JP2003031341A - Plate heater - Google Patents

Plate heater

Info

Publication number
JP2003031341A
JP2003031341A JP2001213014A JP2001213014A JP2003031341A JP 2003031341 A JP2003031341 A JP 2003031341A JP 2001213014 A JP2001213014 A JP 2001213014A JP 2001213014 A JP2001213014 A JP 2001213014A JP 2003031341 A JP2003031341 A JP 2003031341A
Authority
JP
Japan
Prior art keywords
plate
heat transfer
heater
heat
transfer plate
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
Application number
JP2001213014A
Other languages
Japanese (ja)
Inventor
Tetsuya Oka
哲也 岡
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Espec Corp
Original Assignee
Espec Corp
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Espec Corp filed Critical Espec Corp
Priority to JP2001213014A priority Critical patent/JP2003031341A/en
Publication of JP2003031341A publication Critical patent/JP2003031341A/en
Pending legal-status Critical Current

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  • Surface Heating Bodies (AREA)
  • Control Of Resistance Heating (AREA)

Abstract

PROBLEM TO BE SOLVED: To provide a plate heater capable of controlling precise temperature distribution including uniform heating while avoiding size increase of heating elements or considerable increase in cost. SOLUTION: The plate heater consists of a plurality of plate-shaped heating elements 3 interposed between a pair of heat conducting plates 1 and 2. Heating control of each heating element 3 can be performed separately. The subdivide means A for reducing the thickness of one conducting plate 1 is arranged between the corresponding area to the element 3 and the other area in at least one of the pair of heat conducting plates 1 and 2. The subdivide means A consists of cutting lines s along which each plate meets each other.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【発明の属する技術分野】本発明は、各種製造工程にお
ける熱処理工程に利用されるIRヒータ等のプレートヒ
ータに係り、詳しくは、温度制御の自由度を向上させる
技術に関するものである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plate heater such as an IR heater used in a heat treatment process in various manufacturing processes, and more particularly to a technique for improving the degree of freedom in temperature control.

【0002】[0002]

【従来の技術】従来のプレートヒータは、特開平11−
54248号公報にて示されたように、一対のアルミ等
の金属板体の間に発熱体を挟み込む構造であった。即
ち、一対の銅プレート間に、両側に絶縁材であるマイカ
プレート板を配した薄型ヒータを介装して両面型のプレ
ートヒータを構成していた。
2. Description of the Related Art A conventional plate heater is disclosed in Japanese Patent Laid-Open No. 11-
As disclosed in Japanese Patent No. 54248, the heating element is sandwiched between a pair of metal plate bodies such as aluminum. That is, a double-sided plate heater is configured by interposing a thin heater having a mica plate plate as an insulating material on both sides between a pair of copper plates.

【0003】例えば、発熱体として遠赤外線を用いたプ
レートヒーターにより、ガラス基板等の面状の試料を加
熱する場合、遠赤外線の照射される量が中央部分に比べ
て外郭部分の方が少なくなることに起因して、試料の外
側の温度が低くなってしまう傾向にある。
For example, when a planar sample such as a glass substrate is heated by a plate heater using far infrared rays as a heating element, the amount of far infrared rays irradiated is smaller in the outer portion than in the central portion. Due to this, the temperature outside the sample tends to be low.

【0004】そこで、それを改善するために、従来では
次の〜の手段を採っていた。 ヒータの温度分布を非常に精度良くして、試料とヒ
ータとの距離を縮めて加熱する手段。 試料に対してヒータのサイズを十分に大きくする手
段。 単に小さなプレートヒータを並べて加熱する手段。
Therefore, in order to improve it, the following measures (1) to (3) have been conventionally adopted. A means for heating the heater by making the temperature distribution of the heater extremely accurate and shortening the distance between the sample and the heater. A means to make the size of the heater large enough for the sample. Means of simply arranging and heating small plate heaters.

【0005】[0005]

【発明が解決しようとする課題】前記の手段では、ヒ
ータの温度分布を非常に精度良くすることと、ヒータの
大型化とは相反するものであり、コストも高くなるとい
う難点がある。前記の手段では、ヒータ及び装置全体
が非常に大きなものになってしまうとともに、消費電力
も大きくなってランニングコストが増大する。これは、
例えば、クリーンルーム等で使用の際は、設置スペース
の問題や重量の問題が生じる。前記の手段では、ヒー
タの取り扱いが煩雑になるとか、枠等の影響で照射が不
均一となり易い点で難しい。つまり、前記〜のいず
れの手段でも一長一短があり、更なる改善の余地が残さ
れているものであった。
In the above means, there is a contradictory relationship between making the temperature distribution of the heater extremely accurate and increasing the size of the heater, and increasing the cost. With the above-mentioned means, the heater and the entire device become very large, and the power consumption also increases and the running cost increases. this is,
For example, when used in a clean room or the like, there are problems of installation space and weight. The above-mentioned means is difficult in that the heater is complicated to handle and the irradiation is likely to be non-uniform due to the influence of the frame or the like. That is, each of the above-mentioned means has merits and demerits, and there is room for further improvement.

【0006】本発明の目的は、発熱体の大型化や大幅な
コストアップを回避しながら、均一に加熱できる等、精
度良く温度分布を制御できるプレートヒータを提供する
点にある。
An object of the present invention is to provide a plate heater which can control the temperature distribution with high accuracy such as uniform heating while avoiding an increase in size of the heating element and a large increase in cost.

【0007】[0007]

【課題を解決するための手段】請求項1の構成は、一対
の伝熱用板材の間にプレート状の発熱体を介装して成る
プレートヒータにおいて、発熱体を複数設け、かつ、そ
れら複数の発熱体に対して各別に発熱制御自在に構成す
るとともに、一対の伝熱用板材のうちの少なくとも一方
の伝熱用板材における発熱体に対応した領域とそれ以外
の領域との間に、これら両領域を区切るべく一方の伝熱
用板材の厚みを減少させる小割手段を設けてあることを
特徴とする。
According to a first aspect of the present invention, there is provided a plate heater having a plate-shaped heating element interposed between a pair of heat transfer plate members, and a plurality of heating elements are provided. The heat generating element of each of the heat generating elements is configured to be freely controllable, and at least one of the pair of heat transmitting plate materials is provided between the area corresponding to the heat generating element and the other area. It is characterized in that a dividing means for reducing the thickness of one heat transfer plate is provided so as to divide the two regions.

【0008】請求項1の構成によれば、各別に発熱制御
自在な複数の発熱体を設けたので、各発熱体の温度を必
要に応じて個別に制御することができるようになる。例
えば、プレートヒータとしての中央部に位置する発熱体
よりも、外周部分に位置する発熱体の発熱量が大きくな
るように制御するとか、右半分と左半分の温度を異なら
せるといったことがことが自在に行えるようになる。
According to the structure of the first aspect, since a plurality of heating elements whose heat generation can be controlled individually are provided, the temperature of each heating element can be individually controlled as needed. For example, it is possible to control so that the heat generation amount of the heating element located in the outer peripheral portion is larger than that of the heating element located in the central portion as the plate heater, or to make the temperature of the right half and the left half different. You will be able to do it freely.

【0009】請求項2の構成は、請求項1の構成におい
て、小割手段が互いに接する切断線であることを特徴と
するものである。
According to a second aspect of the present invention, in the first aspect of the invention, the dividing means are cutting lines which are in contact with each other.

【0010】請求項2の構成においては、小割手段が互
いに接する切断線であるもの、即ち互いに独立している
伝熱板どうしを互いに接当する状態で配置するものであ
り、伝熱用板材としての連続性が切断線にて一旦途切れ
て、部分的な接触状態となっているから、その切断線で
は熱伝導作用が極めて緩慢になり、各発熱体における発
熱制御が、他の発熱体の領域等の他の領域に及び難くな
る。そして、隣り合う伝熱板どうしは切断線において互
いに接しているから、伝熱用板材として見た場合には、
切断線が外観上で見えるものの、1枚のプレートとして
の形態は維持されており、本来の加熱作用には悪影響が
生じない。又、もう一方の伝熱用板材により、プレート
ヒータとして必要な強度を確保することができる。
According to the second aspect of the present invention, the splitting means are cutting lines which are in contact with each other, that is, the heat transfer plates which are independent of each other are arranged in contact with each other. Since the continuity as a line is interrupted at the cutting line and it is in a partial contact state, the heat conduction action becomes extremely slow at that cutting line, and the heat generation control in each heating element is performed by other heating elements. It becomes difficult to reach other areas such as areas. And since adjacent heat transfer plates are in contact with each other at the cutting line, when viewed as a heat transfer plate,
Although the cutting line is visible on the appearance, the shape as a single plate is maintained and the original heating action is not adversely affected. Also, the strength required for the plate heater can be secured by the other heat transfer plate material.

【0011】請求項3の構成は、請求項1の構成におい
て、小割手段が切断に至らない溝であることを特徴とす
るものである。
According to a third aspect of the present invention, in the first aspect, the dividing means is a groove that does not cut.

【0012】請求項3の構成においては、小割手段が切
断に至らない溝であるから、その溝部分では伝熱用板材
の厚み、即ち、断面積が急減することになって熱伝導作
用が緩慢になり、それによって発熱体の発熱による熱
が、伝熱用板材におけるその発熱体に対応する部分以外
の領域には伝わり難くなる。小割手段が溝であるから、
この溝が形成されている側の伝熱用板材も1枚の連続し
た板材であって、切断線が形成されている場合に比べて
強度上で有利になる。溝が外表面側に表れる場合には、
その溝によって伝熱用板材が区切られている様が外観上
で見えるが、内側表面側に表れる場合には、外表面は溝
のない1枚板と同じ外観を呈するものとなり、両面共に
熱の照射面として使い易い状態が得られる。
According to the third aspect of the present invention, since the slitting means is a groove that does not lead to cutting, the thickness of the heat transfer plate material, that is, the cross-sectional area is sharply reduced at the groove portion, and the heat conduction effect is achieved. The heat becomes slow, and it becomes difficult for the heat generated by the heating element to be transferred to a region of the heat transfer plate other than the portion corresponding to the heating element. Since the slitting means is a groove,
The plate for heat transfer on the side where the groove is formed is also one continuous plate, which is advantageous in terms of strength as compared with the case where the cutting line is formed. If the groove appears on the outer surface side,
It can be seen from the outside that the heat transfer plate is separated by the groove, but when it appears on the inner surface side, the outer surface has the same appearance as a single plate without grooves, and both sides have heat A state that is easy to use as an irradiation surface can be obtained.

【0013】請求項4の構成は、請求項2に記載の切断
線、又は請求項3に記載の溝が、前記両領域の間におけ
る全域に形成されていることを特徴とするものである。
According to a fourth aspect of the present invention, the cutting line according to the second aspect or the groove according to the third aspect is formed in the entire area between the both areas.

【0014】請求項4の構成によれば、切断線又は溝で
囲まれた部分は、単一の発熱体に対応したものになり、
単一の発熱体によって発熱制御される伝熱用板材部分
が、その他の領域からより明確に区切られるようになる
ので、部分的に区切られたものに比べて、伝熱用板材の
部分的な温度制御を、その他の部分への熱影響をより少
なくした状態で、よりきめ細かく行えるようになる。
According to the structure of claim 4, the portion surrounded by the cutting line or the groove corresponds to a single heating element,
Since the heat transfer plate material part whose heat generation is controlled by a single heating element is more clearly separated from other areas, the heat transfer plate material partly This makes it possible to perform temperature control more finely in a state where the heat influence on other parts is reduced.

【0015】請求項5の構成は、請求項1〜4の構成に
おいて、伝熱用板材がアルミ合金製であることを特徴と
するものである。
According to a fifth aspect of the present invention, in the first to fourth aspects, the heat transfer plate is made of an aluminum alloy.

【0016】請求項5の構成によれば、熱伝導性能に優
れながら、機械的強度も比較的優れているアルミ合金に
よって伝熱用板材を構成してあるから、切断線や切断に
至らない溝、或いは長孔等による小割手段を形成して
も、本来の熱伝導作用、及び、小割手段による熱伝動の
規制作用の双方を、高い次元において満たすことが可能
となる。
According to the fifth aspect of the invention, since the heat transfer plate is made of an aluminum alloy having excellent heat conduction performance and relatively high mechanical strength, a cutting line or a groove that does not lead to cutting is formed. Alternatively, even if the slitting means is formed by a long hole or the like, it is possible to satisfy both of the original heat conduction effect and the heat transmission regulation effect by the slitting means in a high dimension.

【0017】[0017]

【発明の実施の形態】以下、本発明の実施の形態を図面
に基づいて説明する。図1、図2に示すように、プレー
トヒータPは、一対の均熱板(伝熱用板材の一例)1,
2の間にプレート状のスペースヒータ(発熱体の一例)
3を介装して成るサンドイッチ構造のIR(遠赤外線)
ヒータに構成されている。表側均熱板1及び裏側均熱板
2は、共にアルミ合金製であり、スペースヒータ3は、
ヒータ線等による発熱部4の上下に絶縁層5,5を備え
た構成となっている。
BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. As shown in FIGS. 1 and 2, the plate heater P includes a pair of heat equalizing plates (an example of a heat transfer plate material) 1.
A plate-shaped space heater between the two (an example of a heating element)
IR (Far Infrared) of sandwich structure consisting of 3
It is composed of a heater. Both the front-side soaking plate 1 and the back-side soaking plate 2 are made of aluminum alloy, and the space heater 3 is
Insulating layers 5 and 5 are provided above and below the heat generating portion 4 formed by a heater wire or the like.

【0018】図2に示すように、この例ではスペースヒ
ータ3を6個設けてあり、それら6個のスペースヒータ
3に対して各別に発熱制御自在に構成するとともに、一
対の均熱板1,2のうちの表側均熱板1におけるスペー
スヒータ3に対応した領域とそれ以外の領域との間に、
これら両領域を区切るべく表側均熱板1の厚みを減少さ
せる小割手段Aを設けてある。
As shown in FIG. 2, in this example, six space heaters 3 are provided, and the heat generation of each of the six space heaters 3 can be controlled independently. Between the area corresponding to the space heater 3 in the front side heat equalizing plate 1 of 2 and the other area,
A dividing means A for reducing the thickness of the front side heat equalizing plate 1 is provided so as to divide these two regions.

【0019】即ち、表側均熱板1は、長方形(矩形)の
単位伝熱板1aの6個を、互いに接するように隙間無く
前後左右に2個及び3個ずつ並べて構成されており、各
単位伝熱板1a毎にスペースヒータ3を対応して設けて
ある。つまり、隣合う単位伝熱板1a,1aを接触させ
ることによる縦横の切断線sによって小割手段Aが構成
されている。これら6個ずつのスペースヒータ3及び単
位伝熱板1aは、1枚板の裏側均熱板2によって強度的
に支持されており、それによって一体化されてレートヒ
ータPとしての形態が構成されている。
That is, the front side heat equalizing plate 1 is composed of six rectangular unit heat transfer plates 1a arranged side by side in front and rear, right and left without contact so as to be in contact with each other. A space heater 3 is provided corresponding to each heat transfer plate 1a. That is, the dividing means A is constituted by the vertical and horizontal cutting lines s formed by bringing adjacent unit heat transfer plates 1a, 1a into contact with each other. The six space heaters 3 and the unit heat transfer plates 1a are strongly supported by the one back side heat equalizing plate 2, and are integrated with each other to form the form as the rate heater P. There is.

【0020】スペースヒータ3は単位伝熱板1aよりも
外郭形状がやや小さ目に形成されて、隣合うスペースヒ
ータ3,3どうしの間に間隙を設けて互いに接触しない
ようにしてあるとともに、陽極及び陰極の一対の端子
6,6が単位伝熱板1aの外側に存在する状態に設定さ
れている。又、各端子6,6には、リード線である陽極
線7と陰極線8とを介して制御装置9に接続されてお
り、各スペースヒータ3毎に対応させた調節器10も制
御装置9に接続されている。
The space heater 3 is formed so that its outer shape is slightly smaller than the unit heat transfer plate 1a, and a space is provided between the space heaters 3 and 3 which are adjacent to each other so as not to contact each other. The pair of terminals 6, 6 of the cathode is set to exist outside the unit heat transfer plate 1a. Further, the terminals 6 and 6 are connected to a control device 9 through an anode wire 7 and a cathode wire 8 which are lead wires, and a controller 10 corresponding to each space heater 3 is also connected to the control device 9. It is connected.

【0021】つまり、各スペースヒータ3はそれ専用の
調節器(温度調節器)10によって発熱制御自在であ
り、温度設定が自在に行えるように構成されている。こ
れにより、例えば、全ての調節器10を同じ操作量に設
定して、どの単位伝熱板1aも同じ温度に設定すると
か、中央側2個の単位伝熱板1a,1aのみ温度を変え
るといったことが自在である。図2に示すように、切断
線sが隣合う単位伝熱板1a,1aの間における全域に
形成すれば、より効率良く、かつ、他への熱影響少なく
発熱制御を行うことができる。
In other words, each space heater 3 can be controlled in heat generation by a controller (temperature controller) 10 dedicated to the space heater 3, and the temperature can be freely set. Thereby, for example, all the regulators 10 are set to the same operation amount and all the unit heat transfer plates 1a are set to the same temperature, or only the two center unit heat transfer plates 1a and 1a are changed in temperature. You are free to do anything. As shown in FIG. 2, if the cutting line s is formed in the entire area between the adjacent unit heat transfer plates 1a, 1a, heat generation control can be performed more efficiently and with less thermal influence on others.

【0022】但し、裏側均熱板2を上側に向けて、この
1枚板の裏側均熱板2によって加熱対象(液晶用ガラス
基板、半導体ウェハ等の面状の試料)を加熱するように
使うことも自在である。この場合でも、各スペースヒー
タ3を個別に発熱制御することで、裏側均熱板2を部分
的に温度に差を付けることが可能ではあるが、切断線s
によって熱伝導が一端断ち切られている表側均熱板1の
方が、加熱時に単位伝熱板1a毎に温度差を待たせるこ
とがより顕著に行えるものとなっている。
However, the back side heat equalizing plate 2 is turned to the upper side, and this back side heat equalizing plate 2 is used to heat an object to be heated (a glass substrate for liquid crystal, a planar sample such as a semiconductor wafer). It is also possible. Even in this case, by controlling the heat generation of each space heater 3 individually, it is possible to partially make the temperature difference of the back side heat equalizing plate 2, but the cutting line s
The front-side heat equalizing plate 1 whose heat conduction has been cut off is more remarkably able to hold a temperature difference for each unit heat transfer plate 1a during heating.

【0023】以下、参考に記載する。発熱体3としての
小さなスペースヒータ3には個別の制御が行えるように
配線を独立させてあり、調節器10の操作により、高い
温度にしたい箇所のスペースヒータ3には出力を大きく
し、温度を高くしたくない箇所のスペースヒータ3には
出力を小さくする。但し、従来の構造では、スペースヒ
ータ3を挟んでいる一対の伝熱板の熱伝導によって熱が
移動してしまい、プレートヒータ3表面に温度勾配を付
けられない。そこで、スペースヒータ3を挟んでいる一
対の伝熱板1,2を照射面のみ分割して熱伝導による熱
の移動を抑え、プレートヒータ3表面に温度勾配を付け
るようにしてある。このとき、切断されて互いに独立し
ている板どうし(単位伝熱板1a,1aどうし)が切断
線sにおいて接触していても、1枚板状態の場合と比べ
て格段に熱伝導は悪くなり、発熱制御の独立性が向上す
るようになる。
The following is described for reference. The small space heater 3 as the heating element 3 has independent wiring so that individual control can be performed, and by operating the controller 10, the space heater 3 at a position where a high temperature is desired to have a large output and a high temperature. The output is made small for the space heater 3 at a portion which is not desired to be raised. However, in the conventional structure, heat is transferred by the heat conduction of the pair of heat transfer plates sandwiching the space heater 3, and the temperature gradient cannot be applied to the surface of the plate heater 3. Therefore, the pair of heat transfer plates 1 and 2 sandwiching the space heater 3 is divided only on the irradiation surface to suppress the movement of heat due to heat conduction, and a temperature gradient is given to the surface of the plate heater 3. At this time, even if the cut and independent plates (unit heat transfer plates 1a, 1a) are in contact with each other at the cutting line s, the heat conduction is significantly worse than that in the single plate state. The independence of heat generation control is improved.

【0024】温度勾配をつけることで、スペースヒータ
3から加熱対象に照射される遠赤外線の量が等しくな
り、加熱対象を均一に加熱することが可能になる。プレ
ートヒータ3と加熱対象とはある程度距離を持っている
ので、プレートヒータ3の温度分布よりも加熱対象の温
度分布をより均一化することができる。つまり、プレー
トヒータ3の温度分布をそれ程精度良くする必要がない
ので、コストを安くして製作することができる。これに
より、加熱対象の大型化に対しても大幅なコストアップ
無く対応させてプレートヒータPの大型化が行える。
By providing a temperature gradient, the amount of far infrared rays irradiated from the space heater 3 to the heating target becomes equal, and the heating target can be heated uniformly. Since the plate heater 3 and the heating target have a certain distance, the temperature distribution of the heating target can be made more uniform than the temperature distribution of the plate heater 3. That is, since it is not necessary to make the temperature distribution of the plate heater 3 so accurate, the cost can be reduced and the plate heater 3 can be manufactured. As a result, it is possible to increase the size of the plate heater P in response to an increase in the size of the heating target without significantly increasing the cost.

【0025】プレートヒータPの外観としてはサンドイ
ッチ構造の1枚のヒータであり、取り扱いが楽である。
何らかの装置へ取り付ける際も、端部を支えるだけで固
定でき、枠等を必要としない。故に、枠等の影響でスペ
ースヒータ3による加熱対象への遠赤外線照射が不均一
になることも無い。
The appearance of the plate heater P is a single heater having a sandwich structure, and it is easy to handle.
Even when it is attached to any device, it can be fixed simply by supporting the end and does not require a frame or the like. Therefore, the far infrared irradiation of the heating target by the space heater 3 does not become uneven due to the influence of the frame or the like.

【0026】スペースヒータ(発熱体)3を挟み込む均
熱用板材1,2については、アルミ(アルミ合金)等の
熱伝導の良い材質のものを用いると、ヒータ線等による
発熱体3の温度分布が悪い場合でも、熱伝導によってプ
レートヒータ3表面の温度分布を均一化できる。つま
り、一つ一つの発熱領域(単位伝熱板1a、又は図3に
示す単位伝熱範囲1b)における温度分布を良くするこ
とができる。このとき均熱用板材1,2の厚みは厚い方
がよりその効果が大きくなる。一つ一つの発熱領域1
a,1b内の温度分布をさらに均一化することができ
る。
If the heat equalizing plate members 1 and 2 for sandwiching the space heater (heat generating member) 3 are made of a material having good heat conduction such as aluminum (aluminum alloy), the temperature distribution of the heat generating member 3 due to the heater wire or the like is used. Even if the temperature is bad, the temperature distribution on the surface of the plate heater 3 can be made uniform by heat conduction. That is, it is possible to improve the temperature distribution in each heat generation region (the unit heat transfer plate 1a or the unit heat transfer range 1b shown in FIG. 3). At this time, the thicker the soaking plate materials 1 and 2, the greater the effect. Each heating area 1
The temperature distribution in a and 1b can be made more uniform.

【0027】例えば、容量の違うスペースヒータ3,3
を予め並べておいて同じ出力を与えても上記と同様の効
果が期待できる。この場合は配線を独立させる必要がな
いので、スペースヒータ3の端子6の数を大幅に削減で
きる。それにより、端子6部分を発熱領域1a又は1b
から外に取り出すといったことが可能であり、端子6構
造を簡略化できる。これによってヒータ端6子部分の耐
熱温度、クリーン度等の問題を解決することが可能にな
る。以上により、プレートヒータPを用いて加熱対象
(液晶用ガラス基板、半導体ウェハ等の面状の試料)に
対して均一な加熱が可能となり、そのコストも抑えるこ
とができる。
For example, space heaters 3 and 3 having different capacities
Even if they are arranged in advance and the same output is given, the same effect as above can be expected. In this case, since it is not necessary to make the wiring independent, the number of terminals 6 of the space heater 3 can be significantly reduced. As a result, the terminal 6 portion is set to the heating area 1a or 1b.
It is possible to take it out from the outside, and the structure of the terminal 6 can be simplified. This makes it possible to solve problems such as the heat resistant temperature of the heater end 6 and the cleanliness. As described above, the plate heater P can be used to uniformly heat an object to be heated (a glass substrate for liquid crystal, a planar sample such as a semiconductor wafer), and the cost thereof can be suppressed.

【0028】〔別実施形態〕 《1》 図3に示すように、表側均熱板1を、その内側
(スペースヒータ3側)に、上表面にまで至らない、即
ち切断に至らない溝mを形成することにより、スペース
ヒータ3に対応した領域(単位伝熱範囲)1bとそれ以
外の領域(単位伝熱範囲)1bとの間に、これら両領域
1b,1bを区切る小割手段Aとしても良い。溝mは、
断面形状が三角形やU字状のものでも良く、これら溝m
や前述の切断線sが、表側均熱板1の厚みを減少させる
小割手段Aとして機能する。
[Other Embodiments] << 1 >> As shown in FIG. 3, the front-side heat equalizing plate 1 is provided with a groove m on its inner side (space heater 3 side) that does not reach the upper surface, that is, does not lead to cutting. By forming the space heater 3, the area 1b (unit heat transfer range) corresponding to the space heater 3 and the area 1b (unit heat transfer range) other than the area 1b can be divided into the area 1b and 1b. good. The groove m is
The cross section may be triangular or U-shaped, and these grooves m
The above-mentioned cutting line s functions as a dividing means A for reducing the thickness of the front side heat equalizing plate 1.

【0029】《2》 発熱体3としては、IRヒータ、
ニクロム線等種々の変更が可能である。又、表側伝熱用
板材1を、厚さの薄い1枚板で成る上面板と、各発熱体
3毎に独立した厚さの厚い複数の単位伝熱板1aで成る
下面板とを貼り合わせたものとして、結果的に切断に至
らない溝sによる小割手段Aを備えたプレートヒータP
としても良い。
<< 2 >> As the heating element 3, an IR heater,
Various modifications such as nichrome wire are possible. Further, the front side heat transfer plate material 1 is laminated with an upper surface plate made of a thin plate and a lower surface plate made of a plurality of independent unit heat transfer plates 1a having a large thickness for each heating element 3. As a matter of fact, the plate heater P provided with the dividing means A by the groove s which does not result in cutting
Also good.

【0030】《3》図1において、伝熱用板材1にだけ
切断線sを設けるものに限らず、伝熱用板材2にも切断
線sを設けることもできる。このとき、全体がバラバラ
にならないように、伝熱用板材1,2の一方又は両方の
切断線sを耐熱性のセメント等で埋めておくものとす
る。また、図2において、伝熱用板材1にだけ溝mを設
けるものに限らず、伝熱用板材2にも溝mを設けること
もできる。この場合、伝熱用板材1,2の溝mは互いに
内向きであることが好ましいが、伝熱用板材2の溝mは
外向きに開口するものであってもよい。また、一方の伝
熱用板材に切断線sを設け、他方の伝熱用板材に溝mを
設けるものであってもよい。このように、伝熱用板材
1,2の両方に切断線m又は/及び切断線sを設ける
と、加熱用に用いられる一方の伝熱用板材の表面の温度
が他方の伝熱用板材を介しての熱伝達の影響を受けにく
く、全体として温度制御を更に精密なものにすることが
できる。
<< 3 >> In FIG. 1, the cutting line s is not limited to being provided only on the heat transfer plate member 1, and the cutting line s may be provided on the heat transfer plate member 2. At this time, the cutting line s of one or both of the heat transfer plate members 1 and 2 is filled with heat-resistant cement or the like so that the whole is not disassembled. Further, in FIG. 2, the groove m is not limited to being provided only in the heat transfer plate material 1, and the groove m can be provided in the heat transfer plate material 2 as well. In this case, the grooves m of the heat transfer plate materials 1 and 2 are preferably inward with respect to each other, but the grooves m of the heat transfer plate material 2 may be open outward. Further, the cutting line s may be provided on one heat transfer plate and the groove m may be provided on the other heat transfer plate. In this way, when the cutting line m and / or the cutting line s is provided on both of the heat transfer plate members 1 and 2, the temperature of the surface of one heat transfer plate member used for heating is different from that of the other heat transfer plate member. It is less susceptible to heat transfer through and allows for more precise temperature control as a whole.

【0031】[0031]

【発明の効果】以上説明したように、本発明によるプレ
ートヒータでは、各別に発熱制御自在な複数の発熱体を
設け、一対の伝熱用板材のうちの一方の伝熱用板材にお
ける発熱体に対応した領域とそれ以外の領域との間に、
これら両領域を区切るべく一方の伝熱用板材の厚みを減
少させる小割手段を設けたので、プレートヒータとして
の中央部に位置する発熱体よりも、外周部分に位置する
発熱体の発熱量が大きくなるように制御するといった具
合に、各発熱体の温度を必要に応じて個別に制御するこ
とができるようになり、発熱体の大型化や大幅なコスト
アップを回避しながら、均一に加熱できる等、精度良く
温度分布を制御できるものとして提供することができ
た。
As described above, in the plate heater according to the present invention, a plurality of heat generating elements whose heat generation can be controlled are provided for each of the pair of heat transmitting plate materials and the heat generating element in one of the heat transfer plate materials is used. Between the corresponding area and the other area,
Since the subdivision means for reducing the thickness of one of the heat transfer plate members is provided so as to divide these two regions, the heat generation amount of the heat generating element located in the outer peripheral portion is smaller than that of the heat generating element located in the central portion as the plate heater. It becomes possible to control the temperature of each heating element individually, such as by controlling it so that it becomes larger, and it is possible to uniformly heat it while avoiding enlargement of the heating element and significant cost increase. As a result, the temperature distribution can be accurately controlled.

【0032】互いに接する切断線による小割手段を備え
ると、他の領域への熱影響を少なくしながら効率良く発
熱制御が行えるようになり、切断に至らない溝による小
割手段を備える場合では、見た目に変更点が無いように
しながら、前記効果を奏することができる。又、切断線
や切断に至らない溝を、一方の伝熱用板材における発熱
体に対応した領域とそれ以外の領域との間の全域に形成
すれば、より効率良く、かつ、他への熱影響少なく発熱
制御を行うことができるとともに、伝熱用板材をアルミ
合金製とすれば、強度十分としながら以上の効果を良好
に発揮できるようになる利点がある。
By providing the dividing means by the cutting lines which are in contact with each other, the heat generation can be efficiently controlled while reducing the thermal influence on other areas, and in the case of providing the dividing means by the groove which does not lead to the cutting, It is possible to achieve the above-mentioned effect while making no change in appearance. Further, if a cutting line or a groove that does not lead to cutting is formed in the entire area between the area corresponding to the heating element in one heat transfer plate and the other area, it is more efficient and heat to the other. Heat generation can be controlled with little influence, and if the heat transfer plate is made of an aluminum alloy, there is an advantage that the above effect can be satisfactorily exhibited while the strength is sufficient.

【図面の簡単な説明】[Brief description of drawings]

【図1】構造を示す断面図FIG. 1 is a sectional view showing a structure.

【図2】プレートヒータ、及び発熱制御系統を示す平面
FIG. 2 is a plan view showing a plate heater and a heat generation control system.

【図3】小割手段の別構造を示す小割手段の部分断面図FIG. 3 is a partial cross-sectional view of the splitting means showing another structure of the splitting means.

【符号の説明】[Explanation of symbols]

1,2 伝熱用板材 3 発熱体 A 小割手段 s 切断線 m 切断に至らない溝 1, 2 Heat transfer plate 3 heating element A small break means s cutting line m Not cut

Claims (5)

【特許請求の範囲】[Claims] 【請求項1】 一対の伝熱用板材の間にプレート状の発
熱体を介装して成るプレートヒータであって、 前記発
熱体を複数設け、かつ、それら複数の発熱体に対して各
別に発熱制御自在に構成するとともに、一対の前記伝熱
用板材のうちの少なくとも一方の伝熱用板材における前
記発熱体に対応した領域とそれ以外の領域との間に、こ
れら両領域を区切るべく前記一方の伝熱用板材の厚みを
減少させる小割手段を設けてあるプレートヒータ。
1. A plate heater having a plate-shaped heating element interposed between a pair of heat transfer plate members, wherein a plurality of the heating elements are provided, and the plurality of heating elements are separately provided. While being configured to control heat generation, between a region corresponding to the heating element in at least one heat transfer plate member of the pair of heat transfer plate members and a region other than the heat transfer plate member, these two regions are divided so as to be separated from each other. A plate heater provided with slicing means for reducing the thickness of one heat transfer plate.
【請求項2】 前記小割手段が互いに接する切断線であ
る請求項1に記載のプレートヒータ。
2. The plate heater according to claim 1, wherein the dividing means are cutting lines that are in contact with each other.
【請求項3】 前記小割手段が切断に至らない溝である
請求項1に記載のプレートヒータ。
3. The plate heater according to claim 1, wherein the dividing means is a groove that does not lead to cutting.
【請求項4】 請求項2に記載の切断線、又は請求項3
に記載の溝が、前記両領域の間における全域に形成され
ているプレートヒータ。
4. The cutting line according to claim 2, or claim 3.
A plate heater in which the groove described in 1) is formed in the entire area between the both areas.
【請求項5】 前記伝熱用板材がアルミ合金製である請
求項1〜4のいずれか1項に記載のプレートヒータ。
5. The plate heater according to claim 1, wherein the heat transfer plate is made of an aluminum alloy.
JP2001213014A 2001-07-13 2001-07-13 Plate heater Pending JP2003031341A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP2001213014A JP2003031341A (en) 2001-07-13 2001-07-13 Plate heater

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2001213014A JP2003031341A (en) 2001-07-13 2001-07-13 Plate heater

Publications (1)

Publication Number Publication Date
JP2003031341A true JP2003031341A (en) 2003-01-31

Family

ID=19048068

Family Applications (1)

Application Number Title Priority Date Filing Date
JP2001213014A Pending JP2003031341A (en) 2001-07-13 2001-07-13 Plate heater

Country Status (1)

Country Link
JP (1) JP2003031341A (en)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2012015285A (en) * 2010-06-30 2012-01-19 Tokyo Electron Ltd Substrate mounting stage, substrate treatment device, and substrate treatment system
EP2073970B1 (en) 2006-09-22 2015-04-15 GEA Food Solutions Germany GmbH Heating plate with a multiplicity of heating cartridges
WO2023275948A1 (en) * 2021-06-28 2023-01-05 日本たばこ産業株式会社 Aerosol generation system
WO2023275952A1 (en) * 2021-06-28 2023-01-05 日本たばこ産業株式会社 Aerosol generation system
WO2023275949A1 (en) * 2021-06-28 2023-01-05 日本たばこ産業株式会社 Aerosol generation system

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2073970B1 (en) 2006-09-22 2015-04-15 GEA Food Solutions Germany GmbH Heating plate with a multiplicity of heating cartridges
JP2012015285A (en) * 2010-06-30 2012-01-19 Tokyo Electron Ltd Substrate mounting stage, substrate treatment device, and substrate treatment system
WO2023275948A1 (en) * 2021-06-28 2023-01-05 日本たばこ産業株式会社 Aerosol generation system
WO2023275952A1 (en) * 2021-06-28 2023-01-05 日本たばこ産業株式会社 Aerosol generation system
WO2023275949A1 (en) * 2021-06-28 2023-01-05 日本たばこ産業株式会社 Aerosol generation system
JP7498865B2 (en) 2021-06-28 2024-06-12 日本たばこ産業株式会社 Aerosol Generation System
JP7518294B2 (en) 2021-06-28 2024-07-17 日本たばこ産業株式会社 Aerosol Generation System
JP7518295B2 (en) 2021-06-28 2024-07-17 日本たばこ産業株式会社 Aerosol Generation System

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