JPS5887792A - Heater - Google Patents
HeaterInfo
- Publication number
- JPS5887792A JPS5887792A JP15879581A JP15879581A JPS5887792A JP S5887792 A JPS5887792 A JP S5887792A JP 15879581 A JP15879581 A JP 15879581A JP 15879581 A JP15879581 A JP 15879581A JP S5887792 A JPS5887792 A JP S5887792A
- Authority
- JP
- Japan
- Prior art keywords
- heating element
- radiator
- metal foil
- heating
- radiation
- 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
Landscapes
- Control Of Resistance Heating (AREA)
Abstract
(57)【要約】本公報は電子出願前の出願データであるた
め要約のデータは記録されません。(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.
Description
【発明の詳細な説明】
本発明は、遠赤外線を放射する電気による発熱体、特に
速熱型の発熱体に関する。DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an electric heating element that emits far infrared rays, particularly a fast heating type heating element.
従来低温の放射体から赤外線特に遠赤外線領域全多く放
射させて乾燥、料理、暖房等に使用する発熱体があった
。これらの発熱体は、加熱を始めてから使用に耐える程
度の温度に達するまでに、早いものでも数10秒、遅い
ものでは数10分を要した。Conventionally, there have been heating elements that emit infrared rays, particularly in the far infrared region, from a low-temperature radiator and are used for drying, cooking, heating, etc. These heating elements require several tens of seconds at the earliest, and several tens of minutes at the latest, from the time they start heating until they reach a temperature suitable for use.
しかし極〈短時間で加熱作業を終了する、例えばオーブ
ントースタ−や、接写器用の定N”l<或はトイレット
の暖房等では、発熱体を予め予熱しておくことはエネル
ギの無駄であり、又時間の無駄でもある。故にこのよう
な目的にはできるだけ堅く温度が所要の高さに達するよ
うな、応答の−Lい発熱体が要望されていた。However, in cases where the heating process is completed in a very short time, such as in a toaster oven, constant N''l for a close-up camera, or for heating a toilet, preheating the heating element in advance is a waste of energy. It is also a waste of time.Thus, for such purposes, there is a need for a heating element that is as stiff as possible to reach the required temperature and has a low response.
本発明はこのような要望にこたえる為に発明された、応
答時間が数秒程ばの、スイッチ投入後非常に早く使用可
能の温度に達する赤外線領域特に遠赤外線領域の放射を
行う電気エネルギによる発熱体を提供することを目的と
する。The present invention was invented in response to these demands, and is a heating element that uses electrical energy to emit radiation in the infrared region, particularly in the far infrared region, with a response time of several seconds and which reaches a usable temperature very quickly after turning on the switch. The purpose is to provide
以下その詳細を説明する。The details will be explained below.
遠赤外線の放射を行う発熱体では、通常その放射面の表
面温度全100℃前後から600℃前後位までの範囲に
保たれる。In a heating element that emits far-infrared rays, the total surface temperature of its radiation surface is usually maintained within a range of about 100°C to about 600°C.
高温に保たれた放射面からは、その表面の温度による波
長帯域と放射率に応じた灰色放射が行われる。A radiation surface kept at a high temperature emits gray radiation according to the wavelength band and emissivity depending on the temperature of the surface.
問題は如何にして放射率の良好な放射面を持つ発熱体を
作り、そしてそれをどのようにして早く温度上昇させる
かである。The problem is how to create a heating element with a radiation surface with good emissivity, and how to quickly raise the temperature of it.
第1図は本発明の実施例を示す発熱体の構造の簡略図で
ある。FIG. 1 is a simplified diagram of the structure of a heating element showing an embodiment of the present invention.
第1図で1は発熱体、2は発熱素子、3は放射体、4は
支持電極である。In FIG. 1, 1 is a heating element, 2 is a heating element, 3 is a radiator, and 4 is a support electrode.
遠赤外線の放射面は温度が低いので、単位面積当りの放
射エネルギは、通常ρタングステンランプや赤外線ラン
プのフィラメント等に比べると、格段に少ない。例えば
100℃近辺の放射面の放射量は”−IW/cJ、 6
o □℃で5W/−位であるから、数100W或は数
KWの放射全必要とする通常の用途では当然、放射面が
広くなくてはならない。一方早く温度上昇させる為には
発熱体の熱容量が小さくなくてはな牧ない。Since the far-infrared ray radiation surface has a low temperature, the radiant energy per unit area is much lower than that of a normal ρ tungsten lamp or an infrared lamp filament. For example, the radiation amount of the radiation surface near 100℃ is "-IW/cJ, 6
Since it is about 5 W/- at o □°C, the radiation surface must be wide for normal applications that require a total radiation of several hundred W or several kilowatts. On the other hand, in order to raise the temperature quickly, the heat capacity of the heating element must be small.
それ放水発明の発熱体1の発熱素子2には熱容量が小さ
い割に表面積が広くなるように金属箔を用いる。その厚
みは19以下で、通常Fio、l+++s以下を用いる
。Metal foil is used for the heating element 2 of the heating element 1 of the water spraying invention so that the surface area is large despite its small heat capacity. Its thickness is 19 or less, and usually Fio, l+++s or less is used.
錆びていない金属の表面は放射率が低いので、遠赤外線
の発熱体としては不適当であるので、この金属箔の表面
に薄い、放射率のよい放射体3を形成させる。この放射
体6は、600〜700℃位の温度の熱にも耐えなけれ
ばならないので、通常無機質の材料が選ばれる。遠赤外
線の放射率が良く、高熱に耐えられ、金属にもなじみの
よいものが材料にも選ばれるが、それにはガラス、ホー
ロー釉薬、陶磁器に使われる釉薬、5IO2等を多く含
んだ耐熱塗料等が適している。Since the surface of an unrusted metal has a low emissivity and is unsuitable as a far-infrared heating element, a thin radiator 3 with a high emissivity is formed on the surface of this metal foil. Since the radiator 6 must withstand heat at a temperature of about 600 to 700°C, an inorganic material is usually selected. Materials that have a good far-infrared emissivity, can withstand high heat, and are compatible with metals are selected, such as glass, enamel glazes, glazes used for ceramics, and heat-resistant paints containing a large amount of 5IO2, etc. is suitable.
放射体3の厚さはo、o1〜1鵠位の間に選ばれる。The thickness of the radiator 3 is selected between o, o1 and o1.
若し数秒間で数百度にしたい場合には放射体ろの厚さば
o、2m以下位にする。又放射体3は急熱、急冷を繰り
返すのでその意味でもあまり厚くするのは好ましくなく
、又発熱素子2に用いられる金属箔の温度による膨張率
とはy似通った膨張率のものを選ぶのが良いみ。If you want to make the temperature several hundred degrees in a few seconds, the thickness of the radiator filter should be about 2 m or less. Also, since the radiator 3 repeatedly heats up and cools rapidly, it is not preferable to make it too thick for that reason, and it is recommended to choose one with an expansion coefficient similar to that of the metal foil used for the heating element 2 due to temperature. Looks good.
放射体3は発熱素子2に例えば高温で焼き付けられたり
、接着剤で接着されたシして構成される。The radiator 3 is formed by, for example, being baked at a high temperature or bonded to the heating element 2 with an adhesive.
発熱素子2に用いられる金属箔には鉄、ニソケノへニク
ローム等が適している。Iron, Nichrome, etc. are suitable for the metal foil used for the heating element 2.
発熱体lは支持電極4で支持されて空気中につるされる
。この場合放射体6が発熱素子2の両面についていない
場合は放射体6のない方にはこれに近付けて且つこれに
触れないように金属反射体と熱絶縁物をおくとよい。早
い応答を得る為には如何なる場合でも、発熱素子2に放
射体以外の他の物体が、広い面積で直接触れるような使
用方法をしてはならない。The heating element 1 is supported by a support electrode 4 and suspended in the air. In this case, if the radiator 6 is not attached to both sides of the heating element 2, it is advisable to place a metal reflector and a thermal insulator on the side without the radiator 6 close to it but not touching it. In order to obtain a fast response, under no circumstances should any object other than the radiator directly touch the heating element 2 over a large area.
第2図は発熱素子の構造例を示す平面図である。FIG. 2 is a plan view showing an example of the structure of the heating element.
第2図で5は金属箔に設けた複数本の切り込みである。In FIG. 2, 5 is a plurality of notches provided in the metal foil.
発熱素子2は巾すで示される切り込みによって一枚の金
属箔から、巾aで示される長い帯状の電路を形成するよ
うに加工される。発熱させる為の電流は矢印めように流
れる。切り込み5は、金属箔として純ニッケル、純鉄等
を用いた場合、その抵抗率の関係から、工OOvで数百
Wの発熱素子を作る時に必要なものである。The heating element 2 is machined from a single piece of metal foil by making cuts shown by width a to form a long strip-shaped electrical path shown by width a. The current to generate heat flows in the direction of the arrow. The cut 5 is necessary when making a heat generating element of several hundred W at OOv due to the resistivity of pure nickel, pure iron, etc., as the metal foil.
若し切り込みなしで、ニッケル箔1所要の抵抗を得よう
とすると厚さが薄くなり過ぎて実用的でなくなるのであ
る。If one tried to obtain the required resistance with one nickel foil without notches, the thickness would become too thin to be practical.
切り込みの巾すは巾aに比べて充分狭いことが好ましい
。何故なら放射体乙の厚みは比較的薄く、放射面に直角
な方向の熱伝導は良好だが、面に平行な方向の熱伝導が
悪いので、切り込み部分の巾すが広いとその部分の放射
面は発熱素子から充分熱をもらうことが出来ず、切り込
み部分が放射面として動作しなくなり、放射面の単位面
積当りの放射効率が落ちるからである。It is preferable that the width of the cut is sufficiently narrower than the width a. This is because the thickness of the radiator B is relatively thin, and the heat conduction in the direction perpendicular to the radiation surface is good, but the heat conduction in the direction parallel to the surface is poor, so if the width of the cut part is wide, the radiation surface of that part This is because the cut portion cannot receive sufficient heat from the heating element, and the cut portion no longer functions as a radiation surface, resulting in a decrease in radiation efficiency per unit area of the radiation surface.
伺切り込み部分5は放射体3の支持にも役立っている。The cut-out portion 5 also serves to support the radiator 3.
第5図は第2図の発熱素子で構成した発熱体の縦断面図
である。FIG. 5 is a longitudinal cross-sectional view of a heating element constructed from the heating elements shown in FIG. 2.
この実施例においては、第5図に示したように放射体ろ
は切り込み50部分を通って発熱素子2の背後にまでま
わり込んでおり、放射体6と発熱素子2との一体化に役
立っている。前述のように放射体6は薄くしかも急熱、
急冷を繰り返すので、ひびが入り易ぐ、発熱素子2がら
剥11&するおそれがあるので、このように切り込み5
全通して発熱素子2をかかえているような構造にするこ
とにより、放射体乙の剥離を防止できる。In this embodiment, as shown in FIG. 5, the radiator loop extends behind the heating element 2 through the notch 50, which helps in integrating the radiator 6 and the heating element 2. There is. As mentioned above, the radiator 6 is thin and heats up rapidly.
Repeated rapid cooling can easily cause cracks and peel off of the heating element 2, so the cut 5 is
By creating a structure in which the heating element 2 is held all the way through, it is possible to prevent the radiator B from peeling off.
発熱素子2の両面から放射する時、即ち第1図で発熱素
子2の上下に放射面を形成する時も、切り込み5は同じ
ように放射体3と発熱素子2との結合を強固にするのに
役立っている。When emitting radiation from both sides of the heating element 2, that is, when forming radiation surfaces on the top and bottom of the heating element 2 in FIG. It is useful for
発熱素イ〜使用される材料の抵抗率や使用電力の関係等
から、切り込み5の密度が小さい場合或は全熱ない場合
は発熱素子の各所に小さい穴を明けて、第3図の切り込
み5と同じ作用をさせると放射体5が強固になる。Heat generating element A ~ If the density of the notches 5 is small or there is no total heat due to the resistivity of the material used and the power used, make small holes in various parts of the heat generating element and make the notches 5 in Figure 3. By applying the same action, the radiator 5 becomes stronger.
第4図はこのような目的で穴を明けた発熱素子2を示す
。第4図で(a)は切り込みのない場合、(′b)は切
り込みの少ない場合で6は穴である。穴の形状は、第4
図に図示したように電流の流れる方向に平行に細長く作
るのが望ましい。丸穴でも差し支えはないが、穴を明け
た部分の金属箔の巾が穴の為に狭くなりその部分の抵抗
が他の部分に比べて、極端に上るような大きさの穴は適
当でない1、との童味で同じ面積なら電流の方向と平行
に細長いのがよいのである。FIG. 4 shows a heating element 2 with holes drilled for this purpose. In FIG. 4, (a) is a case with no notches, ('b) is a case with few notches, and 6 is a hole. The shape of the hole is the 4th
It is desirable to make it elongated parallel to the direction of current flow as shown in the figure. There is no problem with a round hole, but a hole of such a size that the width of the metal foil becomes narrower due to the hole and the resistance of that part becomes extremely higher than other parts is not appropriate1. , if the area is the same, it is better to make it long and thin parallel to the direction of the current.
以上述べたように金属箔で作った発熱素子に泄い放射率
の良好な無機質材料を焼き付けて空気中に他の物体に触
れずに支持出来る放射面を形成した本発明の発熱体によ
って、次のような多くの優れた効果を得ることが出来る
1、
又発熱素子の金属箔に巾の細い切り込み或は穴を設ける
ことにより放射面の強度が増し更に効り゛が上る。As described above, the heating element of the present invention, in which an inorganic material with good emissivity is baked onto the heating element made of metal foil to form a radiation surface that can be supported in the air without touching other objects, can achieve the following effects: Many excellent effects can be obtained such as 1. Also, by providing narrow cuts or holes in the metal foil of the heating element, the strength of the radiation surface is increased and the effectiveness is further increased.
(1)非常に早い応答をもつ発熱体を得ることが出来る
。(1) A heating element with very fast response can be obtained.
(2)単位占有面積当り強力な加熱作用のある遠赤外線
用の発熱体を得ることが出来る。(2) A far-infrared heating element having a strong heating effect per unit occupied area can be obtained.
(3)軽量で持ち運びの楽なヒータ等を容易に作ること
が出来る。(3) It is possible to easily make a heater, etc. that is lightweight and easy to carry.
(4)必要な時に必要な時間だけ加熱する省エネルギ型
のヒータを得ることが出来る。予熱する必要がなく、ス
イッチを切った後も加熱が続くということもない。(4) It is possible to obtain an energy-saving heater that heats only when necessary and for a necessary time. There is no need to preheat, and heating does not continue even after the switch is turned off.
(5)火災や火傷の心配の少ない遠赤外線ヒータを得る
ことが出来る。(5) A far-infrared heater with less risk of fire or burns can be obtained.
(6)急熱、急冷に耐える耐久性のよい発熱体を得るこ
とが出来る。(6) A durable heating element that can withstand rapid heating and cooling can be obtained.
本発明による時は多くの効果を持つ省エネルギに役立つ
使い易い便利な発熱体を得ることが出来、T集用、家庭
用のヒータ等に多くの用途を持ち、その経済的効果は甚
だ大である。According to the present invention, it is possible to obtain a convenient and easy-to-use heating element that is useful for energy saving and has many effects, and has many uses in T-collection, household heaters, etc., and its economical effects are enormous. be.
【図面の簡単な説明】
第1図は本発明の実施例を示す構造簡略図、第2図は発
熱素子の実施例を示す平面図、第6図は第21YIの発
熱素子を用いた本発明の他の実施例を示す縦断面図、第
4図(a)は穴を明けた発熱素子の、(b)は穴と切り
込みを設けた発熱素子の実施例を示す平面図である。
1・・発熱体、2・発熱素子、6・・・放射体、5・・
・切り込み、6・・・穴。
特許出願人 国際技術開発株式会社
「
第 2 図[BRIEF DESCRIPTION OF THE DRAWINGS] Fig. 1 is a simplified structural diagram showing an embodiment of the present invention, Fig. 2 is a plan view showing an embodiment of a heating element, and Fig. 6 is the invention using the 21st YI heating element. FIG. 4(a) is a longitudinal sectional view showing another embodiment of the present invention; FIG. 4(b) is a plan view showing an embodiment of the heating element having holes and notches. 1. Heating element, 2. Heating element, 6. Radiating body, 5.
・Notch, 6...hole. Patent applicant Kokusai Technological Development Co., Ltd. “Figure 2
Claims (3)
た発熱素子と、該発熱素子に密着し、遠赤外線の放射率
が良くかつ耐熱性の材料で形成された放射体とから成る
ことを特徴とする発熱体。(1) It is characterized by consisting of a heating element made of metal foil that generates heat by electric energy, and a radiator made of a heat-resistant material that is in close contact with the heating element and has a high far-infrared emissivity. heating element.
された特許請求の範囲第1項記載の発熱体。(2) The heating element according to claim 1, wherein the heating element is constructed by making a narrow cut in a metal foil.
れた特許請求の範囲第1項記載の発熱体。(3) The heating element according to claim 1, wherein the heating element is constructed by making a plurality of holes in a metal foil.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP15879581A JPS5887792A (en) | 1981-10-07 | 1981-10-07 | Heater |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP15879581A JPS5887792A (en) | 1981-10-07 | 1981-10-07 | Heater |
Publications (1)
Publication Number | Publication Date |
---|---|
JPS5887792A true JPS5887792A (en) | 1983-05-25 |
Family
ID=15679504
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP15879581A Pending JPS5887792A (en) | 1981-10-07 | 1981-10-07 | Heater |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPS5887792A (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS61248383A (en) * | 1985-04-25 | 1986-11-05 | 吉村 昇 | Far infrared heater |
JPS62119886A (en) * | 1985-11-19 | 1987-06-01 | テンパ−ル工業株式会社 | Far-infrared heater |
JPH0357891U (en) * | 1989-10-11 | 1991-06-04 |
-
1981
- 1981-10-07 JP JP15879581A patent/JPS5887792A/en active Pending
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS61248383A (en) * | 1985-04-25 | 1986-11-05 | 吉村 昇 | Far infrared heater |
JPS62119886A (en) * | 1985-11-19 | 1987-06-01 | テンパ−ル工業株式会社 | Far-infrared heater |
JPH0357891U (en) * | 1989-10-11 | 1991-06-04 |
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