JPH0541274A - Electromagnetic induction heating cooker - Google Patents
Electromagnetic induction heating cookerInfo
- Publication number
- JPH0541274A JPH0541274A JP19652291A JP19652291A JPH0541274A JP H0541274 A JPH0541274 A JP H0541274A JP 19652291 A JP19652291 A JP 19652291A JP 19652291 A JP19652291 A JP 19652291A JP H0541274 A JPH0541274 A JP H0541274A
- Authority
- JP
- Japan
- Prior art keywords
- heating coil
- stage
- voltage
- heating
- coil
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
Abstract
Description
【0001】[0001]
【産業上の利用分野】本発明は、電磁誘導加熱調理器に
おいて、特に平板加熱コイルの構造に関するものであ
る。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of a flat plate heating coil in an electromagnetic induction heating cooker.
【0002】[0002]
【従来の技術】図6は従来の電磁誘導加熱調理器の平板
加熱コイル周辺の構造図である。図6において、1は被
加熱物である金属鍋、2は金属鍋1を載置するための載
置台、3は金属鍋1を誘導加熱するための高周波交番磁
束を発生させる平板加熱コイル、4は平板加熱コイル3
を保持する保持台であり、発生した高周波交番磁束が金
属鍋1の底面を透磁する際に流れる渦電流のジュール熱
損により、金属鍋1が加熱される。2. Description of the Related Art FIG. 6 is a structural diagram around a flat plate heating coil of a conventional electromagnetic induction heating cooker. In FIG. 6, 1 is a metal pan that is an object to be heated, 2 is a mounting table on which the metal pan 1 is placed, 3 is a flat plate heating coil that generates high-frequency alternating magnetic flux for inductively heating the metal pan 1, 4 Is a flat plate heating coil 3
The metal pan 1 is heated by Joule heat loss of the eddy current that flows when the generated high-frequency alternating magnetic flux permeates the bottom surface of the metal pan 1.
【0003】また上記平板加熱コイル3を駆動する高周
波電力変換装置としては、図7に示すシングル・エンド
・プッシュ・プル(SEPP)回路か、または図8に示
す一石共振インバータ回路を用いるのが一般的である。Further, as a high frequency power converter for driving the flat plate heating coil 3, a single end push pull (SEPP) circuit shown in FIG. 7 or a single-stone resonance inverter circuit shown in FIG. 8 is generally used. Target.
【0004】従来の平板加熱コイルのほとんどは1段構
成で、本発明のような2段加熱コイルとしては、非磁性
体の金属鍋を加熱する目的で、加熱コイルを2個直列に
接続してインダクタンス値を大きくし、平板加熱コイル
からの高周波交番磁束の量を増やした2段構成の平板加
熱コイルが特公平2ー31472にある。Most of the conventional flat plate heating coils have a single-stage structure. As a two-stage heating coil according to the present invention, two heating coils are connected in series for the purpose of heating a non-magnetic metal pot. Japanese Patent Publication No. 2-31472 discloses a flat plate heating coil having a two-stage structure in which the inductance value is increased and the amount of high frequency alternating magnetic flux from the flat plate heating coil is increased.
【0005】[0005]
【発明が解決しようとする課題】上記の高周波電力変換
装置では、平板加熱コイル3と共振コンデンサ7の直列
共振条件で駆動するため、加熱コイル3に流れるコイル
電流は共振コンデンサ7に充電され、共振コンデンサ7
の両端に高電圧を発生する。この共振電圧は、また加熱
コイルにも引加される。この時、発生する電圧Vcは、
加熱コイル3に流れるコイル電流をIL、加熱コイル3
のインダクタンス値をL,共振コンデンサ7の容量をC
とすると、In the above high-frequency power converter, since the flat plate heating coil 3 and the resonance capacitor 7 are driven under the series resonance condition, the coil current flowing in the heating coil 3 is charged in the resonance capacitor 7 to cause resonance. Capacitor 7
Generate high voltage across both ends of. This resonant voltage is also applied to the heating coil. At this time, the generated voltage Vc is
The coil current flowing through the heating coil 3 is I L , and the heating coil 3
The inductance value of L and the capacitance of the resonance capacitor 7 are C
Then,
【0006】[0006]
【数1】 [Equation 1]
【0007】となり、共振電圧Vcは加熱コイル3のイ
ンダクタンス値に比例する。このため加熱コイルを2個
直列に接続した2段加熱コイルの場合は、通常の1段コ
イルに比べてインダクタンス値が大きく、共振電圧Vc
も大きくなり、その電圧は大出力タイプの電磁誘導加熱
調理器の場合、数10kVにも達する。この高電圧は加
熱コイルの共振コンデンサ側接続点にも同様に発生す
る。この時、2個の加熱コイルは、共振コンデンサ側の
高圧側と、電源側の低圧側とに分けられる。Therefore, the resonance voltage Vc is proportional to the inductance value of the heating coil 3. Therefore, in the case of a two-stage heating coil in which two heating coils are connected in series, the inductance value is larger than that of a normal one-stage coil, and the resonance voltage Vc
In the case of a high output type electromagnetic induction heating cooker, the voltage reaches several tens of kV. This high voltage is also generated at the connection point of the heating coil on the side of the resonance capacitor. At this time, the two heating coils are divided into a high voltage side on the resonance capacitor side and a low voltage side on the power supply side.
【0008】一方、加熱コイル3と被加熱金属鍋1は、
加熱コイル3から発生する高周波交番磁束を効率良く金
属鍋1底面に透磁させるために、構造的に可能な限り近
づけることが好ましく通常数mmとしており、さらに加
熱コイル3と金属鍋1の間にある載置台2は、耐熱性と
強度性を考慮し、その材質として一般的に誘電材料のセ
ラミックやガラスなどを用いているため、加熱コイル3
と金属鍋1の間には浮遊静電容量5が存在している。On the other hand, the heating coil 3 and the heated metal pot 1 are
In order to efficiently permeate the high frequency alternating magnetic flux generated from the heating coil 3 to the bottom surface of the metal pan 1, it is preferable to bring them as close as structurally possible, usually several mm, and between the heating coil 3 and the metal pan 1. In consideration of heat resistance and strength, a certain mounting table 2 generally uses a dielectric material such as ceramic or glass as its material.
There is a floating capacitance 5 between the and the metal pot 1.
【0009】この浮遊静電容量5の存在による静電結合
により、加熱コイル3に発生した高電圧が金属鍋1に誘
起し、大地と金属鍋の間に電圧が発生する。Due to the electrostatic coupling due to the presence of the floating electrostatic capacitance 5, a high voltage generated in the heating coil 3 is induced in the metal pot 1 and a voltage is generated between the ground and the metal pot.
【0010】ここで従来の2段加熱コイルでは、2個の
加熱コイルの低圧側と高圧側の明確な区別をしておら
ず、もし高圧側の加熱コイルが金属鍋に近い上段になれ
ば、上記の金属鍋1の誘起電圧も大きくなり、人体が鍋
に触れると感電するという欠点があり、特に調理者の手
が濡れているような時は強く感電し問題であった。In the conventional two-stage heating coil, no distinction is made between the low-voltage side and the high-voltage side of the two heating coils, and if the heating coil on the high-voltage side is in the upper stage close to the metal pot, The above-mentioned induced voltage of the metal pot 1 also becomes large, and there is a drawback that the human body receives an electric shock when touching the pot, and especially when the hand of the cooker is wet, there was a strong electric shock, which was a problem.
【0011】また、従来の加熱コイルでは1段目と2段
目の接続点も明確化されておらず、もし2段加熱コイル
の内側同士を接続すると2段加熱コイルの外側同士の間
に高電圧がかかり1段目と2段目の間にコロナ放電が発
生する。Further, in the conventional heating coil, the connection points of the first and second stages are not clarified. If the insides of the two-stage heating coils are connected to each other, the height between the outsides of the two-stage heating coils is increased. A voltage is applied and corona discharge occurs between the first and second stages.
【0012】[0012]
【課題を解決するための手段】本発明は係る欠点に鑑み
てなされたもので、上記2段加熱コイルの高圧側と低圧
側の位置関係を明確にし、高圧側加熱コイルを金属鍋1
から離した下段にし、低圧側加熱コイルを金属鍋1に近
い上段となるように、巻き中心を同一にし2段に重ねた
構造にする。The present invention has been made in view of the above drawbacks, and the positional relationship between the high-voltage side and the low-voltage side of the two-stage heating coil is clarified, and the high-pressure side heating coil is attached to the metal pan 1.
The lower coil is separated from the lower coil, and the winding center is the same so that the low-voltage side heating coil is in the upper coil close to the metal pan 1.
【0013】さらに1段目と2段目の接続点を1段目の
内側と2段目の外側、または1段目の外側と2段目の内
側にする。Further, the connection points of the first stage and the second stage are set to the inner side of the first stage and the outer side of the second stage, or the outer side of the first stage and the inner side of the second stage.
【0014】[0014]
【作用】金属鍋1に発生する誘起電圧が、金属鍋1と加
熱コイル3の間に存在する浮遊静電容量5に起因するこ
とから、金属鍋1と加熱コイル3の間の距離を物理的に
離してやれば浮遊静電容量5も小さくすることができ、
結果的には金属鍋1に発生する誘起電圧も小さくするこ
とができる。そのため直列に接続された2段加熱コイル
の共振コンデンサ側の高圧側と、電源側の低圧側の位置
関係を明確にして、金属鍋1に近い上段に2段加熱コイ
ルの低圧側を設け、金属鍋1から遠い下段に高圧側を設
けることにより、金属鍋に発生する誘起電圧を低減させ
ることができ、人体への感電の問題も解決できる。Since the induced voltage generated in the metal pot 1 is caused by the stray capacitance 5 existing between the metal pot 1 and the heating coil 3, the distance between the metal pot 1 and the heating coil 3 is physically adjusted. The floating electrostatic capacitance 5 can be reduced by separating it to
As a result, the induced voltage generated in the metal pot 1 can also be reduced. Therefore, the positional relationship between the high-voltage side on the resonance capacitor side and the low-voltage side on the power supply side of the two-stage heating coil connected in series is clarified, and the low-voltage side of the two-stage heating coil is provided in the upper stage close to the metal pot 1, By providing the high voltage side in the lower stage far from the pot 1, the induced voltage generated in the metal pot can be reduced, and the problem of electric shock to the human body can be solved.
【0015】さらに2段加熱コイルの接続点を1段目の
内側(外側)と2段目の外側(内側)にすることによ
り、1段目と2段目の間の電圧は、どの位置でも同じに
なり低電圧化される。Further, by connecting the connection points of the two-stage heating coil to the inside (outside) of the first stage and the outside (inside) of the second stage, the voltage between the first and second stages can be set at any position. It becomes the same and the voltage is lowered.
【0016】[0016]
【実施例】以下、本発明の実施例を図を用いて詳細に説
明する。Embodiments of the present invention will be described in detail below with reference to the drawings.
【0017】図1は本発明の電磁誘導加熱調理器の2段
加熱コイルの構造を示す説明図であり、図2、図3は本
発明の2段加熱コイルに関する高周波電力変換装置の回
路図である。FIG. 1 is an explanatory view showing the structure of a two-stage heating coil of an electromagnetic induction heating cooker of the present invention, and FIGS. 2 and 3 are circuit diagrams of a high-frequency power converter relating to the two-stage heating coil of the present invention. is there.
【0018】図1において、図4と比較して異なってい
る部分は加熱コイルであり、インダクタンス値を大きく
するため2個直列に接続されており、巻き中心を同一に
して2段に重ねられている。金属鍋1に近い上段が低圧
側加熱コイル3aで金属鍋1から遠い下段が高圧側加熱
コイル3bで、その間に上段加熱コイルの保持台兼絶縁
板6が設けられている。絶縁板6は厚さ数mm程度のマ
イカ板などの絶縁物を用いる。In FIG. 1, the difference from FIG. 4 is a heating coil, which is connected in series in order to increase the inductance value, and is wound in two steps with the same winding center. There is. The upper stage close to the metal pan 1 is the low-voltage side heating coil 3a, and the lower stage far from the metal pan 1 is the high-voltage side heating coil 3b, and the holding plate / insulating plate 6 for the upper stage heating coil is provided between them. As the insulating plate 6, an insulating material such as a mica plate having a thickness of several mm is used.
【0019】電気的には図2または図3に示すように、
電源側(図のA点)に接続されている加熱コイルが低圧
側加熱コイル3aで、商用電源13の交流電圧(100
Vまたは200V)を整流回路12と平滑コンデンサ1
1で平滑した直流電圧以上の電圧は引加されることはな
い。一方共振コンデンサ7側(図のB点)に接続されて
いる加熱コイルが高圧側加熱コイル3bで、加熱コイル
3と共振コンデンサ7が直列共振するため非常に高い共
振電圧(通常数10kV)がその接続点に発生し加熱コ
イル3bに引加される。Electrically, as shown in FIG. 2 or 3,
The heating coil connected to the power source side (point A in the figure) is the low voltage side heating coil 3a, and the alternating voltage (100
Rectifying circuit 12 and smoothing capacitor 1
A voltage above the DC voltage smoothed by 1 will not be applied. On the other hand, the heating coil connected to the resonance capacitor 7 side (point B in the figure) is the high-voltage side heating coil 3b, and since the heating coil 3 and the resonance capacitor 7 resonate in series, a very high resonance voltage (usually several tens of kV) is generated. It is generated at the connection point and applied to the heating coil 3b.
【0020】金属鍋1への漏電は、加熱コイル3と共振
コンデンサ7で構成される直列共振回路に発生する高圧
の共振電圧が加熱コイル3に引加され、その電圧が加熱
コイル3と金属鍋1との静電結合により金属鍋1に誘導
するために生じるものであるから、金属鍋1の対地電圧
Vrは、加熱コイル3と金属鍋1間の浮遊静電容量5の
容量をC,加熱コイル3の対地電圧をVc、金属鍋1の
対地抵抗をR,インバータの駆動周波数をfとするとAs for the electric leakage to the metal pan 1, the high-voltage resonance voltage generated in the series resonance circuit composed of the heating coil 3 and the resonance capacitor 7 is applied to the heating coil 3, and the voltage is applied to the heating coil 3 and the metal pan. Since it is generated by induction in the metal pot 1 by electrostatic coupling with 1, the ground voltage Vr of the metal pot 1 causes the capacitance of the floating electrostatic capacity 5 between the heating coil 3 and the metal pot 1 to be C. If the ground voltage of the coil 3 is Vc, the ground resistance of the metal pot 1 is R, and the drive frequency of the inverter is f.
【0021】[0021]
【数2】 [Equation 2]
【0022】となる(図4参照)。(See FIG. 4)
【0023】また加熱コイル3と金属鍋1の間の浮遊静
電容量5の容量Cは、加熱コイル3と金属鍋1の対向面
積をS,その対向距離をdとすると、ε0:真空誘電
率,εs:比誘電率として、The capacitance C of the floating electrostatic capacitance 5 between the heating coil 3 and the metal pot 1 is ε 0 : vacuum dielectric, where S is the facing area between the heating coil 3 and the metal pot 1 and d is the facing distance. , Ε s : As the relative permittivity,
【0024】[0024]
【数3】 [Equation 3]
【0025】となる。[0025]
【0026】ここで、本発明のように2段加熱コイルの
高圧側3bを下段にすると上式の対向距離dは高圧側3
bを上段にした時に比べて大きくなる。対向距離dが大
きくなると加熱コイル3と金属鍋1間の浮遊静電容量5
は、逆に小さくなり、その結果、金属鍋1の対地電圧V
rも小さくなる。Here, when the high-pressure side 3b of the two-stage heating coil is set to the lower stage as in the present invention, the facing distance d in the above equation is 3
It becomes larger than when b is set to the upper stage. When the facing distance d increases, the floating capacitance 5 between the heating coil 3 and the metal pot 1
On the contrary, as a result, the ground voltage V of the metal pot 1 becomes smaller.
r also becomes small.
【0027】金属鍋1と加熱コイル3との間の距離は、
加熱コイル3から発生する高周波交番磁束を効率良く金
属鍋底面に透磁させるために、構造的に可能な限り近付
けており、通常数mmにしている。一方加熱コイル1段
の厚みはコイル単体で数mmで、その保持台兼絶縁板6
の厚みも含めると5mm程度になり、加熱コイル1段分
の空間距離か又は2段分の空間距離かにより、金属鍋1
と加熱コイル3との間の対向距離dは、2〜3倍は違っ
てくる。その結果、加熱コイルの低圧側3aを上段にし
高圧側3bを下段にすることによりその逆の構造に比べ
て金属鍋1に誘起しいくる誘起電圧は1/2〜1/3に
低減される。The distance between the metal pot 1 and the heating coil 3 is
In order to efficiently permeate the high frequency alternating magnetic flux generated from the heating coil 3 to the bottom surface of the metal pot, the magnetic flux is as close as possible structurally, and is usually several mm. On the other hand, the thickness of one stage of the heating coil is several mm for the coil alone, and the holder and the insulating plate 6
The thickness of the metal pan will be about 5 mm including the thickness of the heating pan.
The facing distance d between the heating coil 3 and the heating coil 3 is two to three times different. As a result, by setting the low-voltage side 3a of the heating coil to the upper stage and the high-voltage side 3b to the lower stage, the induced voltage induced in the metal pot 1 is reduced to 1/2 to 1/3 as compared with the opposite structure.
【0028】また、2段加熱コイルの低圧側3aと高圧
側3bのどちらが上段にあっても加熱効率には影響しな
いため、本発明のように加熱コイルの低圧側3aを上段
にしても全く性能には問題ない。Further, since the heating efficiency is not affected by whichever of the low-pressure side 3a and the high-pressure side 3b of the two-stage heating coil is in the upper stage, even if the low-pressure side 3a of the heating coil is in the upper stage as in the present invention, the performance is completely reduced. No problem with.
【0029】また、図5(a)に示すように2段加熱コ
イルの接続点を内側同士にすると、各々の外側がそれぞ
れ共振コンデンサ側と電源側に接続されるため、共振コ
ンデンサに発生する高電圧Vが、加熱コイルの外側部分
でもろに絶縁板6にかかる。しかし、第5図(b)に示
すように接続点を1段目3aの内側からと2段目3bの
外側というように接続すると、絶縁板6にかかる電圧は
どの位置においてもV/2(1段目と2段目の加熱コイ
ルを同一とした場合)となる。この逆に1段目の外側と
2段目の内側とを接続しても効果は同じである。As shown in FIG. 5 (a), when the connecting points of the two-stage heating coil are inside, the outsides of the two-stage heating coils are connected to the resonance capacitor side and the power supply side, respectively. The voltage V is applied to the insulating plate 6 not only on the outside of the heating coil. However, if the connection points are connected from the inside of the first stage 3a to the outside of the second stage 3b as shown in FIG. 5 (b), the voltage applied to the insulating plate 6 is V / 2 ( (When the heating coils in the first and second stages are the same). On the contrary, even if the outer side of the first stage and the inner side of the second stage are connected, the effect is the same.
【0030】この結果、2段加熱コイルの間にコロナ放
電の発生を抑え、さらに絶縁板の厚みも薄くでき1段目
と2段目の結合も良くなり、高性能な2段加熱コイルが
実現できる。As a result, generation of corona discharge is suppressed between the two-stage heating coils, the thickness of the insulating plate can be reduced, and the first-stage and second-stage couplings are improved, resulting in a high-performance two-stage heating coil. it can.
【0031】[0031]
【発明の効果】以上の説明からも明らかなように、本発
明の2段加熱コイルでは、電磁誘導加熱調理器のインバ
ータ回路に発生する高周波・高電圧の共振電圧による金
属鍋への誘起電圧を低減させ、金属鍋から調理者への感
電を防止することができる。As is apparent from the above description, in the two-stage heating coil of the present invention, the induced voltage to the metal pot due to the high frequency / high voltage resonance voltage generated in the inverter circuit of the electromagnetic induction heating cooker is applied. It is possible to reduce the electric shock from the metal pot to the cook.
【0032】また、本発明の構造では金属鍋と加熱コイ
ルの間にシールド板を挿入して金属鍋に誘起する電圧を
抑えなくてもよく、逆にシールド板を挿入したことによ
る高周波交番磁束の抑制や金属鍋と加熱コイル間の空間
距離の増大による加熱効率の低下というような問題もな
く、構造も簡単にすることができる。Further, in the structure of the present invention, it is not necessary to insert a shield plate between the metal pan and the heating coil to suppress the voltage induced in the metal pan, and conversely, by inserting the shield plate, the high frequency alternating magnetic flux There is no problem such as reduction of heating efficiency due to suppression or increase of the spatial distance between the metal pan and the heating coil, and the structure can be simplified.
【図1】本発明の2段加熱コイルの誘導加熱調理器の構
造図である。FIG. 1 is a structural diagram of an induction heating cooker with a two-stage heating coil according to the present invention.
【図2】本発明の誘導加熱調理器の高周波電力変換装置
の回路図である。FIG. 2 is a circuit diagram of a high frequency power converter for an induction heating cooker according to the present invention.
【図3】本発明の誘導加熱調理器の高周波電力変換装置
の回路図である。FIG. 3 is a circuit diagram of a high frequency power converter for an induction heating cooker according to the present invention.
【図4】漏電状態を説明する説明図である。FIG. 4 is an explanatory diagram illustrating a leakage state.
【図5】(a),(b)は本発明の2段加熱コイルの接
続点を示した図である。5 (a) and 5 (b) are views showing connection points of the two-stage heating coil of the present invention.
【図6】従来の1段加熱コイルの誘導加熱調理器の構造
図である。FIG. 6 is a structural diagram of a conventional induction heating cooker having a one-stage heating coil.
【図7】従来の誘導加熱調理器の高周波電力変換装置の
回路図である。FIG. 7 is a circuit diagram of a conventional high-frequency power converter for an induction heating cooker.
【図8】従来の誘導加熱調理器の高周波電力変換装置の
回路図である。FIG. 8 is a circuit diagram of a conventional high-frequency power converter for an induction heating cooker.
1 金属鍋 3 加熱コイル 7 共振コンデンサ 8 トランジスタ 9 ダイオード 10 インバータ駆動制御回路 11 平滑コンデンサ 12 整流回路 13 商用電源 1 Metal Pan 3 Heating Coil 7 Resonant Capacitor 8 Transistor 9 Diode 10 Inverter Drive Control Circuit 11 Smoothing Capacitor 12 Rectifier Circuit 13 Commercial Power Supply
Claims (2)
平板加熱コイルと、該平板加熱コイルから高周波交番磁
束を発生させる高周波電力変換装置とを有し、前記平板
加熱コイルの構造を上段に低圧側加熱コイル、下段に高
圧側加熱コイルを配した2段構成にしたことを特徴とす
る電磁誘導加熱調理器。1. A flat-plate heating coil having the same winding center and stacked in two stages, and a high-frequency power converter for generating a high-frequency alternating magnetic flux from the flat-plate heating coil, wherein the structure of the flat-plate heating coil is the upper stage. An electromagnetic induction heating cooker having a two-stage structure in which a low-voltage side heating coil and a high-pressure side heating coil are arranged in the lower part.
て、1段目と2段目の間に絶縁板を挿入し、1段目と2
段目の接続点を1段目の内側(外側)と2段目の外側
(内側)にしたことを特徴とする電磁誘導加熱調理器。2. The two-stage heating coil according to claim 1, wherein an insulating plate is inserted between the first stage and the second stage,
An electromagnetic induction heating cooker characterized in that the connection points of the tiers are inside (outside) of the first tier and outside (inner) of the second tier.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP19652291A JPH0541274A (en) | 1991-08-06 | 1991-08-06 | Electromagnetic induction heating cooker |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP19652291A JPH0541274A (en) | 1991-08-06 | 1991-08-06 | Electromagnetic induction heating cooker |
Publications (1)
Publication Number | Publication Date |
---|---|
JPH0541274A true JPH0541274A (en) | 1993-02-19 |
Family
ID=16359142
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP19652291A Pending JPH0541274A (en) | 1991-08-06 | 1991-08-06 | Electromagnetic induction heating cooker |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPH0541274A (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6144019A (en) * | 1998-10-05 | 2000-11-07 | Bsh Bosch Und Siemens Hausgeraete Gmbh | Inductor for an induction cooking area |
JP2012079646A (en) * | 2010-10-06 | 2012-04-19 | Mitsubishi Electric Corp | Induction heating apparatus and heated body |
WO2018116064A1 (en) * | 2016-12-23 | 2018-06-28 | BSH Hausgeräte GmbH | Cooking appliance apparatus, and method for producing a cooking appliance apparatus |
Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS6136987B2 (en) * | 1977-03-07 | 1986-08-21 | Shereko Ab |
-
1991
- 1991-08-06 JP JP19652291A patent/JPH0541274A/en active Pending
Patent Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS6136987B2 (en) * | 1977-03-07 | 1986-08-21 | Shereko Ab |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6144019A (en) * | 1998-10-05 | 2000-11-07 | Bsh Bosch Und Siemens Hausgeraete Gmbh | Inductor for an induction cooking area |
JP2012079646A (en) * | 2010-10-06 | 2012-04-19 | Mitsubishi Electric Corp | Induction heating apparatus and heated body |
WO2018116064A1 (en) * | 2016-12-23 | 2018-06-28 | BSH Hausgeräte GmbH | Cooking appliance apparatus, and method for producing a cooking appliance apparatus |
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