later, and various electronic components including an infrared sensor 231 and a connector 233 are mounted on the substrate surface.
The signal line 400 is for transmitting an output signal output when the infrared sensor detects infrared rays to the circuit board 41. The signal line connector 401 for connecting to the connector 233 (in this embodiment) Use male connector). The signal line 400 is electrically connected inside the signal line connector 401, and a signal line is led out from an end surface 401 a of the signal line connector 401.

The connector 233 is located on the rear end side of the surface of the substrate 232, and is mounted on the substrate 232 with the connection portion 233a of the signal line 400 and the connector 401 facing outward from the substrate.
Further, in a state where the signal line connector 401 is connected to the connector 233, the end surface 401 a of the signal line connector 401 positioned opposite to the connection position of the signal line connector 401 and the connector 232 does not overlap the substrate 232 vertically. In addition, the positional relationship of each part is configured.

Next, the infrared sensor 231 includes a thermopile and a lens, and outputs an infrared detection signal emitted from an object to be heated as a voltage. The substrate 232 includes various electronic components that control the amplifier and the infrared sensor 231, and the voltage output from the infrared sensor 231 is amplified by the amplifier to obtain temperature information of the object to be heated.
Then, the temperature information of the object to be heated is output to a control circuit provided in the circuit board 41 connected by the signal line 400 and used for heating control and the like.

  Next, the case 250 is a case that houses the infrared sensor device 230 therein, and when the infrared unit 200 is attached to the heating coil holding member 120, the upper case 220 that is positioned upward (top plate side); The lower case 240 covers the lower opening of the upper case 220.

The upper case 220 has a box shape, a sensor hole 221 facing the infrared sensor 231 of the infrared sensor device 230 is formed on the upper surface, and a signal line 400 connected to the connector 233 on the substrate 232 is formed on the rear surface. A lead-out hole 224 for leading out to the outside of the case 250 is formed.
The infrared sensor 231 of the infrared sensor device 230 detects infrared rays through the sensor hole 221.

In addition, a positioning portion 236 for positioning the substrate 232 that protrudes substantially vertically from the upper surface toward the inside of the case is formed on the upper surface front side of the upper case 200. The positioning part 236 may be formed on the front surface of the upper case.
Further, on the rear side of the upper surface of the upper case 200, a pin 227 that is a protruding portion that protrudes substantially vertically from the upper surface toward the inside of the case is provided. In addition, this pin 227 is provided so that it may become the positional relationship facing the derivation hole 224 in the front-rear direction. Further, the pin 227 may be integrally formed with the upper case.

Next, the lower case 240 has a lid shape that covers the lower opening of the upper case 220, and a pressing portion that holds the substrate 232 held in the upper case 200 from below is formed therein.
The upper case 220 and the lower case 240 are formed with screw holes 222, 223, 241, and 242 for screwing the infrared sensor unit 200 to the heating coil unit 100, respectively.
These screw holes are configured such that the screw holes 222 and 241 communicate with the screw holes 223 and 242 in a state where the lower case 240 is attached to the upper case 220.

Further, engagement protrusions 225 are provided on both the left and right sides of the outer peripheral lower end portion of the upper case 220. An engagement portion 244 is provided at a position corresponding to the engagement protrusion 225 when the upper case 220 is covered on the outer peripheral portion of the lower case 240.
With these structures, when the upper case 220 is put on the lower case 240, the upper case 220 and the lower case 240 can be coupled by engaging the engaging portion 244 with the engaging protrusion 225.

The substrate 232 on which the infrared sensor device 230 is mounted is attached and stored in the case 250 configured as described above as follows.
The board 232 is attached inside the upper case 220 with the signal line connector 401 connected to the connector 233. At this time, the position of the substrate 232 relative to the upper case 220 is determined by fitting the through-hole 232a formed in the substrate 232 into the positioning portion 236 formed in the upper case 220.

In a state where the substrate 232 is attached to the inside of the upper case 220, the pin 227 is positioned at a portion sandwiched between the lead-out hole 224 and the end surface 401 a of the signal line connector 401. At this time, the pin 227 is positioned substantially at the center in the left-right direction of the end surface 401a, and when a plurality of signal lines protrude from the signal line connector 401 as in the present embodiment, the left and right are sandwiched between the signal lines.
The signal line 400 extending from the signal line connector 401 passes through the side of the pin 227, passes through the lead-out hole 224, and is connected to an external device of the case 250. The pin 227 and the connector 400 overlap each other when viewed from the rear (connection direction of the signal line connector 401).

In this state, the pin 227 and the end surface 401a of the signal line connector 401 are in contact with each other or have a positional relationship such that a slight clearance is provided. That is, the pin 227 is in a state where the end surface 401a of the signal line connector 401 is held in a direction in which the connector detaches (the direction in which the pin detaches) or can be held.
After the substrate 232 for mounting the infrared sensor device 230 is attached to the upper case 220 as described above, the lower case 240 covers the lower opening of the upper case 220, whereby the infrared sensor unit 200 is configured. .

When the infrared sensor device 230 is attached to the case 250, the tip of the infrared sensor 231 protrudes from the sensor hole 221 to the outside of the case 250.
As shown in FIG. 12, the infrared sensor unit 200 constituting each part is attached to the back side of the heating coil holding member 120 (the opposite side to the heating coil 110 side) using screws.

In this embodiment, the pin 227 is located at a portion sandwiched between the lead-out hole 224 and the end surface 401a of the signal line connector 401. At least, the positional relationship between the pin 227 signal line and the connector 401 is the rear side. It is only necessary to overlap when viewed from the direction in which the signal line connector 401 is removed.
That is, the pin 227 is located in the direction Y (direction to remove) in which the signal line connector 401 is removed from the connector 233 mounted on the substrate 230.

By configuring each part of the infrared sensor unit 200 as described above, even if the signal line 400 is pulled when the infrared sensor unit 200 is attached to a predetermined position, the pin 227 and the end surface 401a of the signal line connector 401 are The pins 227 hold the end surface 401a of the signal line connector 401 from the direction in which they are pulled because they are in contact or face each other with a slight clearance. it can.
The slight clearance is an interval at which the pin 227 can hold the end surface 401a of the signal line connector 401 when the signal line 400 is pulled.

Further, since the signal line connector 401 directly receives the force acting from the pin 227 when the signal line 400 is pulled, it is possible to prevent the action of stress on the board 232 and to prevent the board from being damaged. Positioning in the front-rear direction of the substrate 232 with respect to 250 (the direction in which the signal line connector 401 and the connector 233 on the substrate are inserted and removed) is possible.
This stabilizes the position of the infrared sensor 231 and enables accurate temperature detection.

Further, when a plurality of signal lines are output from the connector 400 as in the present embodiment, the pins 227 are arranged so that the left and right are sandwiched between the signal lines. It is possible to suppress the rattling of the device.
In addition to the infrared sensor device 230, the above-described connector drop-off preventing structure can be applied as long as another connector is connected to the connector mounted on the substrate.

1 electromagnetic induction heating cooker, 2 body case, 3L left heating source, 3LM guidance mark, 3R right heating source, 3RM guidance mark, 5 radiation type central electric heating source (heating source),
5M guide mark, 6L left cooling chamber, 6R right cooling chamber, 7 grill heating chamber,
8 Upper parts chamber, 9 door, 9A center opening, 9B handle, 10 rear exhaust chamber,
11 exhaust duct, 12 front operation section, 13 main power switch, 14L left operation dial, 14R right operation dial, 15L liquid crystal display screen, 15R liquid crystal display screen,
16 integrated liquid crystal display, 20 upper frame, 20C central vent, 20L left vent,
20R Right vent, 21 Top plate, 22L Vertical partition plate, 22R Vertical partition plate,
23 Notch, 24 Horizontal divider, 25 Rear divider, 26 Exhaust hole, 27 Cover,
30 Blower, 31 Wings, 32 Fan Case, 32A Blower Chamber, 32B Suction Port,
32C exhaust port, 32D, 32E plastic case, 33 parts case,
34 1st exhaust port, 35 2nd exhaust port, 36 introduction port, 41 circuit board,
42 front part case, 43 electrical parts, 100 heating coil unit,
110 heating coil, 110a inner heating coil, 110b outer heating coil,
120 heating coil holding members, 121 legs, 200 infrared sensor units,
210 Sheet metal, 211 Sensor hole, 212, 213 Screw hole, 220 Upper case,
221 sensor hole, 222, 223 screw hole, 224 lead-out hole, 225 engagement protrusion,
227 pin, 230 infrared sensor device, 231 infrared sensor, 232 substrate,
240 Lower case, 241, 242 Screw hole, 244 Engagement part,
250 cases, 300 air duct units, 301 high part, 302 low part,
303 spout, 304 spout, 305 wind direction plate, 306 vent, 307 partition wall,
308 Partition wall, 308A communication port, 309 Leg holder, 311 Ventilation space,
312 Ventilation space, 313 Ventilation space, 400 Signal line 401 Signal line connector 401a End face of signal line connector A Main body, B Top plate

Claims (4)

An infrared sensor device having a substrate on which an infrared sensor and a first connector are mounted, and a signal line provided with a second connector connected to the first connector;
An opening for passing the signal line and a sensor hole facing the infrared sensor are formed, and a case for accommodating the infrared sensor device inside is provided.
A through hole is formed in the substrate,
The first connector is mounted on the board in a state where the first connector is located at a rear end of the board and a connection portion connected to the second connector is directed outward with respect to the board;
In the state where the second connector is connected to the first connector, the end surface of the second connector located in the direction to be removed from the first connector has a positional relationship that does not overlap with the substrate.
The case is composed of an upper case and a lower case, and the upper case is formed with a positioning portion and a pin that project substantially vertically toward the inside of the case ,
In the state where the infrared sensor device is attached to the case, the positioning portion is fitted into the through hole, and determines the position of the substrate with respect to the upper case.
The pin is located in contact with the end face or with a slight clearance between the pin and the end face in a state where the infrared sensor device is attached to the case. unit. 2. The infrared ray according to claim 1, wherein the pin is a position sandwiched between an opening through which the signal line passes and an end face located in a direction in which the second connector is detached from the first connector. Sensor unit. 3. The infrared sensor unit according to claim 1, wherein a plurality of signal lines are led out from an end face of the second connector, and the pins are sandwiched between the signal lines. 4.   An electromagnetic induction heating cooker using the infrared sensor unit according to claim 1.

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