JP2638473B2 - Electromagnetic rice cooker - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of an electromagnetic rice cooker.

[0002]

2. Description of the Related Art Recent electromagnetic rice cookers (so-called IH jars) generally have a temperature sensor at the lower portion of an inner pot and a heating portion such as a work coil and a switching transistor for operating the work coil, as shown in FIG. It is provided with a cooling fan for cooling.

[0003] That is, the electromagnetic rice cooker shown in FIG. 12 is used for, for example, cooking rice and keeping heat.
(Rice) 2 is provided with a container main body including a bottomed cylindrical outer case 3 configured to be able to set a rice cooker 2 thereon, and a lid unit 4 for covering the upper part of the outer case 3.

The outer case 3 is composed of a bottomed cylindrical cover member 3a made of synthetic resin and a synthetic resin shoulder member 3b joined to the upper end of the cover member 3a. A coil stand 7 for supporting the work coils 6a and 6b from the lower side to the upper side and the inner pot 3;
A bottomed cylindrical inner case 5 for sequentially setting the inner case 5 is provided in order.

The inner case 5 has an upper end engaged with the shoulder member 3b, has a heater 6c at the center in the vertical direction of the outer peripheral surface, and has a cylindrical upper inner case formed of a thin metal plate. 5A, and a lower inner case 5B made of a synthetic resin and engaged with the lower end of the upper inner case 5A. The inner pan 2 has a predetermined gap space 23B inside thereof as shown in FIG. It is set in the state. A center sensor fitting opening is formed at the center of the bottom of the lower inner case 5B, and an opening edge of the lower coil base 7 is extended in a sleeve shape in the vertical direction so that the inner side of the cylindrical body 30 is formed. Is formed with a sensor storage space 23A communicating vertically. A center sensor 22 that resiliently contacts the back surface of the bottom 2a of the inner pot 2 is provided in the sensor storage space 23A of the cylindrical body 30,
It is supported by the lid 29a of the sensor cover 29 fitted and fixed to the lower opening of the cylindrical body 30.

The center sensor 22 is a temperature detection sensor for detecting the temperature of the inner pan 2 and the non-set state of the inner pan 2
Temperature sensor that acts as an inner pan detection sensor that detects (empty state), and serves as a temperature detector for inner pan temperature control
(Thermistor) 24, a temperature fuse 26 as an abnormal temperature detecting means at the time of abnormal heating of the inner pot, and an inner pot set detection sensor 15 for detecting whether or not the inner pot 2 is set.

The center sensor 22 is disposed in the cylindrical sensor housing space 23A formed in the cylindrical body 30 of the coil mount 7 as described above, and is disposed so as to be movable up and down. The sensor holder 22a having the temperature sensor 24 and the temperature fuse 26 built therein, and the sensor holder 22a is located between the sensor holder 22a and the lid 29a of the sensor cover 29, and the sensor holder 22a is lifted upward (that is, the inner pot 2). And a coil spring (not shown) that urges the bottom 2a in the direction of contact with the back surface.
The upper end surface of the sensor holder 22a is a substantially circular flat surface, and a sensor cap 28 having a high thermal conductivity, which is in contact with the bottom surface of the inner pan 2, is provided in a crowned manner.

Further, the inner pot set detection sensor 15
Are reed switches 17 provided at opposing positions on both left and right outer peripheral sides of the sensor holder 22a.
(On the front side of the drawing) and the magnet 18 (on the side facing the drawing), and inserted between the reed switch 17 and the magnet 18 when the sensor holder 22a is moved downward (in other words, when the inner pot is set), which is located between them. And a magnetic shielding plate 19.

The cover 29 of the sensor cover 29
a, water is injected into the inner case 5 when the sensor holder 22a is raised and the inner pot is not set, and
25, a water discharge port 122 for dropping and storing
122 are formed.

Further, on the lower surface of the lower inner case 5B, annular work coils 6a and 6b supported by the coil stand 7 so as to surround the center sensor 22 are efficiently provided with eddy current to the inner pot 2. Are arranged in such a state as to be able to generate the following. The work coils 6a and 6b function as magnetic force generating means in the electromagnetic induction heating device. Reference numerals 20, 20,... Indicate work coils 6a, 6b.
Are magnetically shielded so that the magnetic force generated by the ferrite cores does not affect the underlying equipment, and the ferrite cores 20, 20,.
It is arranged with an interval.

On the other hand, the lid unit 4 has a synthetic resin outer cover 37 forming the outer peripheral surface thereof, and a synthetic resin inner cover (inner frame portion) forming the outer peripheral annular portion of the inner peripheral surface.
38 and a heat radiating plate 57 for covering an opening in the inner peripheral portion of the inner cover 38, to form a hollow structure. A lid heater 56 is provided on the upper surface of the heat sink 57. The lid unit 4 is rotatably attached to one side of the shoulder member 3b via a hinge mechanism 40, and has an open end engaged with a predetermined position of the lid unit 4. A lock mechanism (lock lever) 39 for keeping the lid unit 4 closed is provided.

A sleeve-shaped vapor discharge port 79 is formed between the outer cover 37 and the inner cover 38 side heat radiating plate 57 at the center of the lid unit 4 so as to communicate with each other in the vertical direction. A steam discharge cylinder 44 having a hat-shaped cross section is fitted and fixed in the discharge port 79 as shown in the figure. The steam discharge tube 44 has a large-diameter flange portion 90 on the outer periphery of the lower wall, and a relatively high-rigidity first cylinder wall portion 90a on the upper side of the flange portion 90, and a thin wall portion that can be bent to the lower side. Each of the second cylindrical wall portions 90b has a low rigidity, and the first cylindrical wall portion 90a is provided on the lower edge portion 7 of the sleeve-shaped steam discharge port 79.
9a from below and the second cylindrical wall portion 90b is connected to the upper edge 92a of the opening 92 of the heat dissipation plate 57 on the inner cover 38 side.
The cover unit 4 is sandwiched and fixed between the outer case 37 of the lid unit 4 and the heat radiating plate 57 on the inner cover 38 side.

A pressure adjusting port 93 is formed at the center of the top wall 90c.

In the lower part of the coil stand 7, there are provided a microcomputer unit for controlling the energization of the work coils 6a and 6b, the lid heater 56, the heat retaining heater 6c and the like, and various control circuits having switching transistors. The provided control board 36 is fixed. An operation panel 170 constituting an operation section is provided on the side of the shoulder member 3b opposite to the hinge mechanism 40. The operation panel 170 is provided with various switches required for rice cooking, and a display unit for displaying a rice cooking menu, a switch level, and the like selected by each of the switches and displaying them to the user. .

Reference numeral 78A denotes the work coil 6.
A cooling fan 78B for cooling a heat generating portion such as a switching transistor (not shown) for activating the work coils 6a and 6b, and 78B is a fan motor serving as a driving source thereof. The cooling fan 78A and the fan motor 78B are located in a space below the control board 36 in the outer case 3. When the fan motor 78B is driven, the cooling fan 78A is rotated, and the cooling air is supplied to the above-described work coils 6a and 6b and the switching transistor on the control board 36.
(Ventilation air) is blown to perform cooling, and the cooling air after cooling is discharged from the ventilation air outlet 31 at the rear of the housing.

[0016]

However, by driving the fan motor 78B as described above, the sensor housing space 23
By rotating the cooling fan 78A on the lower side of FIG.
In the case of the configuration 2, the sensor storage space 23 </ b> A is used to discharge the injected water into the inner case 5 when the inner pan is not stored.
Are the water outlets 122, 1 of the lid 29a of the sensor cover 29.
Since the sensor housing space 23A is completely opened to the lower side via the inner case 22, the sensor housing space 23A eventually forms a communication passage into the inner case 5, and the inner case 5 and the inner case 5 are formed by the wind pressure of the cooling fan 78A. When the air pressure in the lower space of the coil stand 7 (below the sensor housing space) rises, on the other hand, the gap space 23B between the inner pan 2 and the inner case 5 communicating with the outer space near the upper inner pan locking portion. Since the air pressure on the side of the cooling fan 7 is relatively low, as shown by the arrow in FIG.
The ventilation flow by 8A passes through the sensor storage space 23A that forms the communication path and passes through the gap space 23B between the inner pot 2 and the inner case 5 to the outside of the opening at the upper end of the outer case 3. Become.

As a result, the temperature sensor (thermistor) 24 which is the temperature sensing part of the center sensor 22 is unnecessarily cooled by the cooling air, and the temperature of the inner pot 2 can be accurately detected. The problem that disappears occurs. As a result, accurate and stable total number determination cannot be performed. Further, the inner pot 2 itself is also cooled over a wide range from the bottom 2a to the peripheral wall 2b, and there is a problem that the heating efficiency is reduced.

The present invention has been made in view of the above circumstances, and when the temperature sensor and the inner pan in which the cooling fan operates is set, the temperature sensor in the sensor storage space in the lower space of the sensor storage space is set. By blocking the passage of the cooling air to the gap space between the inner case and the inner pan through the above, it is possible to ensure accurate temperature detection performance of the temperature sensor and to prevent a decrease in the heating efficiency of the inner pan itself. It is an object of the present invention to provide an electromagnetic rice cooker as described above.

[0019]

SUMMARY OF THE INVENTION The present invention is provided with the following means for solving the problems in order to surely solve the above-mentioned conventional problems and effectively achieve the object.

That is, the electromagnetic rice cooker of the present invention comprises: a container main body comprising an outer case and an inner case; a coil stand provided inside the container main body; and an inner pot accommodated in the inner case. A work coil provided on the coil base for heating the inner pot; a temperature sensor for detecting an inner pot temperature provided in a sensor storage space forming a communication passage into the inner case; An electromagnetic rice cooker comprising a cooling fan provided below the space,
When the inner pan is stored in the inner case, the communication passage is closed to prevent the cooling air from the cooling fan from entering the inner case, and when the inner pan in the inner case is taken out, the communication path is closed. A seal member for opening the passage is provided in the sensor storage space forming the communication passage.

The seal member is made of, for example, a cylindrical elastic member, and is arranged so as to be able to bend in the up-down direction so as to surround the outer periphery of the upper opening end of the sensor housing space.

Further, the seal member is formed of a ring-shaped elastic member having a lip portion, and is fitted to a lower position of the temperature sensor in the sensor storage space.

[0023]

Therefore, in the configuration of the electromagnetic rice cooker according to the present invention, the electromagnetic rice cooker is formed of, for example, a tubular elastic member disposed so as to be able to bend in the vertical direction and to surround the outer periphery of the upper opening end of the sensor housing space. The inner case in the inner pot storage state by the sealing function of the seal member, and further by the sealing function of the seal member made of a ring-shaped elastic member having a lip portion and fitted at the lower position of the temperature sensor in the sensor storage space. The communication passage of the sensor storage space that forms a communication passage to the clearance space between the inner pan and the inner pan is closed, and the ventilation flow by the cooling fan passes through the sensor storage space through the clearance space between the inner case and the inner pan. Will not be distributed.

Therefore, intrusion of cooling air into the sensing part of the temperature sensor such as a thermistor in the sensor storage space is prevented, and the sensing part is cooled by the ventilation flow, and erroneous detection is prevented.

Further, since the inner pot is not cooled at the same time, the heating efficiency of the inner pot is not reduced.

On the other hand, when the inner pot is taken out, the sealing function of the sealing members is released, and the communication path is opened.

[0027]

As described above, according to the electromagnetic rice cooker of the present invention, it is possible to secure the accurate inner pot temperature detection performance of the temperature sensor, and to secure the accurate and stable total number judgment performance. It becomes possible to provide an electromagnetic rice cooker with high heating efficiency without heating loss.

[0028]

(Embodiment 1) FIGS. 1 to 5 show the configuration of an electromagnetic rice cooker according to Embodiment 1 of the present invention.

First, the rice cooker 1 of this embodiment is configured to serve, for example, rice cooking and heat retention. And FIG.
As shown in FIG. 2, a bottomed cylindrical outer case 3 formed so that an inner pot (rice cooker) 2 can be set therein, and a lid unit 4 for covering the upper part of the outer case 3 are provided. Container body.

The outer case 3 includes a cylindrical cover member 3a formed of a synthetic resin plate, a synthetic resin shoulder member 3b fused to the upper end of the cover member 3a, and the cover member 3a. And a bottom member 3c made of synthetic resin that is fusion-bonded to the lower end of the inner pan 2. Inside the bottom, the inner pan 2 is set so that the inner pan 2 can be taken out. Inner case (protection frame) 5, work coil 6a, 6
b, The coil bases 7 are provided in a vertically stacked manner.

First, the lowermost coil stand 7 has an inner case supporting surface 8a in the shape of a saucer, and the work coil 6a,
6b, and ferrite core fitting grooves 9, 9 formed in the work coil support portion 8.
And legs 10, 10 provided below the work coil supporting portion 8, and are supported on the bottom plate 11 of the bottom member 3c by the legs 10, 10. On the outer peripheral surface of the side of the work coil supporting portion 8 of the coil stand 7, one end (outer peripheral end) of the ferrite core fitting grooves 9, 9,. Spacer pieces 13,
A ring-shaped magnetic shielding plate 14 is fitted and fixed around the outer periphery of the spacer 13 while maintaining a predetermined interval via the spacer pieces 13 and 13.

The ferrite core insertion grooves 9, 9.
.. are formed in a state in which they extend in the radial direction, for example, at intervals of 90 degrees in the circumferential direction, and penetrate vertically, and at a lower portion thereof, are spaced apart by a predetermined distance in the radial direction. Ferrite core locking pieces 12, 12 are provided.
The ferrite core engaging pieces 12, 12 are formed integrally with the work coil supporting portion 8 between the side walls 9a, 9a of the ferrite core fitting grooves 9, 9,.... And the ferrite cores 20, 20,.
Are fitted into the ferrite core fitting grooves 9, 9... From the outer peripheral side toward the radial center, and the lower surface side is locked by the ferrite core locking pieces 12, 12. It is supported as shown. When the fitting is completed, the front ends 20a of the ferrite cores 20, 20,... Are abutted against the regulating ribs 21, and the rear ends 20b are locked by the locking ribs 25, so that the ferrite cores 20, 20,. Then, the adhesive is dried to be completely joined to the back surface of the work coil supporting portion 8.

As described above, according to the mounting and fixing structure of the ferrite core 20, the adhesive such as a silicone resin is applied to the back surface of the work coil supporting portion 8 of the coil base 7 without providing the locking pieces 12 and 12 as described above. Unlike the case where only the adhesive is fixed with only the tip, the end 20a side, which is a round surface from the outer peripheral side, is inserted and inserted into the ferrite core fitting insertion grooves 9, 9,. be able to.

Further on the work coil support 8 of the coil base 7, together with the rib L ₃ for work coil pressing is provided, also has a temperature fuse holders 150 standing upright on the cross-section H-shaped is provided, the Thermal fuse holder 1
Reference numeral 50 denotes a temperature fuse 26 for detecting an abnormal temperature necessary for safety standards, which is supported in contact with the bottom 5b of the inner case 5.

The center of the bottom of the inner case 5 and the center of the work coil supporting portion 8 of the coil stand 7 penetrate vertically and concentrically, as shown in detail in FIG. Storage space 23A of center sensor 22
Is formed to extend downward, and a center sensor 22 for detecting the temperature of the inner pot is provided in the center sensor storage space 23A so as to be vertically movable and constantly urged upward. Have been. And the center sensor 2
A communication passage 23c into the inner case 5 is formed between an outer peripheral edge 28a of the sensor cap 28 described later and the coil stand 7 and the inner case 5. The center sensor storage space 23A is a tube in which half-walled cylindrical wall portions 30A, 30B extending downward from the center of the coil stand 7 and the center of the bottom of the inner case 5 at different positions by 180 ° are integrally opposed to each other. The sensor cover 2 is formed in the body 30 and has a lower opening.
9 is fitted into the cylindrical body portion 29d, and a screw 32 is used with a screw 32 through an outer peripheral edge 29e of the lid portion 29a.
The boss portion A is integrally fastened and fixed.

As shown in the figure, the sensor cover 29 is provided with a sensor storage space 23A in the cylinder body 30 on the coil mount 7 side.
A cylindrical water discharge guide 29b is provided below the lid 29a for closing the lower opening of the center sensor storage space 23A when water is injected into the upper inner case 5 of the center sensor storage space 23A when the inner pan is not stored. Water that enters the sensor storage space 23A through the communication passage 23c is introduced through the water outlets 122, 122 formed in the lid 29a, and is not scattered to the side of the control board 36 provided on the side. Water receiver 125 immediately below
It can be dropped inside and taken out of the container.
At the upper end of the opening of the communication passage on the inner case 5 side of the center sensor storage space 23A, the lower space between the center sensor storage space 23A and the inner case 5 and the inner pan 2 when the inner pan is set. A rubber-made thin cylindrical seal member (seal member made of a bendable elastic member) 100A is provided to block communication with the gap 23B. The sealing member 100A has a lower edge 102
Is fitted and fixed to the upper ends of the cylindrical walls 30A and 30B (the upper ends of the openings of the cylindrical body 30), and the upper edge 101 thereof is bent outward in the radial direction so that the bottom 2a of the inner pan 2 is As shown in the figure, the contact between the communication passage 23c on the side of the center sensor storage space 23A and the gap space 23B between the inner case 5 and the inner pot 2 is set. Communication is blocked. Therefore, air does not flow between the two spaces.

As shown in FIG. 2, the center sensor 22 has a temperature sensor (thermistor) 24 provided at the upper end of the sensor holder 22a for controlling both the inner pot temperature control and the abnormal temperature detection control. A sensor cap (lid) 28 made of a metal material having good heat conductivity is integrally fitted and fixed to the upper surface of the upper end of the sensor holder 22a. For example, it is supported by a coil spring 27 interposed between the intermediate edge 92a of the sensor holder 22a and the lid 29a of the sensor cover 29 so as to be vertically movable and urged upward. The rising position of the center sensor 22 is determined by the cylindrical portion 2 of the sensor cover 29.
It is regulated by locking the upper surface of the center holder 22a with the locking edge provided at the upper end 29c of the 9d.

Then, the sensor cap 28 of the center sensor 22 is attached to the upper surface of the coil spring on the back surface of the bottom portion 2a of the inner pot 2 which is set in the inner case 5 while maintaining a predetermined gap 23B. Close contact with pressure,
In the contact state, the temperature of the inner pot 2 is detected by the temperature sensor (thermistor) 24.

A control board 36 having a control circuit formed mainly of the switching transistor and the rice cooker control unit (microcomputer) is provided below the coil stand 7.

Reference numeral 78A denotes the work coil 6a,
A cooling fan for cooling a switching transistor (not shown) for activating the work coils 6b and the work coils 6a and 6b, and a fan motor 78B as a drive source thereof. The cooling fan 78A and the fan motor 78B
Is located in a space below the control board 36 in the outer case 3. The fan motor 78
When B is driven, the cooling fan 78A is rotated, and ventilation air is blown to the above-described work coils 6a and 6b and the switching transistor on the control board 36 to perform cooling. Is discharged from the ventilation wind outlet 31 at the rear of the outer case.

In the drawing, L ₁ and L ₂ are work coil engaging ribs formed on the back surface of the bottom portion 5b of the inner case 5, and L ₃ is a work coil holding rib on the coil base 7 side as described above.

On the other hand, the lid unit 4 has an outer case 37 made of synthetic resin constituting the outer peripheral surface thereof and an inner cover (inner frame portion) made of synthetic resin constituting the outer peripheral side annular portion of the inner peripheral surface.
38, and a heat radiating plate 57 for covering an opening in the inner peripheral portion of the inner cover 38. The outer case 37 and the radiating plate 57 are formed in a hollow structure. Are connected to each other through the peripheral portion. The lid unit 4 is rotatably attached to the shoulder 3b via a hinge mechanism 40, and has an open end engaged with a predetermined position of the lid unit 4 to A lock mechanism 39 for maintaining the closed state is provided. The lock mechanism 39 is also configured as a lock release lever.

In the above state, a glass wool 58 having a high heat insulating property is interposed between the heat radiating plate 57 having the lid heater 56 and the outer cover 37.
Insulation on the surface side is attempted. As a result, the effect of improving the safety and the heat retaining effect is realized.

Further, an opening 43 for attaching a vapor discharge tube is formed substantially at the center of the lid unit 4. A packing 5 is provided in the opening 43 for mounting the steam discharge cylinder.
A steam discharge cylinder 44, which will be described later, is attached via the “0”.

As shown in the figure, the steam discharge pipe 44 has a steam discharge pipe 44b integrated with an upper portion of the rear end of an elliptical main body 44a extending in the front-rear direction, and an upper end surface of the steam discharge pipe 44b. Grill-like steam discharge port (pressure control port) 42
are formed on the front end bottom 45a of the main body 44a, and a bottom return hole 46 is opened downward, and a bottom introduction hole 47 is formed on the side wall thereof. It is pierced in the direction. Further, a steam introduction hole 48 is formed in the front end ceiling wall portion of the main body portion 44a.
Is drilled downward. And the main body 44
a, the height of the rear end side bottom 45b is high, and the front end side bottom 45a
Is formed to have a low height, and the bottom 45 has an inclination angle θ such that the bottom 45 itself becomes gradually lower from the rear end side to the front end side.

On the outer periphery of the base of the steam discharge pipe portion 44b of the steam discharge tube 44, a mountain-shaped engaging projection 51 for engaging and fixing the steam discharge tube 44 to the lid unit 4 is formed. It is provided in a state of protruding from.

On the other hand, the packing 50 is provided on the upper section Y with respect to the two locking walls 52a, 52b extending in the form of a sleeve below the opening of the vapor discharge cylinder mounting opening 43.
The engagement pieces 50a, 50b are press-fitted into engagement, and the engagement pieces 50c, 50d having a Y-shaped cross section on the lower side are press-fitted into an opening edge 57a formed in an upright state at the center of the heat sink 57. A concave portion 54 with which the projection 51 of the vapor discharge pipe portion 44b can be engaged is formed in the inner peripheral surface at a substantially middle portion in the vertical direction.

When the steam discharge pipe portion 44b of the steam discharge tube 44 is completely inserted into the packing 50 of the steam discharge tube mounting opening 43 of the lid unit 4 from below, the steam discharge pipe portion 44b is inserted. 44b of the engaging projection 5
1 is resiliently press-fitted into the engaging recess 54 of the packing 50, and the entire steam discharge cylinder 44 is detachably attached to the lid unit 4 in the state shown in the drawing. On both side walls of the main body portion 44a of the vapor discharge cylinder 44, detachable finger engaging claw members 55a, 55a are provided to extend in the left-right direction, and at the time of removal, the claw members 55a, 55a are provided. The user can easily remove the "needle" by washing it with his / her finger and pulling it downward.

The reference numeral 2c in the figure denotes a locking edge of the inner pot 2,
59 is a packing between the locking edge 2c of the inner pot 2 and the inner cover 38 on the lid unit 4 side.

On the other hand, on the shoulder 3b of the outer case 3 on the side opposite to the hinge mechanism 40, an operation panel 170 constituting an operation section is provided. The operation panel 170 includes various switches 17 necessary for cooking rice as shown in FIG.
1, 173, 176, 177, and rice display menus 172, 17 for displaying a rice cooking menu, a switch level, and the like selected by each of the switches so as to be visually recognized by the user.
4,175 are provided.

As described above, in the configuration of the electromagnetic rice cooker of this embodiment, the lower edge 102A of the cylindrical rubber seal member 100A is provided.
Is fitted to the outer periphery of the upper end of the opening of the center sensor storage space 23A of the inner case 5 forming the communication path 23c as shown in the figure, and the upper edge 101 is radially outward when two inner pans are set. Center sensor 22
The communication state of the communication passage 23c communicating from the storage space 23A to the space 23B between the inner case 5 and the inner pot 2 is shut off.

Therefore, as is apparent from FIG. 5, in the configuration of the electromagnetic rice cooker of this embodiment, the sensor storage space 2
3A, the outer peripheral edge 28 of the sensor cap 28
Even if there is a communication path 23c due to the gap between the inner case 5 and the inner pot 2, the gap space 23B between the inner case 5 and the inner pot 2 is formed by the sealing function of the sealing member 100A made of the cylindrical rubber member.
The cooling fan 78A-side sensor housing space 23A does not communicate with the cooling fan 78A, and the ventilation flow from the cooling fan 78A does not enter the center sensor housing space 23A and flow through the temperature sensor (thermistor) 24.

For this reason, the center sensor 22
The thermistor 24, which is the sensing unit of the above, is cooled by the ventilation flow, and no erroneous detection is made.

Since the inner pot 2 is not cooled at the same time, the heating efficiency of the inner pot 2 is not reduced.

As a result, the temperature sensor of the center sensor 22
(Thermistor) 24 can ensure accurate inner pot temperature detection performance, and can provide an accurate and stable total number determination and provide an electromagnetic rice cooker with high heating efficiency without heating loss.

In the sealing member 100A having the above structure,
There is no hindrance to draining the water injected into the inner case 5 downward when the inner pan is not stored.

(Embodiment 2) Next, FIG. 6 shows a structure around a center sensor of an electromagnetic rice cooker according to Embodiment 2 of the present invention.

In the configuration of the electromagnetic rice cooker according to the present embodiment, the lower end 102 of the cylindrical rubber seal member 100B having the same function as the seal member 100A of the first embodiment is connected to the communication passage 23c as shown in the figure. The center sensor storage space 23A of the inner case 5 is fitted to the outer periphery of the upper end of the upper end side opening, and the upper edge portion 101 is elastically bent inward in the radial direction when the inner pan 2 is set, thereby forming the center sensor 22. From the storage space portion 23A to the gap space portion 23 between the inner case 5 and the inner pan 2
The communication state of the communication path 23c communicating with B is cut off.

Therefore, in the configuration of the electromagnetic rice cooker of the present embodiment, the gap between the inner case 5 and the inner pot 2 is made by the sealing function of the sealing member 100B made of a rubber member, just like the case of the first embodiment. The cooling fan 78A-side sensor storage space 23A is not communicated with the space 23B, and the ventilation flow from the cooling fan 78A enters the center sensor storage space 23A and the temperature sensor (thermistor) 24.
There is no need to distribute the department.

Therefore, the temperature sensor (thermistor) 24, which is the sensing part of the center sensor 22, is cooled by the ventilation flow, so that erroneous detection does not occur.

Further, since the inner pot 2 is not cooled at the same time, the heating efficiency of the inner pot 2 is not reduced.

As a result, the temperature sensor of the center sensor 22
(Thermistor) 24 can ensure accurate inner pot temperature detection performance, and can provide an accurate and stable total number determination and provide an electromagnetic rice cooker with high heating efficiency without heating loss.

Further, even with the sealing member having the above configuration, there is no hindrance to discharging the water into the inner case 5 in a state where the inner pot is not stored.

Third Embodiment Next, FIGS. 7 and 8 show a structure around a center sensor of an electromagnetic rice cooker according to a third embodiment of the present invention.

In the configuration of the electromagnetic rice cooker according to the present embodiment, the cylindrical body 30 for forming the center sensor storage space 23A is formed at the center of the coil mount 7, and the seal members 100A, A rubber sealing member 100C having the same sealing function as 100B is formed by a ring-shaped member having a lip portion 105, and is fitted and fixed to the sensor holder 37 of the center sensor 22 as shown in the figure. When the inner pot 2 is set, the lip portion 105 is inscribed in the upper inner peripheral wall surface TA of the cylindrical body portion 30 so that the first and second two sets of temperature sensors of the center sensor storage space 23A are provided. (Thermistor) The space between the sides 24A and 24B and the space below the cooling fan 78A are partitioned. At the same time, the lower space of the cooling fan 78A side and the clearance space 2 between the inner case 5 and the inner pot 2 are simultaneously formed.
The communication state of the communication path 23c with 3B is shut off (see the state of FIG. 8).

That is, in the electromagnetic rice cooker of this embodiment, it is located at the center of the bottom of the inner case 5 and at the center of the work coil support of the coil stand 7 and is concentric in the vertical direction as shown in detail in FIGS. A storage space 23A for the center sensor 22 penetrating therethrough is formed. The storage space 23A is vertically movable in the center sensor storage space 23A, and is constantly urged upward by the coil spring 27. And center sensor 22 for inner pot temperature detection and inner pot detection
Is provided. In the case of the present embodiment, the center sensor storage space 23A is located at the center of the coil base 7 and extends in both up and down directions.
0. The cylindrical portion 29d of the sensor cover 29 is fitted from the lower opening thereof, and the sensor cover 29 is formed on the cylindrical portion 30 of the coil mount 7 with screws 32 via the outer peripheral edge 29e. It is fastened and fixed to the boss 30a.

The sensor cover 29 is, as shown in FIG.
A cylindrical water discharge guide 29b is provided below the lid 29a that closes the lower opening of A, and through the communication passage 23c when water is injected from above the center sensor storage space 23A when the inner pan is not stored. The intruded water is introduced through the water outlets 122 formed in the lid 29a, and is not directly scattered to the side of a control board (not shown) provided on the side. (Not shown) and can be taken out of the container. The lid 29a
The water outlets 122, 122 have two legs 37b, 37b of a sensor holder 37 described later, which are freely fitted up and down so as to be able to freely move up and down, so as to perform a function of guiding the sensor holder 37 up and down.

The center sensor storage space 23
A shelf 30c having a hook-shaped cross section is formed inside the upper edge 30b of the opening of the cylindrical body 30 forming the portion A.
The bottom 5b of the inner case 5 is located near the upper edge 30b of the inner case 5c.
The inner case 5 is supported in such a manner that the rib 113 is placed thereon. The diameter of the opening 121 of the inner case 5 is formed smaller than the diameter of the opening on the upper end side of the cylindrical body portion 30, and the opening edge covers the center sensor storage space 23 </ b> A.

The inner surface of the peripheral wall of the cylindrical body 30 is formed in a V-shape in cross section, whereby the upper first tapered surface whose diameter is gradually reduced from the upper side to the lower side as shown in the figure. TA and a lower second tapered surface TB whose diameter gradually increases from the upper side to the lower side are formed.

On the other hand, the center sensor 22 is provided in the upper end 37a of the sensor holder (sensor cylinder main body) 37 having a cylindrical structure having two legs 37b, 37b on the lower side as described above. The sensor mounting member 110 to which the temperature sensors (thermistors) 24A and 24B and the reed switch 17 are mounted.
A sensor cap (lid) 28 made of a metal material having good heat conductivity is integrally fitted and fixed to the upper surface of the upper end of the sensor holder 37. A first edge 114 for coil spring engagement is provided in the middle of the cylindrical portion of the sensor holder 37,
The sensor holder 22a is supported by the coil spring 27 interposed between the first edge portion 114 for engagement with the coil spring and the lid portion 29a of the sensor cover 29 so as to be able to move up and down and urge upward. ing.

A second edge 115 is provided below the sensor cap 28 in the cylinder of the sensor holder 37, and a second edge 115 is provided between the second edge 115 and the first edge 114. A seal member fitting groove 106 is formed. A ring-shaped seal member 100C having a flat lip portion 105 formed on the outer periphery as shown in the figure is fitted and fixed to the seal member fitting groove 106.

The seal member 100C is made of an elastic member such as a rubber member (for example, silicon rubber), and the lip portion 105 is configured to be elastically deformable in the vertical direction while having appropriate rigidity. . The outer shape of the lip portion 105 is set to be slightly larger than the inner diameter of the upper end of the upper first tapered surface TA of the cylindrical body portion 30.

The seal member 100C is provided in the inner case 5
In the state of FIG. 7 in which the inner pot 2 is not set inside, the upper part is located above the upper end of the opening of the cylindrical body 30 and does not fit in the cylindrical body 30. As shown by the line, the opening 121 of the inner case 5 and the sensor cap 28
The sensor cover 29 is freely discharged toward the water discharge guide 29b through the communication passage 23c formed between the outer peripheral edges 28a of the sensor cover 29.

On the other hand, the inner pan 5
Is set, and when the sensor holder 37 is lowered against the urging force of the coil spring 27, the lip portion 105 is moved to the first tapered surface T in the cylindrical body portion 30.
A cooling fan which is fitted to the portion A and is located below the sensor cover 29.
(See 78A in FIG. 1) The sealing is ensured so that the cooling air from the first and second thermistors 24A and 24B does not enter the space through the communication passage 23c.

Therefore, in the configuration of the electromagnetic rice cooker according to the present embodiment, the center sensor storage space 23A via the communication passage 23c by the sealing function of the sealing member 100C made of a rubber member, just like the case of the first embodiment. The space between the upper first and second temperature sensors 24A and 24B and the clearance space 23B between the inner case 5 and the inner pot 2 does not communicate with the cooling fan (78A) side space, and the cooling fan
(78A) ventilation flow by center sensor storage space 23A
The first and second temperature sensors 24A, 2
There will be no circulation around 4B.

Therefore, the first and second temperature sensors 24A and 24B, which are the sensing units of the center sensor 22, are cooled by the ventilation flow, so that erroneous detection does not occur. In addition, the fitting between the lip portion 105 of the sealing member 100C and the cylindrical body portion 30 is performed using the first tapered surface TA having a gradually decreasing diameter from the upper side to the lower side. I do.

Further, since the inner pot 2 is not cooled at the same time, the heating efficiency of the inner pot 2 is not reduced.

As a result, the first and second
Accurate inner pot temperature detection performance of the temperature sensors 24A and 24B can be secured, and accurate and stable inner pot temperature control,
Combination judgment and abnormal temperature detection become possible.

In the sealing member 100C having the above structure,
There is no hindrance to discharging the water injected into the inner case 5 in a state where the inner pot is not stored.

As shown, the sensor mounting member 110 in the sensor holder 37 is partially extended downward, and a reed switch mounting portion 112 having a U-shaped cross section is provided at the lower end of the extended portion 111. Is formed. The reed switch 17 is mounted on the reed switch mounting portion 112. On the other hand, when the sensor holder 37 is lowered, a magnetic force corresponding to the reed switch 17 is acted on the lid 29a of the sensor cover 29 below it,
A magnet 18 is provided to detect that the inner pot 2 is set by turning on the reed switch 17. Accordingly, this enables the empty detection of the inner pot 2 to be performed.

By the way, in the configuration of FIGS. 7 and 8, the upper first tapered surface T is formed in the cylindrical body 30 as described above.
A, the lip portion 105 of the seal member 100C is configured to be fitted in a high density and smoothly. However, for example, the outer diameter of the lip portion 105 is changed to the upper end side opening portion of the cylindrical body portion 30. While the sensor holder 37 of the seal member 100C is formed.
7 or 8, or the position of the shelf 30C at the upper end of the opening of the cylindrical body 30 is the position of FIGS. 7 and 8. When the sensor holder 37 is lowered, the large-diameter lip portion 105 can be placed on the shelf 30C to cover the sensor holder 37 when the sensor holder 37 is lowered. With this configuration, it is possible to achieve the same sealing effect as above. In addition, since the lip portion 105 is not worn due to long-term use, the durability is increased.

In this embodiment, the first and second two temperature sensors 24A, 24A,
24B, the first and second temperature sensors 24B are provided.
A and 24B are configured such that the first temperature sensor 24A is for controlling the amount of heating of the inner pot of the work coils 6a and 6b, and the second temperature sensor 24B is for detecting abnormal temperature.

In the configuration of the conventional general electromagnetic rice cooker, the inner pot 2
The temperature of the bottom is converted into an electric signal by a single temperature sensor and detected, and the detected signal is transmitted to a control circuit (for controlling the heating amount) (in the microcomputer) to control the work coils 6a and 6b.
The heating temperature of the inner pan 2 was controlled by varying the oscillation duty of the inner pan 2. However, in the control of the IH rice cooker, the temperature can be controlled in the process of controlling the temperature in general, but the temperature of the inner pot rises abnormally in the process of the timer control, When an abnormality such as runaway occurs, the temperature control becomes impossible.
For this reason, in the conventional configuration, the temperature fuse is provided in the center sensor 22 side by side with a single temperature sensor, but in such a configuration, the temperature fuse must be replaced every time there is an abnormality.

Therefore, in the present embodiment, the second temperature sensor 24B is used for detecting an abnormal temperature, and the inner pot temperature detection signal from the second temperature sensor 24B is used as a control circuit for controlling the heating amount. Input to a comparator, which is a temperature determination means that does not depend on microcomputer control and is provided separately from the
When an abnormal temperature equal to or higher than a predetermined temperature occurs, the oscillation operation of the work coil driving inverter circuit is automatically stopped.

With such a configuration, the control state (temperature control step or timer control step) of the microcomputer control circuit unit or a failure state is determined by the abnormal temperature detection signal detected with high accuracy by the second temperature sensor 24B. Irrespective of this, oscillation of the inverter circuit can be reliably and forcibly stopped. Accordingly, it is possible to quickly stop the alternating magnetic field from the work coils 6a and 6b, thereby ensuring more reliable safety. In addition, as a result, abnormal heating can be stopped early before the temperature fuse (see reference numeral 26 in FIG. 2) provided separately according to the safety standard is blown depending on how to set the reference temperature. There is a merit that can be almost eliminated.

(Embodiment 4) FIG. 9 shows a structure around a center sensor of an electromagnetic rice cooker according to Embodiment 4 of the present invention.

The temperature sensing performance of the center sensor 22 by the temperature sensor (thermistor) 24 is different from that of the cooling fan 78A due to the ventilation wind, for example, in the center sensor storage space 23A. It is also affected by the intrusion of foreign matter, which causes erroneous detection. This phenomenon is caused by the presence of a communication path communicating with the center sensor storage space 23A around the outer peripheral edge 28a of the sensor cap 28 of the center sensor 22, as in the case of the influence of the ventilation wind.

However, as a countermeasure against this phenomenon, a sealing member 1 made of a cylindrical rubber member is provided around the outer periphery of the sensor cap 28 of the center sensor 22 as in the first to third embodiments.
This cannot be realized only by providing the 00A and 100B separately or by fitting the ring-shaped seal member 100C to the cylindrical body of the sensor holder 37.

The present embodiment has been made in view of such circumstances, and in addition to the same sealing effect of ventilation air as in the first, second and third embodiments, the center sensor storage space 23
It is characterized in that it is possible to prevent foreign substances from entering the inside A.

That is, in this embodiment, the lower edge 102 of the sealing member 100D made of a cylindrical thin rubber member is formed into a large-diameter flange piece, and the upper end side of the center sensor storage space 23A of the inner case 5 is formed. The other upper edge 101 is fixed to the center sensor 2 while being fixed on the upper outer peripheral surface of the opening.
The center sensor storage space 23 is fixed to the inside of the outer peripheral edge portion 28a of the second sensor cap 28 by bonding.
A is completely sealed in the inner pan 2 set space on the inner case 5 side.

Therefore, according to this configuration, the communication passage is eliminated, and the cooling fan 7 is provided in the same manner as in the first and second embodiments.
8A ventilation space 23 between the inner case 5 and the inner pan 2
B of the center sensor 22 and the temperature sensor (thermistor) 24 of the center sensor 22 are not cooled by the passage of ventilation air.
No foreign matter such as rice or water can enter the 3A, and the reliability of the temperature detection performance of the thermistor 24 is further improved.

Further, since the seal member 100D is made of a highly flexible rubber member and is formed to be thin, it does not affect the elevation of the center sensor 22 at all.

(Embodiment 5) As the structure of the center sensor unit to which the present invention is applied, various structures other than the structures of the above-described embodiments can be adopted. For example, FIG. 10 and FIG. As shown, in the electromagnetic rice cooker provided with the center sensor 22 with the temperature fuse, the embodiments 1, 2, and 4 indicated by the arrow P are shown.
5 (Embodiment 1) and FIG. 6 described above (the opening of the upper end side communication passage 23c of the center sensor storage space 23A).
(Embodiment 2) Even if the sealing members 100A, 100B, 100 having the same structure as that of FIG. 9 (Embodiment 4) are provided, the same operation and effect can be obtained.

That is, in the electromagnetic rice cooker shown in FIGS. 10 and 11, an opening is formed in the center of the coil stand 7, and the opening is extended in both directions up and down in the form of a sleeve. A center sensor storage space 23A communicating vertically with the cylindrical body 30 is formed, and a center sensor 22 that resiliently contacts the bottom surface 2a of the inner pot 2 is provided in the center sensor storage space 23A. Have been.

The center sensor 22 includes a temperature detecting sensor for detecting the temperature of the inner pan 2 and the inner case 5 of the inner pan 2.
A temperature sensor (thermistor) 24 serving as a temperature detecting unit and a temperature fuse 2 for detecting an abnormal temperature, serving as an inner pot detecting sensor for detecting a set state and a non-set state in the inside.
6. An inner pot detecting device for detecting whether or not the inner pot 2 is set in the inner case 5 is provided as follows.

That is, the center sensor 22 is fitted and fixed from below into a cylindrical sensor housing space 23A formed inside the cylindrical body 30 of the coil mount 7 which is continuous with the bottom opening of the inner case 5. A cylindrical sensor cover 29, and a sensor holder 22a which is disposed inside the cylindrical body portion 29d of the sensor cover 29 so as to be vertically movable and has the temperature sensor 24 and the temperature fuse 26 built in at the upper end. ,
The sensor holder 22a is interposed between an intermediate edge portion 92a provided in the middle of the shaft portion of the sensor holder 22a and the lid portion 29a of the sensor cover 29, and the sensor holder 22a is moved upward (i.e.,
A coil spring 27 that urges the bottom portion 2a of the inner pan 2 in the direction of contact with the back surface thereof; a magnetic shield plate loose fitting hole 91 formed from the lower side to the upper side in the center of the shaft portion of the sensor holder 22a; The sensor holder 22a is located between the lower edge portion 92b provided at the lower end of the shaft portion and the intermediate edge portion 92a, and is provided to face left and right through the magnetic shield plate loose fitting hole 91. Magnet 18 and reed switch 1
7, and a magnetic shield plate loose fitting hole 91 which is erected on the lid portion 29a of the sensor cover 29 and is provided on the sensor holder 22a.
And a magnetic shielding plate 19 loosely fitted from below. Then, the lower edge 92b and the intermediate edge 92a of the sensor holder 22a are attached to the sensor cover 29.
Of the cylindrical body 29d so as to be able to move up and down, and the upper end side locking piece 29c of the cylindrical body 29d regulates the ascending position. Also,
At the upper end of the sensor holder 22a, a sensor cap 2 having a high thermal conductivity, which is in contact with the bottom surface 2a of the inner pot 2, is provided.
8 are provided.

The above-mentioned inner pot detecting device includes the reed switch 17 and the reed switch 17 which are provided at opposite positions on both left and right outer peripheral sides of the shaft portion of the sensor holder 22a with the magnetic shield plate loose fitting hole 91 interposed therebetween. With a magnet 18,
In the middle of them, when the sensor holder 22a is moved downward (in other words, when the inner pan is set), the lead is inserted between the reed switch 17 and the magnet 18 via the magnetic shield plate loose fitting hole 91 and the lead is inserted. Switch 17 to O
The reed switch 17 is configured to detect the set state when the reed switch 17 is ON and the non-set state when the reed switch 17 is OFF.

[Brief description of the drawings]

FIG. 1 is a central longitudinal sectional view (AA section in FIG. 4) of a configuration of an electromagnetic rice cooker according to a first embodiment of the present invention, which is cut in a front-rear direction.

FIG. 2 is a vertical cross-sectional view (cross section BB in FIG. 4) of a central portion of the electromagnetic rice cooker cut in a left-right direction.

FIG. 3 is a plan view of the electromagnetic rice cooker.

FIG. 4 is a perspective view of the electromagnetic rice cooker.

FIG. 5 is an enlarged cross-sectional view showing a structure around a center sensor unit in an inner pot setting state of the electromagnetic rice cooker.

FIG. 6 is an enlarged cross-sectional view showing a structure around a center sensor unit in an inner pot set state of the electromagnetic rice cooker according to the second embodiment of the present invention.

FIG. 7 is an enlarged cross-sectional view showing a structure around a center sensor in an electromagnetic rice cooker according to a third embodiment of the present invention when an inner pot is not set.

FIG. 8 is an enlarged cross-sectional view showing a structure around a center sensor in an inner pot set state of the electromagnetic rice cooker according to the third embodiment.

FIG. 9 is an enlarged cross-sectional view showing a structure around a center sensor unit in an inner pot set state of the electromagnetic rice cooker according to Embodiment 4 of the present invention.

FIG. 10 is an enlarged cross-sectional view showing a structure around a center sensor in an inner pot set state of an electromagnetic rice cooker according to Embodiment 5 of the present invention.

FIG. 11 is an enlarged cross-sectional view showing a structure of a peripheral portion of a center sensor in an inner pot set state of the electromagnetic rice cooker according to the fifth embodiment, which is cut at a different position from FIG. 10;

FIG. 12 is a sectional view showing the structure of a conventional electromagnetic rice cooker.

[Explanation of symbols]

1 is an electromagnetic rice cooker, 2 is an inner pot, 3 is an outer case, 4 is a lid unit, 5 is an inner case, 6a and 6b are work coils, 7 is a coil stand, 23A is a center sensor storage space, and 23B is an inner case. Space between the inner pot and the inner pot, 23c is a communication passage, 7
8A is a cooling fan, 100A, 100B, 100C, 10
0D is a seal member.

Claims (3)

(57) [Claims] 1. A container main body comprising an outer case and an inner case, a coil table provided inside the container main body, an inner pot stored in the inner case, and provided on the coil table. A work coil for heating the inner pot, a temperature sensor for detecting the temperature of the inner pot provided in a sensor storage space forming a communication passage into the inner case, and a sensor provided below the sensor storage space. An electromagnetic rice cooker comprising a cooling fan, wherein when the inner pan is stored in the inner case, the communication passage is closed to prevent the cooling air of the cooling fan from entering the inner case, and An electromagnetic rice cooker, wherein a seal member for opening the communication passage when the inner pot in the case is taken out is provided in a sensor storage space forming the communication passage. 2. A sealing member comprising a cylindrical elastic member,
2. The electromagnetic rice cooker according to claim 1, wherein the rice cooker is arranged so as to be able to bend in a vertical direction so as to surround an outer periphery of an upper opening end of the sensor storage space. 3. The sensor according to claim 1, wherein the seal member is formed of a ring-shaped elastic member having a lip portion, and is fitted to a lower portion of the temperature sensor in the sensor storage space. Electromagnetic rice cooker.