JPH0974228A - Series type thermocouple - Google Patents
Series type thermocoupleInfo
- Publication number
- JPH0974228A JPH0974228A JP7248708A JP24870895A JPH0974228A JP H0974228 A JPH0974228 A JP H0974228A JP 7248708 A JP7248708 A JP 7248708A JP 24870895 A JP24870895 A JP 24870895A JP H0974228 A JPH0974228 A JP H0974228A
- Authority
- JP
- Japan
- Prior art keywords
- thermocouple
- type thermocouple
- series
- burner
- series type
- 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]
【発明の属する技術分野】本発明は燃焼熱によって熱起
電力を発生させて電力を供給する直列型熱電対に関す
る。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a series type thermocouple for generating electric power by generating thermoelectromotive force by heat of combustion.
【0002】[0002]
【従来の技術】従来から、燃焼制御装置等の電源として
蓄電池を設け、炎の燃焼熱によって発生する熱起電力を
利用し、蓄電池に充電するタイプのガス燃焼器がある。
そこで、蓄電池に充電する為の従来技術として、図5に
示した直列型熱電対について説明する。蓄電池を効率よ
く容易に充電する為には、高い起電力を得る必要があ
る。そこで、従来、複数個の熱電対素子12を直列に接
続して構成した直列型熱電対10が使用された。例え
ば、1個の熱電対素子12で30mVの起電力しか得ら
れない場合であっても、50個の熱電対素子12を集積
したならば、全体として1.5Vの起電力を得ることが
できるからである。2. Description of the Related Art Conventionally, there is a gas combustor of a type in which a storage battery is provided as a power source for a combustion control device or the like, and the thermoelectromotive force generated by the combustion heat of a flame is used to charge the storage battery.
Therefore, as a conventional technique for charging the storage battery, the series type thermocouple shown in FIG. 5 will be described. In order to charge the storage battery efficiently and easily, it is necessary to obtain a high electromotive force. Therefore, conventionally, a series type thermocouple 10 configured by connecting a plurality of thermocouple elements 12 in series has been used. For example, even if only one thermocouple element 12 can obtain an electromotive force of 30 mV, if 50 thermocouple elements 12 are integrated, an electromotive force of 1.5 V can be obtained as a whole. Because.
【0003】図5に示した直列型熱電対10のように、
2種の異なる金属線材17,18の端部を接続してジグ
ザグ状に連結し、複数個の熱電対素子12が連なる直列
型熱電対10を作る。従って、直列型熱電対10は各熱
電対素子12の数だけ高温接点12aと冷温接点12b
とが形成され、先頭と最後の熱電対素子12にそれぞれ
リ−ド線11a,11bを溶接することで完成する。こ
の結果、1つ1つの熱電対素子12から得られる起電力
は小さくても、全体的には安定した高起電力が得られる
ようになる。Like the series thermocouple 10 shown in FIG.
The ends of two different types of metal wire rods 17 and 18 are connected and connected in a zigzag shape to form a series type thermocouple 10 in which a plurality of thermocouple elements 12 are connected. Therefore, the series type thermocouple 10 has as many hot contact points 12a and cold contact points 12b as there are thermocouple elements 12.
Are formed and are completed by welding lead wires 11a and 11b to the first and last thermocouple elements 12, respectively. As a result, even if the electromotive force obtained from each thermocouple element 12 is small, a stable high electromotive force can be obtained as a whole.
【0004】[0004]
【発明が解決しようとする課題】しかしながら、上述し
た従来の直列型熱電対10では、高温接点12aが直接
炎に接触する為に、その高温の熱によって金属線材1
7,18表面で酸化が起こり、高温腐食・劣化してしま
うという耐熱性能上の問題があった。特に、高い起電力
が得られるコンスタンタンとステンレスとを組み合わせ
た場合、ステンレスは耐熱性に優れるが、コンスタンタ
ンは耐熱性に劣る為に高温腐食・劣化が起こりやすくな
ってしまう。本発明は上記課題を解決し、簡単な構成
で、燃焼時に起こる酸化による高温接点の高温腐食・劣
化を抑制し、安定した高起電力が得られる直列型熱電対
を作ることを目的とする。However, in the above-mentioned conventional series type thermocouple 10, since the high temperature contact 12a directly contacts the flame, the metal wire 1 is heated by the high temperature heat.
There was a problem in heat resistance performance that oxidation occurred on the surfaces of Nos. 7 and 18, causing high temperature corrosion and deterioration. In particular, when Constantan and stainless steel, which can obtain a high electromotive force, are combined, stainless steel has excellent heat resistance, but Constantan is inferior in heat resistance, so that high temperature corrosion / degradation easily occurs. SUMMARY OF THE INVENTION It is an object of the present invention to solve the above problems and to make a series thermocouple that has a simple structure, suppresses high temperature corrosion / deterioration of a high temperature contact due to oxidation that occurs during combustion, and can obtain stable high electromotive force.
【0005】[0005]
【課題を解決する為の手段】本発明の直列型熱電対は、
2つの異種金属片を接合・形成した熱電対素子を複数接
続した直列型熱電対において、上記2つの金属片のう
ち、耐熱性が高い方の金属片の端部で、耐熱性が低い方
の金属片の端部を覆うように接合して火炎に接触する高
温接点を構成したことを要旨とする。The series type thermocouple of the present invention comprises:
In a series-type thermocouple in which a plurality of thermocouple elements formed by joining and forming two dissimilar metal pieces are connected to each other, one of the two metal pieces having a higher heat resistance has the lower heat resistance at the end portion of the metal piece having a higher heat resistance. The gist of the present invention is that a high temperature contact is formed so as to be in contact with a flame by being joined so as to cover the end of the metal piece.
【0006】上記構成を有する本発明の請求項1記載の
直列型熱電対は、2種類の金属を接合・形成した複数個
の熱電対素子を使用しており、高温雰囲気中での耐熱性
が高い方の金属片の端部で低い方の金属片の端部を覆う
ことによって高温接点を構成する。その為、耐熱性の低
い方の金属片には、直接炎が当たりにくくなり、耐熱性
が低い方の金属片の熱による高温腐食(酸化)・劣化を
低コストで抑制することができる。The series type thermocouple according to claim 1 of the present invention having the above structure uses a plurality of thermocouple elements in which two kinds of metals are joined and formed, and has a heat resistance in a high temperature atmosphere. A hot contact is constructed by covering the end of the lower metal strip with the end of the higher metal strip. Therefore, the metal piece having lower heat resistance is less likely to be directly exposed to the flame, and high-temperature corrosion (oxidation) / degradation due to heat of the metal piece having lower heat resistance can be suppressed at low cost.
【0007】本発明の請求項2記載の直列型熱電対は、
請求項1記載の直列型熱電対において、こんろバ−ナの
周りの全周あるいはその一部に配列したことを要旨とす
る。The series type thermocouple according to claim 2 of the present invention comprises:
The gist of the series-type thermocouple according to claim 1 is that it is arranged on the entire circumference or part of the circumference of the stove burner.
【0008】上記構成を有する請求項2記載の直列型熱
電対は、請求項1記載の直列型熱電対において、こんろ
バ−ナの形状に合わせてバ−ナの周りの全周あるいはそ
の一部に配列した為、バ−ナ火炎から発生する熱を効率
良く大量に受けることができ、且つ得られる起電力も安
定する。The series-type thermocouple according to claim 2 having the above structure is the series-type thermocouple according to claim 1, wherein the whole circumference or one of the circumferences of the burner is matched with the shape of the stove burner. Since they are arranged in the section, a large amount of heat generated from the burner flame can be efficiently received, and the obtained electromotive force is stable.
【0009】[0009]
【発明の実施の形態】以上説明した本発明の構成・作用
を一層明らかにする為に、以下本発明の直列型熱電対の
好適な実施例について説明する。BEST MODE FOR CARRYING OUT THE INVENTION In order to further clarify the constitution and operation of the present invention described above, preferred embodiments of the series thermocouple of the present invention will be described below.
【0010】図2は、一実施例としての直列型熱電対を
表すもので、図3(a)に示したステンレスからなる板
材(以後、ステンレスと呼ぶ)51とコンスタンタンか
らなる丸棒(以後、コンスタンタンと呼ぶ)52とをそ
れぞれ両端にて溶接して、高温接点55と冷温接点56
とを構成し、複数個の熱電対素子が連なる直列型熱電対
50を作る。しかし、ステンレスに比べてコンスタンタ
ンは耐熱性に劣る。そこで、直列型熱電対50の高温接
点55は、コンスタンタン52に比べて耐熱性の高いス
テンレス51のL字状の端部Bをカ−ルし、それによっ
てできた円筒内にコンスタンタン52の先端部を挿通・
溶接することによって固定・形成する。ただし、カ−ル
方向は図中に示した、互いに異なる方向とする。また、
冷温接点56は炎との接触がない為、従来のように溶接
しただけで構成しても良い。更に、ステンレス51のカ
−ルを行う部分Bの形状は、図3(b),(c)に例示
した形状でも良い。尚、上述した直列型熱電対50に使
用されている熱電対素子の内、先頭と最後に位置するも
のには、それぞれリード線53を接続する。また、熱電
対素子の接点同士が電気的に短絡することを防止する為
に、表面にホーロー処理等の表面処理を施す。FIG. 2 shows an in-line type thermocouple as an example. A plate material (hereinafter referred to as stainless steel) 51 made of stainless steel shown in FIG. 52, which is referred to as a constantan), is welded at both ends to form a hot contact 55 and a cold contact 56.
And a series type thermocouple 50 in which a plurality of thermocouple elements are connected. However, Constantan is inferior in heat resistance to stainless steel. Therefore, the high temperature contact 55 of the series type thermocouple 50 curls the L-shaped end portion B of the stainless steel 51 having higher heat resistance than the constantan 52, and the tip portion of the constantan 52 is formed in a cylinder formed by the curling. Insert
It is fixed and formed by welding. However, the curl directions are different from each other as shown in the figure. Also,
Since the cold / hot contact 56 does not come into contact with the flame, it may be constructed by welding as in the conventional case. Further, the shape of the curled portion B of the stainless steel 51 may be the shape illustrated in FIGS. 3B and 3C. The lead wires 53 are respectively connected to the first and last ones of the thermocouple elements used in the series thermocouple 50 described above. Further, in order to prevent the contacts of the thermocouple element from being electrically short-circuited, the surface is subjected to surface treatment such as enamel treatment.
【0011】一般に、多くの金属については、高温の熱
によって起こる金属の酸化現象の反応速度は、ある一定
の温度までは非常に遅いが、それを越えると急激に速く
なる放物線型のグラフ形状となることが知られているこ
とから、高温接点での温度を、酸化現象の速度が大きく
変化する直前の温度、つまり、ほぼコンスタンタン52
の耐熱温度になるように諸条件を調整することによっ
て、高温の熱による酸化から保護することができ、且つ
高い起電力を得ることができる。In general, for many metals, the reaction rate of the metal oxidation phenomenon caused by high temperature heat is very slow up to a certain temperature, but beyond that, it rapidly increases and becomes a parabolic graph shape. It is known that the temperature at the high temperature contact is the temperature immediately before the rate of the oxidation phenomenon changes greatly, that is, the temperature at the constantan 52
By adjusting various conditions so that the heat-resistant temperature becomes, it is possible to protect from oxidation due to high temperature heat and to obtain high electromotive force.
【0012】図3(b)に示したステンレス51は、上
述した図2のものとほぼ同様の方法で、コンスタンタン
52の先端部Bをカ−ルし、溶接される。カ−ル方向も
同様に、図中に示した互いに異なる方向とする。また、
図2(c)のステンレス51では、両端の長方形部分を
カ−ルしてコンスタンタン52の端部に溶接されるが、
上述した2つの実施例のようにステンレス51を曲折し
て隣合うコンスタンタン52同士の間隔を設けるのでは
なく、コンスタンタン52同士の距離を長方形部分Bの
カ−ルする中心軸の間の距離Lによって決定すれば、ス
テンレス51を曲折することなく、コンスタンタン52
の正確な位置を設定でき、且つ器具への取付も容易にで
きる。また、カ−ル方向は、高温接点側と冷温接点側と
は図中に示したように同方向である。これらの結果、単
純な形状、且つ低コストで直列型熱電対50を作ること
ができる。また、耐熱性が低いコンスタンタン52へは
直接炎を当てず、高温の熱による高温腐食・劣化が起こ
らないようにステンレス51で保護している為、耐久性
が向上している。The stainless steel 51 shown in FIG. 3 (b) is welded by curling the tip portion B of the constantan 52 in a manner substantially similar to that shown in FIG. The curl direction is also different from each other as shown in the figure. Also,
In the stainless steel 51 of FIG. 2C, the rectangular portions at both ends are curled and welded to the end of the constantan 52.
Rather than bending the stainless steel 51 to provide a space between the adjacent constantans 52 as in the two embodiments described above, the distance between the constantans 52 is determined by the distance L between the central axes of the curled rectangular portions B. If decided, the constantan 52 without bending the stainless steel 51
The precise position can be set, and it can be easily attached to the device. The curl direction is the same for the hot contact side and the cold contact side as shown in the figure. As a result, the series thermocouple 50 can be manufactured with a simple shape and at low cost. Further, the constantan 52, which has low heat resistance, is not directly exposed to the flame, and is protected by the stainless steel 51 so as not to be corroded or deteriorated by high temperature heat, so that the durability is improved.
【0013】また、図4に示した直列型熱電対60は、
コンスタンタンの板材62の端部をステンレスの板材6
1で覆うように曲げを行った後に溶接することによっ
て、固定・形成した熱電対素子を上述した方法で複数接
続したものである。また、冷温接点66は炎との接触は
ないことから、特にコンスタンタン62の端部をステン
レス61で覆う必要はないので、溶接処理を施すだけで
も良い。更に、上述した2種の板材を共に丸棒にしても
良い。この結果、図2に示した直列型熱電対50と同
様、低コストで耐久性を向上させることができる。The series type thermocouple 60 shown in FIG.
The end of the constantan plate 62 is replaced by a stainless plate 6
A plurality of thermocouple elements, which are fixed and formed by bending and bending so as to be covered with No. 1, are connected by the method described above. Further, since the cold / hot contact point 66 does not come into contact with the flame, it is not necessary to cover the end portion of the constantan 62 with the stainless steel 61, so that the welding process may be performed. Further, both of the above-mentioned two types of plate materials may be round bars. As a result, durability can be improved at low cost, as in the case of the serial thermocouple 50 shown in FIG.
【0014】こうした直列型熱電対の設置形態に示した
実施例を、図1の親子こんろバ−ナ31により説明す
る。図1中で使用している直列型熱電対50は、図2に
示したものである。親子こんろバ−ナ31は、火力の大
きい親バ−ナ33の中央部に火力の小さい子バ−ナを設
けたもので、調理品に応じてどちらかあるいは両方に点
火して火力を調節するようにしたこんろバ−ナである。An embodiment shown in the installation form of such a series type thermocouple will be described with reference to the parent-child stove burner 31 shown in FIG. The series thermocouple 50 used in FIG. 1 is the one shown in FIG. The parent-child stove burner 31 is provided with a child burner having a small heating power in the central portion of the parent burner 33 having a large heating power, and the heating power is adjusted by igniting one or both of them depending on the cooking product. It is a stove burner that is supposed to do.
【0015】親バーナは、鋳鉄等の鋳物で作成された親
バーナ本体32と、そのバーナ本体32に上から嵌合さ
れた黄銅等の熱間鍛造品からなる略円盤状の親バーナヘ
ッド33とから構成される。親バーナ本体32は、導入
された燃料ガスと1次空気とを混合する混合管34と、
その下流にあって混合気を環状に分布させ、親バーナヘ
ッド33との隙間より噴出させる環状の混合室35とが
一体となっている。混合室35の混合気噴出側(親バー
ナヘッド33との嵌合側)の中央には、燃焼時の2次空
気通路を兼ねた円筒状の位置決めガイド36が設けら
れ、親バーナヘッド33の中央部に形成されたリング状
の突起37がそこに位置決めされながら嵌合される。ま
た、混合管34より混合室35へ送られた混合気は、親
バーナヘッド33と親バーナ本体32との合わせ面によ
り形成された隙間を炎口として噴出し、リング状の火炎
31aを形成する。The parent burner includes a parent burner main body 32 made of cast iron or the like, and a substantially disc-shaped parent burner head 33 made of a hot forged product such as brass fitted on the burner main body 32 from above. Composed of. The main burner main body 32 includes a mixing pipe 34 that mixes the introduced fuel gas and primary air,
It is integrated with an annular mixing chamber 35 which is located downstream thereof and which distributes the air-fuel mixture annularly and ejects it from a gap between the parent burner head 33 and the parent burner head 33. A cylindrical positioning guide 36, which also serves as a secondary air passage at the time of combustion, is provided at the center of the air-fuel mixture jetting side (fitting side with the parent burner head 33) of the mixing chamber 35, and the center of the parent burner head 33 is provided. A ring-shaped protrusion 37 formed on the portion is fitted while being positioned therein. Further, the air-fuel mixture sent from the mixing pipe 34 to the mixing chamber 35 is ejected as a flame opening through a gap formed by the mating surfaces of the parent burner head 33 and the parent burner main body 32 to form a ring-shaped flame 31a. .
【0016】子バ−ナは、親バ−ナ本体32及び親バ−
ナヘッド33中央の円孔部を通って突出した子バ−ナ本
体38と、この子バ−ナ本体38に上方から嵌合された
黄銅等の熱間鍛造品からなる略円盤状の子バ−ナヘッド
39とから構成される。The child burner includes a parent burner main body 32 and a parent burner.
Child disk main body 38 protruding through a circular hole in the center of the head 33, and a substantially disk-shaped child bar made of a hot forged product such as brass fitted to the child burner body 38 from above. And a head 39.
【0017】直列型熱電対50は、この子バ−ナの火炎
31aの下方から高温接点55が火炎31aに臨む位置
に固定され、熱起電力を発生する。そして、発生した熱
起電力に応じて、電源を必要とする各制御装置(図示
略)を作動させる。尚、こうした親子こんろバ−ナ31
であっても、子バ−ナばかりでなくその周囲に設けられ
た親バ−ナにおいても、図1中の直列型熱電対50aの
様にして直列型熱電対を設置することができ、同様の作
用・効果を得ることができる。また、直列型熱電対50
は、バ−ナの全周に限らず、その一部として円弧状に配
置しても良い。The series thermocouple 50 is fixed at a position where the high temperature contact 55 faces the flame 31a from below the flame 31a of the child burner and generates a thermoelectromotive force. Then, each control device (not shown) that requires a power source is operated in accordance with the generated thermoelectromotive force. In addition, such parent-child stove burner 31
However, not only in the child burner but also in the parent burner provided around the child burner, the series type thermocouple can be installed like the series type thermocouple 50a in FIG. The action and effect of can be obtained. In addition, a series thermocouple 50
Is not limited to the entire circumference of the burner, but may be arranged in an arc shape as a part thereof.
【0018】以上説明したように、本実施例の直列型熱
電対50によれば、燃焼時に起こる酸化に対する耐久性
の高いステンレス51で、酸化に弱いコンスタンタン5
2を覆うことによって、簡単な構成で熱電対素子50の
高温接点55の酸化に対する耐久性の向上を図ることが
でき、且つ高い起電力を得ることができる。また、多数
の熱電対素子50を直列につなぎ、その高温接点55を
リング状にこんろバ−ナ31の周囲に均一に並べ、こん
ろバーナ31の火炎31a全体に臨ませているので、火
炎31aから発生する熱を効率良く大量に受けることが
できる。As described above, according to the in-line type thermocouple 50 of this embodiment, the stainless steel 51 has high durability against oxidation that occurs during combustion, and the constantan 5 which is weak against oxidation.
By covering 2 the durability of the thermocouple element 50 against oxidation of the high temperature contact 55 can be improved and a high electromotive force can be obtained with a simple configuration. Further, since a large number of thermocouple elements 50 are connected in series and the high temperature contacts 55 thereof are uniformly arranged in a ring shape around the cooking stove burner 31, the flame 31a of the cooking stove burner 31 is entirely exposed to the flame. A large amount of heat generated from 31a can be efficiently received.
【0019】以上本発明の実施例について説明したが、
本発明はこうした実施例に何等限定されるものではな
く、本発明の要旨を逸脱しない範囲において、種々なる
態様で実施し得ることは勿論である。例えば、湯沸器等
のガス燃焼器にも適用できるものである。The embodiment of the present invention has been described above.
The present invention is not limited to these examples, and it goes without saying that the present invention can be implemented in various modes without departing from the gist of the present invention. For example, it can be applied to a gas combustor such as a water heater.
【0020】[0020]
【発明の効果】以上記述したように本発明の請求項1記
載の直列型熱電対によれば、耐熱性の高い方の金属片
で、低い方の金属片を覆うという単純な構造で高温接点
を構成し、燃焼時に起こる耐熱性が低い方の金属片の高
温腐食・劣化を抑制することができる為、低コストで耐
久性を向上させることができ、安定した高い起電力を得
ることができる。また、請求項2記載の直列型熱電対に
よれば、こんろバ−ナのバ−ナ火炎から発生する燃焼熱
を大量に受けることができる為、効率よく高い起電力を
得ることができる。As described above, according to the series type thermocouple of claim 1 of the present invention, the high temperature contact has a simple structure in which the metal piece having a higher heat resistance covers the metal piece having a lower heat resistance. Since it is possible to suppress high temperature corrosion and deterioration of the metal piece having lower heat resistance that occurs during combustion, durability can be improved at low cost and stable high electromotive force can be obtained. . Moreover, according to the series type thermocouple of the second aspect, a large amount of combustion heat generated from the burner flame of the stove burner can be received, so that a high electromotive force can be efficiently obtained.
【図1】本発明の一実施例のこんろバ−ナの概略図であ
る。FIG. 1 is a schematic view of a stove burner according to an embodiment of the present invention.
【図2】第一実施例の直列型熱電対の説明図である。FIG. 2 is an explanatory diagram of a series type thermocouple of the first embodiment.
【図3】第一実施例の直列型熱電対を構成する要素の説
明図である。FIG. 3 is an explanatory diagram of elements forming the series thermocouple of the first embodiment.
【図4】第二実施例の直列型熱電対の説明図である。FIG. 4 is an explanatory view of a series type thermocouple of a second embodiment.
【図5】従来技術の直列型熱電対の説明図である。FIG. 5 is an explanatory view of a conventional series type thermocouple.
バ−ナ ・・・31 直列型熱電対 ・・・50,60 ステンレス材 ・・・51,61 コンスタンタン材・・・52,62 リ−ド線 ・・・53,63 高温接点 ・・・55,65 冷温接点 ・・・56,66 Burner ・ ・ ・ 31 Series thermocouple ・ ・ ・ 50,60 Stainless steel ・ ・ ・ 51,61 Constantan ・ ・ ・ 52,62 Lead wire ・ ・ ・ 53,63 High temperature contact ・ ・ ・ 55, 65 Cold and hot contact ・ ・ ・ 56,66
Claims (2)
対素子を複数接続した直列型熱電対において、 上記2つの金属片のうち、耐熱性が高い方の金属片の端
部で、耐熱性が低い方の金属片の端部を覆うように接合
して火炎に接触する高温接点を構成したことを特徴とす
る直列型熱電対。1. A series type thermocouple in which a plurality of thermocouple elements, in which two dissimilar metal pieces are joined and formed, are connected to each other, wherein a heat resistance is provided at an end of a metal piece having a higher heat resistance of the two metal pieces. A series-type thermocouple, characterized in that a high-temperature contact which is joined to cover an end of a metal piece having a lower property and contacts a flame is constructed.
ことを特徴とする直列型熱電対。2. The series type thermocouple according to claim 1, wherein the series type thermocouple is arranged around the entire circumference of the stove burner or a part thereof.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP7248708A JPH0974228A (en) | 1995-09-01 | 1995-09-01 | Series type thermocouple |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP7248708A JPH0974228A (en) | 1995-09-01 | 1995-09-01 | Series type thermocouple |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| JPH0974228A true JPH0974228A (en) | 1997-03-18 |
Family
ID=17182162
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP7248708A Pending JPH0974228A (en) | 1995-09-01 | 1995-09-01 | Series type thermocouple |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JPH0974228A (en) |
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2006004060A1 (en) * | 2004-07-01 | 2006-01-12 | Aruze Corp. | Thermoelectric conversion module |
| JP2006292703A (en) * | 2005-04-05 | 2006-10-26 | Yoshinobu Abe | Thermocouple |
| WO2007145183A1 (en) * | 2006-06-14 | 2007-12-21 | Aruze Corp. | Thermoelectric conversion module, and connector for thermoelectric conversion modules |
-
1995
- 1995-09-01 JP JP7248708A patent/JPH0974228A/en active Pending
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2006004060A1 (en) * | 2004-07-01 | 2006-01-12 | Aruze Corp. | Thermoelectric conversion module |
| JP2006292703A (en) * | 2005-04-05 | 2006-10-26 | Yoshinobu Abe | Thermocouple |
| JP4671752B2 (en) * | 2005-04-05 | 2011-04-20 | 可伸 安部 | thermocouple |
| WO2007145183A1 (en) * | 2006-06-14 | 2007-12-21 | Aruze Corp. | Thermoelectric conversion module, and connector for thermoelectric conversion modules |
| US8796533B2 (en) | 2006-06-14 | 2014-08-05 | Universal Entertainment Corporation | Thermoelectric conversion module and connector for thermoelectric conversion elements |
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