JP2846244B2 - heater - Google Patents
heaterInfo
- Publication number
- JP2846244B2 JP2846244B2 JP15137194A JP15137194A JP2846244B2 JP 2846244 B2 JP2846244 B2 JP 2846244B2 JP 15137194 A JP15137194 A JP 15137194A JP 15137194 A JP15137194 A JP 15137194A JP 2846244 B2 JP2846244 B2 JP 2846244B2
- Authority
- JP
- Japan
- Prior art keywords
- temperature coefficient
- positive temperature
- coefficient thermistor
- electrode
- heater
- 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.)
- Expired - Lifetime
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- Surface Heating Bodies (AREA)
- Resistance Heating (AREA)
Description
【0001】[0001]
【産業上の利用分野】本発明は、正特性サーミスタを発
熱要素として用いたヒータに関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heater using a positive temperature coefficient thermistor as a heating element.
【0002】[0002]
【従来の技術】正特性サーミスタを発熱要素とするヒー
タは従来よりよく知られている。正特性サーミスタは、
自己温度制御機能により定温動作をするから、安全で信
頼性の高いヒータを実現できる。この種のヒータは、正
特性サーミスタを、一対の電極板で挟み込み、電極板を
介して駆動する構造を有する。電極板は、更に、間接的
または直接的に放熱板に熱結合され、放熱板を介して熱
が取出される。水や油等の液体加熱に用いる場合は、放
熱板はケースによって構成され、このケース内に正特性
サーミスタ及び電極板等の基本要素が収納される。大き
な発熱量を得る場合は、複数個の正特性サーミスタを用
い、正特性サーミスタのそれぞれを、共通の一対の電極
板で挟み込み、電極板を介して、複数の正特性サーミス
タを同時に駆動する。このような組立構造についての関
連技術文献例としては、例えば実公平4ー36071号
公報がある。2. Description of the Related Art A heater using a PTC thermistor as a heating element has been well known. Positive characteristic thermistors
Since the constant temperature operation is performed by the self-temperature control function, a safe and highly reliable heater can be realized. This type of heater has a structure in which a PTC thermistor is sandwiched between a pair of electrode plates and driven via the electrode plates. The electrode plate is further indirectly or directly thermally coupled to the heat sink, and heat is extracted through the heat sink. When used for heating liquid such as water or oil, the radiator plate is constituted by a case, and the case accommodates basic elements such as a positive temperature coefficient thermistor and an electrode plate. When a large amount of heat is to be obtained, a plurality of PTC thermistors are used, each of the PTC thermistors is sandwiched between a pair of common electrode plates, and the plurality of PTC thermistors are simultaneously driven via the electrode plates. As a related technical document example of such an assembly structure, there is, for example, Japanese Utility Model Publication No. 4-36071.
【0003】[0003]
【発明が解決しようとする課題】前述したように、この
種のヒータにおいて、電極板は正特性サーミスタに対す
る給電のみならず、熱伝導体としても用いられるので、
正特性サーミスタに対する電極板の電気的接触及び熱結
合を密にすることがきわめて重要になる。しかし、これ
らの条件を、組立の容易さ、構造の簡素化等を確保しつ
つ、確実に満たすことは、技術的な困難性を伴う。As described above, in this type of heater, the electrode plate is used not only for supplying power to the positive temperature coefficient thermistor but also as a heat conductor.
Tighter electrical contact and thermal coupling of the electrode plate to the positive temperature coefficient thermistor is extremely important. However, it is technically difficult to reliably satisfy these conditions while ensuring ease of assembly and simplification of the structure.
【0004】更に、正特性サーミスタに対する電極板の
電気的接触及び熱結合を密にし、正特性サーミスタを完
全密閉状に封止した場合、正特性サーミスタを構成する
磁器素体、例えばチタン酸バリウム系半導体磁器が劣化
し、正特性サーミスタのピークの抵抗値が低下し、熱暴
走、熱破壊を生じることがある。Furthermore, when the electrical contact and thermal coupling of the electrode plate to the positive temperature coefficient thermistor are made high and the positive temperature coefficient thermistor is completely sealed, a porcelain body constituting the positive temperature coefficient thermistor, for example, a barium titanate-based material The semiconductor porcelain deteriorates, the peak resistance of the positive temperature coefficient thermistor decreases, and thermal runaway and thermal destruction may occur.
【0005】本発明の課題は、自己温度制御機能に基づ
く定温発熱動作型のヒータを提供することである。[0005] It is an object of the present invention to provide a constant temperature heating operation type heater based on a self temperature control function.
【0006】本発明のもう一つの課題は、組立の容易な
ヒータを提供することである。It is another object of the present invention to provide a heater which is easy to assemble.
【0007】本発明の更にもう一つの課題は、正特性サ
ーミスタを所定位置に確実に位置決めし得るヒータを提
供することである。Still another object of the present invention is to provide a heater capable of reliably positioning a positive temperature coefficient thermistor at a predetermined position.
【0008】本発明の更にもう一つの課題は、正特性サ
ーミスタの劣化及びそれに伴う熱暴走を確実に防止し得
るヒータを提供することである。Still another object of the present invention is to provide a heater capable of reliably preventing deterioration of the positive temperature coefficient thermistor and accompanying thermal runaway.
【0009】[0009]
【課題を解決するための手段】上述した課題解決のた
め、本発明に係るヒータは、1つのケースと、少なくと
も2つの絶縁枠部材と、少なくとも2つの電極板と、少
なくとも1つの正特性サーミスタとを含む。前記ケース
は、放熱面を含んで構成された内部空間を有している。
前記絶縁枠部材のそれぞれは、板状であって、面内に孔
を有し、前記孔が前記正特性サーミスタの数に対応した
数だけ備えられ、一面が互いに対向するように、前記ケ
ースの前記内部空間内に配置されている。前記電極板の
それぞれは、前記絶縁枠部材の他面側に重ねられ、前記
ケースの前記放熱面に熱結合している。前記正特性サー
ミスタは、正特性サーミスタ素体の厚み方向の両面に電
極を有し、前記絶縁枠部材の前記孔内に配置され、前記
電極のそれぞれが前記電極板に電気的に接触して導通
し、前記電極が電極板に接触した状態で前記絶縁枠部材
の対向面間に隙間を生じさせる厚みを有する。In order to solve the above-mentioned problems, a heater according to the present invention comprises a case, at least two insulating frame members, at least two electrode plates, and at least one positive temperature coefficient thermistor. including. The case has an internal space including a heat radiation surface.
Each of the insulating frame members is plate-shaped, has holes in a plane, and the holes are provided in a number corresponding to the number of the positive temperature coefficient thermistors, and the surfaces of the case are arranged so that one surface faces each other. It is arranged in the internal space. Each of the electrode plates is stacked on the other surface side of the insulating frame member, and is thermally coupled to the heat dissipation surface of the case. The positive temperature coefficient thermistor has electrodes on both surfaces in the thickness direction of the positive temperature coefficient thermistor body, is disposed in the hole of the insulating frame member, and each of the electrodes is electrically contacted with the electrode plate to conduct. In addition, the electrode has a thickness such that a gap is formed between the opposing surfaces of the insulating frame member when the electrode is in contact with the electrode plate.
【0010】好ましくは、前記電極板は、電極接触部に
突起を有する。[0010] Preferably, the electrode plate has a projection at an electrode contact portion.
【0011】更に好ましくは、熱伝導性充填物を含み、
前記熱伝導性充填物は、樹脂でなり、前記正特性サーミ
スタの前記電極と、前記電極板との間に、前記突起によ
って生じる隙間を埋めるように、充填されている。More preferably, it comprises a thermally conductive filler,
The heat conductive filler is made of resin, and is filled between the electrode of the positive temperature coefficient thermistor and the electrode plate so as to fill a gap created by the protrusion.
【0012】[0012]
【作用】正特性サーミスタは正特性サーミスタ素体の厚
み方向の両面に電極を有し、電極のそれぞれが電極板に
電気的に接触して導通しているから、正特性サーミスタ
に対して電極板を通して給電することにより発熱動作を
させ、正特性サーミスタの自己温度制御機能により定温
発熱動作をするヒータが得られる。The positive temperature coefficient thermistor has electrodes on both sides in the thickness direction of the positive temperature coefficient thermistor body, and each of the electrodes is in electrical contact with the electrode plate to conduct electricity. , The heater operates to generate heat, and the self-temperature control function of the positive temperature coefficient thermistor provides a heater that generates heat at a constant temperature.
【0013】絶縁枠部材のそれぞれは、板状であって、
面内に孔を有し、孔が正特性サーミスタの数に対応した
数だけ備えられ、正特性サーミスタは絶縁枠部材の孔内
に配置されているから、正特性サーミスタの位置ずれが
防止される。このため、正特性サーミスタの位置ずれに
伴う発熱の不均一さをなくするとともに、正特性サーミ
スタ側面に対する樹脂の付着を防ぎ、信頼性の高いヒー
タを実現できる。Each of the insulating frame members has a plate shape,
It has holes in the plane, and the holes are provided in a number corresponding to the number of the PTC thermistors. Since the PTC thermistors are arranged in the holes of the insulating frame member, the displacement of the PTC thermistors is prevented. . Therefore, it is possible to eliminate the non-uniformity of heat generation due to the displacement of the positive temperature coefficient thermistor, prevent the resin from adhering to the side surface of the positive temperature coefficient thermistor, and realize a highly reliable heater.
【0014】正特性サーミスタは、電極が電極板に接触
した状態で絶縁枠部材の対向面間に隙間を生じさせる厚
みを有するから、前記隙間により、絶縁枠部材の孔を互
いに連絡する通気路が形成される。このため、正特性サ
ーミスタを構成する磁器素体の劣化を阻止し、正特性サ
ーミスタの劣化及びそれに伴う熱暴走、熱破壊を確実に
防止する。Since the positive temperature coefficient thermistor has a thickness that creates a gap between the opposing surfaces of the insulating frame member when the electrode is in contact with the electrode plate, the gap forms an air passage connecting the holes of the insulating frame member with each other. It is formed. For this reason, the deterioration of the porcelain body constituting the positive temperature coefficient thermistor is prevented, and the deterioration of the positive temperature coefficient thermistor and the resulting thermal runaway and thermal destruction are reliably prevented.
【0015】電極板が電極接触部に突起を有する好まし
い例では、電極板が突起の部分で正特性サーミスタの電
極に確実に接触する。In a preferred example in which the electrode plate has a projection at the electrode contact portion, the electrode plate reliably contacts the electrode of the positive temperature coefficient thermistor at the projection.
【0016】電極板が電極接触部に突起を有する構造に
おいて、熱伝導性充填物が正特性サーミスタの電極と、
電極板との間に、突起によって生じる隙間を埋めるよう
に、充填されている好ましい例では、正特性サーミスタ
に発生した熱が熱伝導性充填物を介して電極板に確実に
伝達される。このため、突起により、電極板と正特性サ
ーミスタの電極との間に隔たりが生じているにもかかわ
らず、両者間に高い熱結合が構成される。この結果、電
極板と正特性サーミスタとの間の電気的接触を確保する
と共に、正特性サーミスタから電極板への熱伝導効率を
向上させたヒータが得られる。In a structure in which the electrode plate has a projection at an electrode contact portion, the thermally conductive filler is provided with an electrode of a positive temperature coefficient thermistor,
In a preferred example, the space between the electrode plate and the electrode plate is filled so as to fill the gap created by the protrusion, the heat generated in the positive temperature coefficient thermistor is reliably transmitted to the electrode plate via the thermally conductive filler. For this reason, high thermal coupling is formed between the electrode plate and the electrode of the positive temperature coefficient thermistor, despite the separation between the two. As a result, a heater can be obtained in which electrical contact between the electrode plate and the positive temperature coefficient thermistor is ensured and the efficiency of heat conduction from the positive temperature coefficient thermistor to the electrode plate is improved.
【0017】熱伝導性充填物は樹脂でなるから、正特性
サーミスタの発熱動作時に熱伝導性充填物にかなり大き
な熱歪が発生する。電極板は正特性サーミスタと接触す
る面側に突起を有しているから、熱伝導性充填物は、ケ
ースとの熱結合面側よりも、電極板の突起のある側に多
く充填される。このため、熱伝導性充填物に発生した熱
歪が電極板を押し上げるように作用する。電極板は、ケ
ースの放熱面側に機械的に固定または接触しているの
で、熱伝導性充填物の熱膨張に起因する熱歪を受けたと
き、ケース側固定点または接触点を支点として、反作用
的に、正特性サーミスタの方向に押し付けられる。この
ため、電極板に備えられた突起が正特性サーミスタの電
極の表面に対して押付けられ、発熱動作時にも、安定し
た電気的接触が得られる。Since the thermally conductive filler is made of a resin, a considerably large thermal strain is generated in the thermally conductive filler when the positive temperature coefficient thermistor generates heat. Since the electrode plate has a protrusion on the surface contacting the positive temperature coefficient thermistor, the thermally conductive filler is filled more on the side of the electrode plate with the protrusion than on the side of the heat coupling surface with the case. Therefore, the thermal strain generated in the thermally conductive filler acts to push up the electrode plate. Since the electrode plate is mechanically fixed or in contact with the heat dissipation surface side of the case, when subjected to thermal strain caused by thermal expansion of the thermally conductive filler, the case side fixed point or contact point is used as a fulcrum, In reaction, it is pressed in the direction of the positive temperature coefficient thermistor. For this reason, the projection provided on the electrode plate is pressed against the surface of the electrode of the positive temperature coefficient thermistor, and stable electrical contact can be obtained even during the heating operation.
【0018】発熱量増大のために、複数の正特性サーミ
スタを用いた場合にも、各正特性サーミスタと電極板と
の間に上記した構造を形成することにより、各正特性サ
ーミスタ毎に上述した作用を得ることができる。Even when a plurality of PTC thermistors are used to increase the amount of heat generated, the above-described structure is formed between each PTC thermistor and the electrode plate, so that each PTC thermistor is described above. Action can be obtained.
【0019】[0019]
【実施例】図1は本発明に係るヒータの分解斜視図、図
2は図1に示されたヒータを構成する電極板及び絶縁枠
部材の拡大分解斜視図、図3は図1に示したヒータの一
部を示す拡大断面図、図4は図2に示した電極板と絶縁
枠部材の組立状態を部分的に示す断面図である。本発明
に係るヒータは、ケース1と、絶縁枠部材91、92
と、電極板21、22と、正特性サーミスタ3とを含ん
でいる。FIG. 1 is an exploded perspective view of a heater according to the present invention, FIG. 2 is an enlarged exploded perspective view of an electrode plate and an insulating frame member constituting the heater shown in FIG. 1, and FIG. FIG. 4 is an enlarged sectional view showing a part of the heater, and FIG. 4 is a sectional view partially showing an assembled state of the electrode plate and the insulating frame member shown in FIG. The heater according to the present invention includes a case 1 and insulating frame members 91 and 92.
And the electrode plates 21 and 22 and the positive temperature coefficient thermistor 3.
【0020】ケース1は、間隔を隔てて対向する一対の
放熱面11、12を含んで形成された内部空間13を有
する。内部空間13は放熱面11、12に対して側部と
なる一辺部に開口部14を有し、開口部14を除く全周
を閉じている。実施例に示すケース1は、例えばステン
レス板等の金属板材で構成されていて、周辺がネジ等の
結合具15による機械的結合または溶接もしくは接着等
の手段によって、完全に密閉されている。The case 1 has an internal space 13 including a pair of heat radiating surfaces 11 and 12 facing each other at an interval. The internal space 13 has an opening 14 on one side that is a side portion with respect to the heat radiation surfaces 11 and 12, and the entire periphery except the opening 14 is closed. The case 1 shown in the embodiment is made of, for example, a metal plate such as a stainless steel plate, and its periphery is completely sealed by means of mechanical coupling with a coupling 15 such as a screw or welding or bonding.
【0021】絶縁枠部材91、92のそれぞれは、板状
であって、面内に孔911、921を有する。孔91
1、921は正特性サーミスタ3の数に対応した数だけ
備えられている。絶縁枠部材91、92のそれぞれは、
一面912、922が互いに対向するように、ケース1
の内部空間13の内部に配置されている。絶縁枠部材9
1、92は耐熱性に優れた電気絶縁材料、例えばポリフ
ェニリンサルファイド(P.P.S)またはベーク等に
よって形成する。孔911、921は円形または多角形
状の何れでもよい。Each of the insulating frame members 91 and 92 is plate-shaped and has holes 911 and 921 in the plane. Hole 91
1 and 921 are provided in a number corresponding to the number of the PTC thermistors 3. Each of the insulating frame members 91 and 92 is
Case 1 so that the surfaces 912 and 922 face each other.
Is arranged inside the internal space 13. Insulating frame member 9
Reference numerals 1 and 92 are formed of an electric insulating material having excellent heat resistance, for example, polyphenylene sulfide (PPS) or bake. The holes 911 and 921 may be circular or polygonal.
【0022】電極板21、22は、一対備えられてお
り、それぞれは、絶縁枠部材91、92の他面側に重ね
られ、ケース1の放熱面11、12に電気絶縁して熱結
合している。図示の電極板21、22のそれぞれは、一
面212、222に突起211、221を有し、一面2
12、222が絶縁枠部材91の他面913、923側
に重ねられ、面213、223がケース1の放熱面1
1、12に熱結合し、ケース1の内部空間13内に収納
されている。電極板21、22と絶縁枠部材91、92
の間は適当な接着剤を用いて接着する。実施例におい
て、突起211、221は3〜4個を1組として、この
組を適当な間隔で配置してある。参照符号23、24は
電極板21、22に接続されたリード線である。A pair of electrode plates 21 and 22 are provided, each of which is superimposed on the other surface of the insulating frame members 91 and 92, and is electrically insulated and thermally coupled to the heat radiation surfaces 11 and 12 of the case 1. I have. Each of the illustrated electrode plates 21 and 22 has protrusions 211 and 221 on one surface 212 and 222, respectively.
12 and 222 are overlapped on the other surfaces 913 and 923 of the insulating frame member 91, and the surfaces 213 and 223
1 and 12 are housed in the internal space 13 of the case 1. Electrode plates 21, 22 and insulating frame members 91, 92
Adhesion is performed using an appropriate adhesive. In the embodiment, three to four projections 211 and 221 are set as one set, and the sets are arranged at appropriate intervals. Reference numerals 23 and 24 are lead wires connected to the electrode plates 21 and 22.
【0023】ケース1の放熱面11、12と電極板2
1、22との間には電気絶縁層51、52が設けられて
いる。電気絶縁層51、52は耐熱性が高く、かつ、熱
伝導に優れた電気絶縁材料、例えばアルミナ、窒化アル
ミナ、ポリイミドまたはマイカ等によって構成できる。
電気絶縁層51、52とケース1との接触面は、熱伝導
率の高い耐熱接着剤61、62によって接着することが
望ましい。耐熱性接着剤61、62としては、熱可塑性
ポリイミド樹脂またはシリコン系樹脂を用いることがで
きる。電気絶縁層51、52を熱可塑性ポリイミドによ
って構成した場合には、それ自体を接着剤層として兼用
できる。ケース1はアルミナ等によって構成することも
でき、このような場合には、電気絶縁層51、52は省
略できる。Heat radiation surfaces 11 and 12 of case 1 and electrode plate 2
Electrical insulating layers 51 and 52 are provided between the first and second layers. The electric insulating layers 51 and 52 can be made of an electric insulating material having high heat resistance and excellent heat conductivity, for example, alumina, alumina nitride, polyimide or mica.
It is desirable that the contact surfaces between the electric insulating layers 51 and 52 and the case 1 be bonded with heat-resistant adhesives 61 and 62 having high thermal conductivity. As the heat-resistant adhesives 61 and 62, a thermoplastic polyimide resin or a silicon-based resin can be used. When the electric insulating layers 51 and 52 are made of thermoplastic polyimide, they can also be used as adhesive layers. The case 1 can be made of alumina or the like, and in such a case, the electric insulating layers 51 and 52 can be omitted.
【0024】正特性サーミスタ3は、正特性サーミスタ
素体31の厚み方向の両面に電極32、33を有し、絶
縁枠部材91、92の孔911、921内に配置されて
いる。正特性サーミスタ3の電極32、33のそれぞれ
は、電極板21、22に電気的に接触して導通してい
る。図示では、正特性サーミスタ3は、複数個備えら
れ、電極32、33のそれぞれに突起211、221が
圧接するように、内部空間13の内部に配置されてい
る。The positive temperature coefficient thermistor 3 has electrodes 32, 33 on both sides in the thickness direction of the positive temperature coefficient thermistor body 31, and is disposed in holes 911, 921 of insulating frame members 91, 92. Each of the electrodes 32 and 33 of the positive temperature coefficient thermistor 3 is electrically connected to the electrode plates 21 and 22 so as to conduct. In the figure, a plurality of PTC thermistors 3 are provided, and are arranged inside the internal space 13 such that the protrusions 211 and 221 are pressed against the electrodes 32 and 33, respectively.
【0025】正特性サーミスタ3は電極32、33が電
極板21、22に接触した状態で、絶縁枠部材91、9
2の対向面間に隙間Gを生じさせる厚みd0を有する。The PTC thermistor 3 holds the insulating frame members 91 and 9 in a state where the electrodes 32 and 33 are in contact with the electrode plates 21 and 22.
2 has a thickness d0 that creates a gap G between the opposing surfaces.
【0026】正特性サーミスタ3は正特性サーミスタ素
体31の厚み方向の両面に電極32、33を有し、電極
32、33のそれぞれが電極板21、22に電気的に接
触して導通しいるから、正特性サーミスタ3に対して電
極板21、22を通して給電することにより発熱動作を
させ、正特性サーミスタ3の自己温度制御機能により定
温発熱動作をするヒータが得られる。The positive temperature coefficient thermistor 3 has electrodes 32 and 33 on both sides in the thickness direction of the positive temperature coefficient thermistor body 31, and the electrodes 32 and 33 are electrically connected to the electrode plates 21 and 22, respectively, to conduct electricity. Thus, the heater is operated by supplying power to the positive temperature coefficient thermistor 3 through the electrode plates 21 and 22, and the constant temperature heat generation operation is performed by the self temperature control function of the positive temperature coefficient thermistor 3.
【0027】絶縁枠部材91、92のそれぞれは、板状
であって、面内に孔911、921を有し、孔911、
921が正特性サーミスタ3の数に対応した数だけ備え
られ、正特性サーミスタ3は絶縁枠部材91、92の孔
911、921内に配置されているから、正特性サーミ
スタ3の位置ずれが防止される。このため、正特性サー
ミスタ3の位置ずれに伴う発熱の不均一さをなくすると
ともに、正特性サーミスタ側面に対する樹脂の付着を防
ぎ、信頼性の高いヒータを実現できる。Each of the insulating frame members 91 and 92 has a plate shape and has holes 911 and 921 in the plane.
921 are provided in a number corresponding to the number of the PTC thermistors 3, and the PTC thermistors 3 are arranged in the holes 911 and 921 of the insulating frame members 91 and 92, so that the displacement of the PTC thermistor 3 is prevented. You. For this reason, the uniformity of heat generation due to the displacement of the positive temperature coefficient thermistor 3 is eliminated, and the adhesion of resin to the side surface of the positive temperature coefficient thermistor is prevented, so that a highly reliable heater can be realized.
【0028】正特性サーミスタ3は、電極32、33が
電極板21、22に接触した状態で絶縁枠部材91、9
2の対向面間に隙間Gを生じさせる厚みd0を有するか
ら、隙間Gにより、絶縁枠部材91、92の孔911、
921を互いに連絡する通気路93が形成される。この
ため、正特性サーミスタ3を構成する磁器素体31、例
えばチタン酸バリウム系半導体磁器の劣化が阻止され、
正特性サーミスタ3の劣化及びそれに伴う熱暴走、熱破
壊が確実に防止される。上述の通気路93が形成されて
いない場合、正特性サーミスタ3の入っている孔91
1、921が密閉された状態になり、正特性サーミスタ
3のピークの抵抗値が低下し、熱暴走を生じる危険性が
あることが分かった。その理由は、正特性サーミスタ3
の入っている孔911、921が閉塞された場合、正特
性サーミスタ3を構成する磁器素体31が、加熱された
孔91内の空気によって還元作用を受けるためと推測さ
れる。本発明によれば、前述したように、このような問
題を解決できる。The PTC thermistor 3 is configured such that the electrodes 32 and 33 are in contact with the electrode plates 21 and 22 while the insulating frame members 91 and 9 are in contact with each other.
2 has a thickness d0 for forming a gap G between the opposing surfaces, the gap G allows the holes 911 of the insulating frame members 91 and 92 to be formed.
An air passage 93 connecting the 921 to each other is formed. For this reason, the deterioration of the porcelain body 31 constituting the positive temperature coefficient thermistor 3, for example, the barium titanate-based semiconductor porcelain is prevented,
Deterioration of the positive temperature coefficient thermistor 3 and accompanying thermal runaway and thermal destruction are reliably prevented. When the above-described ventilation path 93 is not formed, the hole 91 containing the PTC thermistor 3 is formed.
1 and 921 were sealed, and it was found that the peak resistance value of the positive temperature coefficient thermistor 3 was reduced and there was a risk of causing thermal runaway. The reason is that the positive characteristic thermistor 3
When the holes 911 and 921 containing the holes are closed, it is presumed that the porcelain body 31 constituting the positive temperature coefficient thermistor 3 is subjected to a reducing action by the air in the heated hole 91. According to the present invention, as described above, such a problem can be solved.
【0029】電極板21、22のそれぞれが、一面21
2、222に突起211、221を有し、一面212、
222が間隔を隔てて対向し、他面213、223が放
熱面11、12によって支持されるように、ケース1の
内部空間13内に収納されている実施例によれば、電極
板21、22が突起211、221の部分で正特性サー
ミスタ3の電極32、33に確実に接触する。Each of the electrode plates 21 and 22 is
2, 222 have protrusions 211, 221 and one surface 212,
According to the embodiment in which the electrode plates 21 and 22 are accommodated in the internal space 13 of the case 1 so that the opposite surfaces 222 and 223 and 223 are supported by the heat dissipation surfaces 11 and 12 at intervals. Are in reliable contact with the electrodes 32 and 33 of the positive temperature coefficient thermistor 3 at the projections 211 and 221.
【0030】電極板21、22が突起211、221を
有する構造の場合、正特性サーミスタ3の電極32、3
3と、電極板21、22との間に、突起211、221
によって生じる隙間を埋めるように、熱伝導性充填物4
1、42を充填することが望ましい。ここで選定される
べき熱伝導性充填物41、42は樹脂である。上述の熱
伝導性充填物41、42により、正特性サーミスタ3に
発生した熱が熱伝導性充填物41、42を介して電極板
21、22に確実に伝達される。このため、突起21
1、221により、電極板21、22と正特性サーミス
タ3の電極32、33との間に隔たりが生じているにも
かかわらず、両者間に高い熱結合が構成される。このた
め、電極板21、22と正特性サーミスタ3との間の電
気的接触を確保すると共に、正特性サーミスタ3から電
極板21、22への熱伝導効率を向上させたヒータが得
られる。In the case where the electrode plates 21 and 22 have the projections 211 and 221, the electrodes 32 and 3 of the positive temperature coefficient thermistor 3 are used.
3 and the electrode plates 21, 22 between the projections 211, 221.
To fill the gap created by the heat conductive filler 4
It is desirable to fill 1,42. The heat conductive fillers 41 and 42 to be selected here are resins. The heat generated in the positive temperature coefficient thermistor 3 is reliably transmitted to the electrode plates 21 and 22 via the heat conductive fillers 41 and 42 by the above-described heat conductive fillers 41 and 42. For this reason, the protrusion 21
Due to 1,221, high thermal coupling is formed between the electrode plates 21 and 22 and the electrodes 32 and 33 of the positive temperature coefficient thermistor 3 irrespective of the occurrence of a gap therebetween. Therefore, a heater can be obtained in which electrical contact between the electrode plates 21 and 22 and the PTC thermistor 3 is ensured and the efficiency of heat conduction from the PTC thermistor 3 to the electrode plates 21 and 22 is improved.
【0031】しかも、熱伝導性充填物41、42は樹脂
でなるから、図5に示すように、正特性サーミスタ3の
発熱動作時に、熱伝導性充填物41、42にかなり大き
な熱歪F1が発生する。電極板21、22は正特性サー
ミスタ3と接触する面212、222に突起211、2
21を有しているから、熱伝導性充填物41、42は、
ケース1との熱結合面側よりも、突起211、221の
ある側に多く充填される。このため、熱伝導性充填物4
1、42に発生した熱歪F1が電極板を押し上げるよう
に作用する。電極板21、22は、面213、223側
がケース1と機械的に固定または接触しているので、熱
伝導性充填物41、42の熱膨張に起因する熱歪F1を
受けたとき、ケース側固定点または接触点を支点P0と
して、矢印F2で示す如く、正特性サーミスタ3の方向
に押し付けられる。このため、電極板21、22に備え
られた突起211、221が正特性サーミスタ3の電極
32、33の表面に対して押付けられ、発熱動作時に
も、安定した電気的接触が得られる。なお、図5は熱歪
みによる押し付け作用を分かりやすく説明するために、
誇張して図示されている。Further, since the heat conductive fillers 41 and 42 are made of resin, as shown in FIG. 5, when the positive temperature coefficient thermistor 3 generates heat, a considerably large thermal strain F1 is applied to the heat conductive fillers 41 and 42. Occur. The electrode plates 21 and 22 have protrusions 211 and 2 on surfaces 212 and 222 that are in contact with the thermistor 3.
21 so that the thermally conductive fillers 41 and 42
It is more filled on the side where the protrusions 211 and 221 are located than on the side of the thermal coupling surface with the case 1. Therefore, the heat conductive filler 4
The thermal strain F1 generated in the first and second elements acts to push up the electrode plate. Since the electrode plates 21 and 22 have the surfaces 213 and 223 mechanically fixed or in contact with the case 1, when the electrode plates 21 and 22 receive the thermal strain F1 due to the thermal expansion of the thermally conductive fillers 41 and 42, The fixed point or the contact point is set as a fulcrum P0 and is pushed in the direction of the positive temperature coefficient thermistor 3 as shown by an arrow F2. For this reason, the projections 211 and 221 provided on the electrode plates 21 and 22 are pressed against the surfaces of the electrodes 32 and 33 of the positive temperature coefficient thermistor 3, and stable electrical contact can be obtained even during the heating operation. FIG. 5 shows the pressing action due to thermal strain in an easily understood manner.
The illustration is exaggerated.
【0032】図示はされていないが、ケース1の内部空
間13内に温度ヒューズを備え、この温度ヒューズによ
って、正特性サーミスタ3が故障等によって異常発熱動
作をした場合等に正特性サーミスタ3に対する給電を停
止させるように動作させることもできる。Although not shown, a thermal fuse is provided in the internal space 13 of the case 1, and the thermal fuse supplies power to the positive characteristic thermistor 3 when the positive temperature characteristic thermistor 3 performs an abnormal heating operation due to a failure or the like. Can also be operated to stop.
【0033】[0033]
【発明の効果】以上述べたように本発明によれば、次の
ような効果を得ることができる。 (a)自己温度制御機能に基づく定温発熱動作型のヒー
タを提供できる。 (b)組立の容易なヒータを提供できる。 (c)正特性サーミスタを所定位置に確実に位置決めし
得るヒータを提供できる。 (d)正特性サーミスタの劣化及びそれに伴う熱暴走を
確実に防止し得るヒータを提供できる。As described above, according to the present invention, the following effects can be obtained. (A) It is possible to provide a constant temperature heating operation type heater based on the self-temperature control function. (B) A heater that can be easily assembled can be provided. (C) It is possible to provide a heater that can reliably position the positive temperature coefficient thermistor at a predetermined position. (D) It is possible to provide a heater capable of reliably preventing deterioration of the positive temperature coefficient thermistor and accompanying thermal runaway.
【図1】本発明に係るヒータの分解斜視図である。FIG. 1 is an exploded perspective view of a heater according to the present invention.
【図2】図1に示されたヒータを構成する電極板及び絶
縁枠部材の拡大分解斜視図である。FIG. 2 is an enlarged exploded perspective view of an electrode plate and an insulating frame member constituting the heater shown in FIG.
【図3】図1に示されたヒータの一部を示す拡大断面図
である。FIG. 3 is an enlarged sectional view showing a part of the heater shown in FIG.
【図4】図2に示された電極板と絶縁枠部材の組立状態
を部分的に示す断面図である。FIG. 4 is a sectional view partially showing an assembled state of the electrode plate and the insulating frame member shown in FIG. 2;
【図5】本発明に係るヒータの作用を説明する図であ
る。FIG. 5 is a diagram illustrating the operation of the heater according to the present invention.
1 ケース 11、12 放熱面 13 内部空間 21、22 電極板 211、221 突起 3 正特性サーミスタ 31 正特性サーミスタ素体 32、33 電極 41、42 熱伝導性充填物 91、92 絶縁枠部材 911、921 孔 DESCRIPTION OF SYMBOLS 1 Case 11, 12 Heat dissipation surface 13 Internal space 21, 22 Electrode plate 211, 221 Projection 3 Positive temperature coefficient thermistor 31 Positive temperature coefficient thermistor body 32, 33 Electrode 41, 42 Thermal conductive filler 91, 92 Insulating frame member 911, 921 Hole
フロントページの続き (58)調査した分野(Int.Cl.6,DB名) H05B 3/02 - 3/18 H05B 3/40 - 3/82Continuation of the front page (58) Field surveyed (Int.Cl. 6 , DB name) H05B 3/02-3/18 H05B 3/40-3/82
Claims (3)
枠部材と、少なくとも2つの電極板と、少なくとも1つ
の正特性サーミスタとを含むヒータであって、 前記ケースは、放熱面を含んで構成された内部空間を有
しており、 前記絶縁枠部材のそれぞれは、板状であって、面内に孔
を有し、前記孔が前記正特性サーミスタの数に対応した
数だけ備えられ、一面が互いに対向するように、前記ケ
ースの前記内部空間内に配置されており、 前記電極板のそれぞれは、前記絶縁枠部材の他面側に重
ねられ、前記ケースの前記放熱面に熱結合しており、 前記正特性サーミスタは、正特性サーミスタ素体の厚み
方向の両面に電極を有し、前記絶縁枠部材の前記孔内に
配置され、前記電極のそれぞれが前記電極板に電気的に
接触して導通し、前記電極が電極板に接触した状態で、
前記絶縁枠部材の対向面間に隙間を生じさせる厚みを有
するヒータ。1. A heater including one case, at least two insulating frame members, at least two electrode plates, and at least one positive temperature coefficient thermistor, wherein the case includes a heat radiation surface. Each of the insulating frame members is plate-shaped, has holes in the surface, and the holes are provided in a number corresponding to the number of the positive temperature coefficient thermistors, and one surface is provided. The electrode plates are arranged in the internal space of the case so as to face each other, and each of the electrode plates is stacked on the other surface side of the insulating frame member, and is thermally coupled to the heat dissipation surface of the case. The positive temperature coefficient thermistor has electrodes on both sides in the thickness direction of the positive temperature coefficient thermistor body, is disposed in the hole of the insulating frame member, and each of the electrodes is in electrical contact with the electrode plate. Conducts and the electrode is In a state of being in contact with the electrode plate,
A heater having a thickness that creates a gap between the opposing surfaces of the insulating frame member.
なり、前記正特性サーミスタの前記電極と、前記電極板
との間に、前記突起によって生じる隙間を埋めるよう
に、充填されているヒータ。3. The heater according to claim 2, further comprising a thermally conductive filler, wherein the thermally conductive filler is made of a resin, and wherein the electrode of the positive temperature coefficient thermistor and the electrode plate are connected to each other. The heater is filled so as to fill a gap created by the protrusion.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP15137194A JP2846244B2 (en) | 1994-07-01 | 1994-07-01 | heater |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP15137194A JP2846244B2 (en) | 1994-07-01 | 1994-07-01 | heater |
Publications (2)
Publication Number | Publication Date |
---|---|
JPH0817559A JPH0817559A (en) | 1996-01-19 |
JP2846244B2 true JP2846244B2 (en) | 1999-01-13 |
Family
ID=15517101
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP15137194A Expired - Lifetime JP2846244B2 (en) | 1994-07-01 | 1994-07-01 | heater |
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JP (1) | JP2846244B2 (en) |
Families Citing this family (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6707987B2 (en) * | 2001-06-08 | 2004-03-16 | Algas-Sdi International Llc | Electric liquefied petroleum gas vaporizer |
JP5381879B2 (en) * | 2010-04-08 | 2014-01-08 | 住友電気工業株式会社 | Wafer heating heater unit and semiconductor manufacturing apparatus equipped with the same |
KR102589040B1 (en) * | 2016-12-27 | 2023-10-17 | 현대자동차주식회사 | Radiant heater for vehicle |
CN109587845A (en) * | 2018-10-24 | 2019-04-05 | 董林妤 | One kind exempting from binder baffle heater and its production technology |
-
1994
- 1994-07-01 JP JP15137194A patent/JP2846244B2/en not_active Expired - Lifetime
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