TW201700194A - Manufacturing facility line and thermoelectric power generation method - Google Patents
Manufacturing facility line and thermoelectric power generation method Download PDFInfo
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- TW201700194A TW201700194A TW105129461A TW105129461A TW201700194A TW 201700194 A TW201700194 A TW 201700194A TW 105129461 A TW105129461 A TW 105129461A TW 105129461 A TW105129461 A TW 105129461A TW 201700194 A TW201700194 A TW 201700194A
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- 238000010248 power generation Methods 0.000 title claims abstract description 471
- 238000004519 manufacturing process Methods 0.000 title claims abstract description 111
- 238000000034 method Methods 0.000 title claims description 39
- 229910000831 Steel Inorganic materials 0.000 claims description 477
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- 238000005266 casting Methods 0.000 claims description 28
- 238000005098 hot rolling Methods 0.000 claims description 26
- 238000009749 continuous casting Methods 0.000 claims description 25
- 238000012546 transfer Methods 0.000 claims description 22
- 238000005242 forging Methods 0.000 claims description 19
- 238000010438 heat treatment Methods 0.000 claims description 19
- 230000006698 induction Effects 0.000 claims description 16
- 238000011144 upstream manufacturing Methods 0.000 claims description 10
- 238000009628 steelmaking Methods 0.000 claims description 5
- 239000003638 chemical reducing agent Substances 0.000 claims description 3
- 230000005619 thermoelectricity Effects 0.000 claims description 3
- 239000000463 material Substances 0.000 description 74
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- 229910000838 Al alloy Inorganic materials 0.000 description 1
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Classifications
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P70/00—Climate change mitigation technologies in the production process for final industrial or consumer products
- Y02P70/10—Greenhouse gas [GHG] capture, material saving, heat recovery or other energy efficient measures, e.g. motor control, characterised by manufacturing processes, e.g. for rolling metal or metal working
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- Metal Rolling (AREA)
- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
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- Electromechanical Clocks (AREA)
Abstract
Description
本發明係關於一種具有移動之熱源之煉鋼廠之製造設備線,且係關於一種熱軋設備線及使用其之熱電發電方法,該熱軋設備線包括將由熱軋步驟中之鋼胚、粗軋鋼條及熱軋鋼帶之輻射所產生之熱能轉換為電能並加以回收之熱電發電裝置。 The present invention relates to a manufacturing equipment line of a steelmaking plant having a moving heat source, and relates to a hot rolling equipment line and a thermoelectric power generating method using the same, the hot rolling equipment line including a steel preform to be roughed by the hot rolling step A thermoelectric power generation device that converts thermal energy generated by radiation of rolled steel bars and hot-rolled steel strips into electrical energy and recovers them.
又,本發明係關於一種製造設備線及使用其之熱電發電方法,上述製造設備線係包括將由連續鑄造步驟中之熱鋼胚之輻射所產生之熱能轉換為電能並加以回收之熱電發電裝置的連續鑄造設備線。 Further, the present invention relates to a manufacturing apparatus line including a thermoelectric power generation apparatus for converting thermal energy generated by radiation of a hot steel billet in a continuous casting step and recovering the same, and a thermoelectric power generation method using the same. Continuous casting equipment line.
進而,本發明係關於一種製造設備線及使用其之熱電發電方法,上述製造設備線係包括將連續實施鑄造及軋壓之鋼板製造步驟中之熱鋼胚或熱軋板之熱能轉換為電能並加以回收之熱電發電裝置且進行鑄造及軋壓的鋼板製造設備線。 Furthermore, the present invention relates to a manufacturing apparatus line and a thermoelectric power generation method using the same, the manufacturing apparatus line including converting thermal energy of a hot steel or hot rolled sheet in a steel sheet manufacturing step of continuous casting and rolling into electric energy and A steel sheet manufacturing equipment line for casting and rolling a thermoelectric power generation device to be recovered.
而且,本發明係關於一種製造設備線及使用其之熱電發電方法,上述製造設備線係包括將由鍛接管之製造步驟中之鋼板及管材之輻射所產生之熱能轉換為電能並加以回收之熱電發電裝置的鍛接管設備線。 Moreover, the present invention relates to a manufacturing equipment line including a thermoelectric power generation system that converts thermal energy generated by radiation of steel sheets and pipes in a manufacturing process of a forged pipe into electric energy and recovers the same. The forged pipe line of the device.
先前,作為席貝克效應便已知有若對不同種類之導體或半導體賦予溫度差則於高溫部與低溫部之間產生電力,亦已知有使用利用此種性質之熱電發電元件,將熱直接轉換為電力。 In the prior art, it has been known that when a temperature difference is given to a different type of conductor or semiconductor, electric power is generated between the high temperature portion and the low temperature portion. It is also known to use a thermoelectric power generation element utilizing such a property to directly conduct heat. Convert to electricity.
近年來,正推動以下研究,即,於煉鋼工廠等之製造設備中,藉由使用有如上所述之熱電發電元件之發電,而利用至今為止作為廢熱被廢棄之能量、例如由鋼胚、或粗軋鋼條、熱軋鋼帶、熱鋼胚、鋼板、管材等鋼材之輻射所產生之熱能。 In recent years, the following research has been promoted, that is, in the manufacturing equipment such as a steel-making plant, by using the power generation of the thermoelectric power generation element as described above, the energy that has been discarded as waste heat so far, for example, from a steel embryo, Or the heat generated by the radiation of steel such as rough rolled steel bars, hot rolled steel strips, hot steel blanks, steel plates, and pipes.
作為利用熱能之方法,例如專利文獻1中記載有將受熱裝置與高溫物體對向配置,將高溫物體之熱能轉換為電能並加以回收之方法。 As a method of utilizing thermal energy, for example, Patent Document 1 discloses a method in which a heat receiving device is disposed opposite to a high temperature object, and heat energy of the high temperature object is converted into electric energy and recovered.
專利文獻2中記載有使熱電元件模組接觸於作為廢熱被處理之熱能而將其轉換為電能並加以回收之方法。 Patent Document 2 describes a method in which a thermoelectric device module is brought into contact with heat energy treated as waste heat to convert it into electric energy and recover it.
專利文獻3中記載有將於冷床上自冷卻材料散發至大氣中之熱量作為電力進行回收之方法。 Patent Document 3 describes a method of recovering heat which is emitted from a cooling material to the atmosphere on a cooling bed as electric power.
專利文獻4中記載有可藉由傾斜部(rake)之熱傳導而將高溫材料之熱能有效率地轉換為電能之熱回收方法及冷床。 Patent Document 4 describes a heat recovery method and a cooling bed capable of efficiently converting thermal energy of a high-temperature material into electric energy by heat conduction of a ramp.
專利文獻5中記載有回收藉由熱軋線上之金屬材料之處理而產生之熱、且作為電力加以儲存之熱回收裝置。 Patent Document 5 describes a heat recovery device that collects heat generated by treatment of a metal material on a hot rolling line and stores it as electric power.
專利文獻1:日本專利特開昭59-198883號公報 Patent Document 1: Japanese Patent Laid-Open No. 59-198883
專利文獻2:日本專利特開昭60-34084號公報 Patent Document 2: Japanese Patent Laid-Open No. 60-34084
專利文獻3:日本專利特開平10-296319號公報 Patent Document 3: Japanese Patent Laid-Open No. Hei 10-296319
專利文獻4:日本專利特開2006-263783號公報 Patent Document 4: Japanese Patent Laid-Open No. 2006-263783
專利文獻5:日本專利特開2011-62727號公報 Patent Document 5: Japanese Patent Laid-Open Publication No. 2011-62727
然而,專利文獻1中,雖然有以可應用於鋼胚連鑄線為主旨之記載,但未考慮實際操作中之鋼胚之溫度變化、因鋼胚量之變動所致之釋放熱量(熱能)之變動等因操作條件之變動所致之熱源溫度之變化。 However, in Patent Document 1, although it is described that it can be applied to a steel preform continuous casting line, the temperature change of the steel preform in actual operation and the heat release (heat energy) due to the change in the amount of steel embryo are not considered. Changes in heat source temperature due to changes in operating conditions, such as changes.
又,專利文獻2中,由於必須將模組相對於熱源而固定,故而有無法將該技術應用於如熱軋設備等般之移動之熱源之問題。 Further, in Patent Document 2, since it is necessary to fix the module with respect to the heat source, there is a problem that the technique cannot be applied to a heat source such as a hot rolling facility.
專利文獻3中,雖然有中、高溫部之材料溫度有300℃以上、且利用其輻射熱及將材料冷卻後之對流熱之記載,但未記載實際操作中之高溫材料之溫度變化、或因高溫材料之變動所致之釋放熱量(熱能)之變動等因操作條件之變動所致之熱源溫度之變化。 In Patent Document 3, although the material temperature in the middle and high temperature portions is 300 ° C or higher, and the radiant heat and the convective heat after cooling the material are described, the temperature change of the high temperature material in actual operation or the high temperature is not described. Changes in heat source temperature due to changes in operating conditions, such as changes in heat released from heat (heat).
專利文獻4所記載之技術係僅特殊化為利用熱傳導來進行熱回收者,而未考慮實際操作中之高溫材料之溫度變化、或因高溫材料之變動所致之釋放熱量(熱能)之變動等因操作條件之變動所致之熱源溫度之變化。 The technique described in Patent Document 4 is only specialized in heat recovery by heat conduction, and does not consider changes in temperature of a high-temperature material in actual operation or a change in heat release (thermal energy) due to fluctuation of a high-temperature material. Changes in heat source temperature due to changes in operating conditions.
專利文獻5所記載之技術除如上述無實際操作上之考慮以外,該文獻中所記載之電力儲存手段亦並非必需。 The technique described in Patent Document 5 is not essential to the power storage means described in the document except for the above-mentioned practical operation.
此外,先前之熱電發電方法中,於鋼材之前端或後端等成為熱源之非穩定狀態下,為了防止因鋼板之高度變動等所導致之裝置之破損,只能將熱電發電裝置設置於鋼材之遠方。而且,若設置於鋼材之遠方,則有未能將高溫物體之熱能較佳地傳遞至熱電發電裝置而無法有效率地轉換為電能之問題。 Further, in the conventional thermoelectric power generation method, in the unsteady state in which the front end or the rear end of the steel material is a heat source, in order to prevent breakage of the device due to fluctuations in the height of the steel sheet, the thermoelectric power generation device can be placed only in the steel material. distance. Further, if it is placed far away from the steel material, there is a problem that the thermal energy of the high-temperature object cannot be efficiently transmitted to the thermoelectric power generator, and the electric energy cannot be efficiently converted into electric energy.
本發明係鑒於上述現狀而研發出者,其目的在於一併提供一種於熱源移動(流動)之熱軋設備、或連續鑄造設備、進行鑄造及軋 壓之鋼板製造設備、鍛接管設備中,包括可將釋放狀態變動之鋼胚、粗軋鋼條、熱軋鋼帶、熱軋板、鋼板及管材之熱能高效率地轉換為電能並加以回收之熱電發電裝置的熱軋設備線、連續鑄造設備線、進行鑄造及軋壓之鋼板製造設備線、以及鍛接管設備線、與使用該等之熱電發電方法。 The present invention has been made in view of the above-described status quo, and an object thereof is to provide a hot rolling apparatus or a continuous casting apparatus that moves (flows) a heat source, and performs casting and rolling. The steel plate manufacturing equipment and the forging pipe equipment include a thermoelectric power generation that can efficiently convert the thermal energy of the steel blank, the rough-rolled steel strip, the hot-rolled steel strip, the hot-rolled steel sheet, the steel plate and the pipe material with the release state into electric energy and recover it. The hot rolling equipment line of the apparatus, the continuous casting equipment line, the steel plate manufacturing equipment line for casting and rolling, the forging pipe line, and the thermoelectric power generation method using the same.
發明者等人為解決上述課題而努力進行研究之結果得出以下見解,即,可藉由根據熱能之釋放狀態來調整熱源與熱電發電單元之距離等設置位置,而進行高效率之熱電發電,且一併開發出新穎之煉鋼廠中之具備可利用熱之熱電發電裝置的熱軋設備線、連續鑄造設備線、進行鑄造及軋壓之鋼板製造設備線、以及鍛接管設備線、與使用該等之熱電發電方法。 As a result of intensive research to solve the above problems, the inventors have found that high-efficiency thermoelectric power generation can be performed by adjusting the installation position such as the distance between the heat source and the thermoelectric power generation unit according to the release state of the thermal energy. A hot rolling line, a continuous casting equipment line, a steel sheet manufacturing equipment line for casting and rolling, and a forging pipe line, which are available in a novel steelmaking plant with a heat-generating thermoelectric power generation unit, and the use of the same The thermoelectric power generation method.
本發明係立足於上述見解者。 The present invention is based on the above-mentioned insights.
即,本發明之主要構成如下所述。 That is, the main constitution of the present invention is as follows.
1.一種製造設備線,其係具有移動之熱源之煉鋼廠的製造設備線,上述製造設備線包括有熱電發電裝置,而該熱電發電裝置具有熱電發電單元、及進行該熱電發電單元之一體移動之移動手段,並且該熱電發電單元係被配置對向於上述熱源。 A manufacturing equipment line which is a manufacturing equipment line of a steelmaking plant having a moving heat source, the manufacturing equipment line including a thermoelectric power generating unit having a thermoelectric power generating unit, and performing one of the thermoelectric power generating units The moving means of moving, and the thermoelectric power generating unit is configured to oppose the heat source.
2.如上述1之製造設備線,其中,上述製造設備線係包括有對經加熱之鋼胚進行粗軋而製成粗軋鋼條之粗軋機、及對粗軋鋼條進行精軋而製成熱軋鋼帶之精軋機之熱軋設備線,上述熱電發電裝置被配置於自粗軋機前至熱軋鋼帶搬送路徑為止之鋼胚搬送路徑、粗軋機、粗軋鋼條搬送路徑、精軋機及熱軋鋼帶搬送路徑中之任一位置,且將上述熱電發電單元配置對向於鋼胚、粗軋 鋼條及熱軋鋼帶中之至少一者。 2. The manufacturing equipment line according to the above 1, wherein the manufacturing equipment line comprises a roughing mill for rough rolling a heated steel billet to obtain a rough rolled steel strip, and finishing the rough rolled steel strip to be hot. The hot rolling equipment line of the finishing mill for the rolling strip, the thermoelectric power generating device is disposed in the steel embryo transfer path from the rough rolling mill to the hot rolling steel strip conveying path, the rough rolling mill, the rough rolling steel strip conveying path, the finishing mill and the hot rolled steel strip Any one of the transport paths, and the above-mentioned thermoelectric power generation unit is disposed opposite to the steel embryo and rough rolling At least one of a steel strip and a hot rolled steel strip.
3.如上述2之製造設備線,其中,上述熱電發電裝置進而包括有運行判斷手段,而該運行判斷手段係對應於上述熱電發電單元之輸出,而判斷該熱電發電單元之運行與否。 3. The manufacturing equipment line according to the above 2, wherein the thermoelectric generation device further includes an operation determining means for determining whether the thermoelectric power generation unit operates or not according to an output of the thermoelectric generation unit.
4.如上述2或3之製造設備線,其中,對應於鋼胚、粗軋鋼條及熱軋鋼帶中之至少一者之溫度及/或熱電發電單元之輸出而設置上述熱電發電單元。 4. The manufacturing apparatus line according to the above 2 or 3, wherein the thermoelectric power generation unit is provided corresponding to a temperature of at least one of a steel blank, a rough rolled steel strip, and a hot rolled steel strip and/or an output of the thermoelectric power generation unit.
5.如上述2至4中任一項之製造設備線,其中,對應於鋼胚、粗軋鋼條及熱軋鋼帶中之至少一者之溫度及/或熱電發電單元之輸出,而相對於高溫部以靠近於低溫部之方式設置上述熱電發電單元。 5. The manufacturing equipment line of any one of the above 2 to 4, wherein the temperature of the at least one of the steel blank, the rough rolled steel strip and the hot rolled steel strip and/or the output of the thermoelectric power generating unit is relative to the high temperature The thermoelectric power generation unit is disposed in such a manner as to be close to the low temperature portion.
6.如上述2至5中任一項之製造設備線,其中,對應於鋼胚、粗軋鋼條及熱軋鋼帶中之至少一者之溫度及/或熱電發電單元之輸出,而相對於低溫部將上述熱電發電單元中之熱電發電模組緊密地配置於高溫部。 6. The manufacturing equipment line of any one of the above 2 to 5, wherein the temperature corresponding to at least one of the steel blank, the rough rolled steel strip and the hot rolled steel strip and/or the output of the thermoelectric power generating unit is relative to the low temperature The thermoelectric power generation module in the thermoelectric power generation unit is closely arranged in the high temperature portion.
7.如上述2至6中任一項之製造設備線,其中,上述移動手段係對應於測定鋼胚、粗軋鋼條及熱軋鋼帶中之至少一者之溫度及/或熱電發電單元之輸出而求出之溫度及/或輸出,而進行該熱電發電單元、與該鋼胚、粗軋鋼條及熱軋鋼帶中之至少一者之距離之控制。 7. The manufacturing equipment line according to any one of the above 2 to 6, wherein the moving means corresponds to measuring the temperature of at least one of the steel blank, the rough rolled steel strip and the hot rolled steel strip and/or the output of the thermoelectric power generating unit. The temperature and/or output is determined to control the distance between the thermoelectric power generation unit and at least one of the steel blank, the rough rolled steel strip, and the hot rolled steel strip.
8.如上述2至7中任一項之製造設備線,其中,上述熱電發電裝置進而包括有熱反射材。 8. The manufacturing apparatus line according to any one of the above 2 to 7, wherein the thermoelectric power generating apparatus further includes a heat reflective material.
9.如上述2至8中任一項之製造設備線,其中,上述熱電發電裝置係成為包圍鋼胚、粗軋鋼條及熱軋鋼帶中之至少一者之外周部之形狀。 The manufacturing equipment line according to any one of the above 2 to 8, wherein the thermoelectric power generating device has a shape surrounding a peripheral portion of at least one of a steel blank, a rough rolled steel strip, and a hot rolled steel strip.
10.如上述2至9中任一項之製造設備線,其中,上述熱電發電裝置係至少設置有一處開口部。 10. The manufacturing apparatus line according to any one of the above 2 to 9, wherein the thermoelectric power generating apparatus is provided with at least one opening.
11.一種熱電發電方法,其係利用上述2至10中任一項之製造設備線,接收鋼胚、粗軋鋼條及熱軋鋼帶中之至少一者之熱而進行熱電發電。 A thermoelectric power generation method for performing thermoelectric power generation by receiving heat of at least one of a steel blank, a rough rolled steel strip, and a hot rolled steel strip using the manufacturing equipment line of any one of the above 2 to 10.
12.如上述11之熱電發電方法,其中,利用上述製造設備線之運行判斷手段而控制熱電發電單元之運行。 12. The thermoelectric power generation method according to the above 11, wherein the operation of the thermoelectric power generation unit is controlled by the operation determining means of the manufacturing equipment line.
13.如上述1之製造設備線,其中,上述製造設備線係包括有鋼胚冷卻裝置及鋼胚切斷裝置而連續鑄造熱鋼胚之連續鑄造設備線,上述熱電發電裝置被配置於自鋼胚冷卻裝置送出側至鋼胚切斷裝置之上游、鋼胚切斷裝置之下方及鋼胚切斷裝置送出側中之任一位置,且將上述熱電發電單元配置對向於熱鋼胚。 13. The manufacturing equipment line according to the above 1, wherein the manufacturing equipment line comprises a continuous casting equipment line for continuously casting a hot steel billet with a steel blank cooling device and a steel blank cutting device, and the thermoelectric power generating device is configured from steel. The delivery side of the embryo cooling device to the upstream of the steel cutting device, the lower portion of the steel cutting device, and the delivery side of the steel cutting device, and the thermoelectric power generation unit is disposed opposite to the hot steel.
14.如上述13之製造設備線,其中,上述熱電發電裝置進而包括有運行判斷手段,而該運行判斷手段係對應於上述熱電發電單元之輸出而判斷該熱電發電單元之運行與否。 14. The manufacturing equipment line according to the above 13, wherein the thermoelectric generation device further includes an operation determining means for determining whether the thermoelectric power generation unit operates or not according to an output of the thermoelectric power generation unit.
15.如上述13或14之製造設備線,其中,對應於熱鋼胚之溫度及/或熱電發電單元之輸出而設置上述熱電發電單元。 15. The manufacturing apparatus line according to the above 13 or 14, wherein the thermoelectric power generation unit is provided corresponding to a temperature of the hot steel billet and/or an output of the thermoelectric power generating unit.
16.如上述13至15中任一項之製造設備線,其中,對應於熱鋼胚之寬度方向溫度分佈,而相對於高溫部以靠近於低溫部之方式設置上述熱電發電單元。 16. The manufacturing apparatus line according to any one of the above 13 to 15, wherein the thermoelectric power generation unit is disposed in a manner close to the low temperature portion with respect to the high temperature portion corresponding to the temperature distribution in the width direction of the hot steel.
17.如上述13至16中任一項之製造設備線,其中,對應於熱鋼胚之寬度方向溫度分佈,而相對於低溫部將上述熱電發電單元中之熱電發電模組緊密地配置於高溫部。 17. The manufacturing apparatus line according to any one of the above 13 to 16, wherein the thermoelectric power generation module in the thermoelectric power generation unit is closely arranged at a high temperature with respect to the low temperature portion corresponding to a temperature distribution in a width direction of the hot steel blank unit.
18.如上述13至17中任一項之製造設備線,其中,上述移動手段係對應於測定熱鋼胚之溫度及/或熱電發電單元之輸出而求出之溫度及/或輸出,而進行該熱電發電單元與該熱鋼胚之距離之控制。 The manufacturing apparatus line according to any one of the above 13 to 17, wherein the moving means is performed in accordance with a temperature and/or an output obtained by measuring a temperature of the hot steel billet and/or an output of the thermoelectric power generating unit. The control of the distance between the thermoelectric power generation unit and the hot steel billet.
19.如上述13至18中任一項之製造設備線,其中,上述熱電發電裝置進而包括有熱反射材。 The manufacturing equipment line according to any one of the above 13 to 18, wherein the thermoelectric generation device further includes a heat reflective material.
20.如上述13至19中任一項之製造設備線,其中,上述熱電發電裝置係成為包圍熱鋼胚之外周部之形狀。 The manufacturing equipment line according to any one of the above 13 to 19, wherein the thermoelectric power generating device has a shape surrounding an outer peripheral portion of the hot steel slab.
21.如上述13至20中任一項之連續鑄造設備線,其中,上述熱電發電裝置係至少設置有一處開口部。 The continuous casting equipment line according to any one of the above 13 to 20, wherein the thermoelectric generation device is provided with at least one opening.
22.一種熱電發電方法,其係利用上述13至21中任一項之製造設備線,接收熱鋼胚之熱而進行熱電發電。 A thermoelectric power generation method for performing thermoelectric power generation by receiving heat of a hot steel bill using the manufacturing equipment line of any one of the above 13 to 21.
23.如上述22之熱電發電方法,其中,利用於鋼胚切斷裝置送出側具備有熱電發電裝置之製造設備線,將對向於上述熱電發電裝置之熱鋼胚之搬送速度設定為連續鑄造速度以上、且為連續鑄造速度之1.1倍以下之速度。 23. The thermoelectric power generation method according to the above-mentioned item 22, wherein the conveying line provided with the thermoelectric power generating device on the delivery side of the steel preform cutting device is set to continuously cast the hot steel preform to the thermoelectric power generating device. Above speed, and is at least 1.1 times the continuous casting speed.
24.如上述22或23之熱電發電方法,其中,利用上述製造設備線之運行判斷手段而控制熱電發電單元之運行。 24. The thermoelectric power generation method according to 22 or 23 above, wherein the operation of the thermoelectric power generation unit is controlled by the operation determining means of the above-described manufacturing equipment line.
25.如上述1之製造設備線,其中,上述製造設備線係包括有鋼胚鑄造機及軋壓線而進行鑄造及軋壓之鋼板製造設備線,上述熱電發電裝置被配置於在上述鋼胚鑄造機之鋼胚冷卻裝置及鋼胚切斷裝置中之鋼胚冷卻裝置送出側、鋼胚切斷裝置內及鋼胚切斷裝置送出側、以及在上述軋壓線之保持爐、感應爐、軋壓機及滾子台中之保持爐之前、保持爐之後、感應爐之前、感應爐之後、軋壓機之前、軋壓機之後、滾子台之上及滾子台之間中選出之至少一個位置, 且將上述熱電發電單元配置對向於鋼胚及/或熱軋板。 25. The manufacturing equipment line according to the above 1, wherein the manufacturing equipment line includes a steel sheet manufacturing equipment line which is cast and rolled by a steel blank casting machine and a rolling line, and the thermoelectric power generating apparatus is disposed in the steel embryo. The steel embryo cooling device and the steel embryo cutting device of the casting machine, the steel embryo cooling device delivery side, the steel embryo cutting device, and the steel embryo cutting device delivery side, and the holding furnace and the induction furnace of the rolling line, At least one of the rolling mill and the roller table, which is selected before the furnace is maintained, after the furnace is maintained, before the induction furnace, after the induction furnace, before the rolling press, after the rolling press, above the roller table, and between the roller tables position, And the thermoelectric power generation unit is disposed opposite to the steel blank and/or the hot rolled sheet.
26.如上述25之製造設備線,其中,上述熱電發電裝置進而包括有運行判斷手段,而該運行判斷手段係對應於上述熱電發電單元之輸出而判斷熱電發電單元之運行與否。 26. The manufacturing apparatus line according to the above 25, wherein the thermoelectric generation device further includes an operation determining means for determining whether the thermoelectric power generation unit is operated or not according to an output of the thermoelectric power generation unit.
27.如上述25或26之製造設備線,其中,對應於鋼胚及熱軋板中之至少一者之溫度及/或熱電發電單元之輸出而設置上述熱電發電單元。 27. The manufacturing apparatus line of 25 or 26 above, wherein the thermoelectric power generation unit is provided corresponding to a temperature of at least one of the steel blank and the hot rolled sheet and/or an output of the thermoelectric power generating unit.
28.如上述25至27中任一項之製造設備線,其中,對應於鋼胚及熱軋板中之至少一者之溫度及/或熱電發電單元之輸出,而相對於低溫部將上述熱電發電單元中之熱電發電模組緊密地配置於高溫部,從而使輸出穩定於高位。 The manufacturing apparatus line of any one of the above-mentioned items 25 to 27, wherein the thermoelectricity is compared with respect to the low temperature portion corresponding to the temperature of at least one of the steel blank and the hot rolled sheet and/or the output of the thermoelectric power generating unit The thermoelectric power generation module in the power generation unit is closely arranged at the high temperature portion, thereby stabilizing the output at a high level.
29.如上述25至28中任一項之製造設備線,其中,上述移動手段係對應於測定鋼胚及熱軋板中之至少一者之溫度及/或熱電發電單元之輸出而求出之溫度及/或輸出,而進行該熱電發電單元與該鋼胚及熱軋板中之至少一者之距離之控制。 The manufacturing equipment line according to any one of the above-mentioned items 25 to 28, wherein the moving means is determined according to a temperature of at least one of the steel preform and the hot rolled sheet and/or an output of the thermoelectric power generating unit. Temperature and/or output, and control of the distance between the thermoelectric power generation unit and at least one of the steel blank and the hot rolled sheet.
30.如上述25至29中任一項之製造設備線,其中,上述熱電發電裝置進而包括有熱反射材。 The manufacturing apparatus line according to any one of the above-mentioned items 25 to 29, wherein the thermoelectric power generating device further includes a heat reflective material.
31.如上述25至30中任一項之製造設備線,其中,上述熱電發電裝置係成為包圍鋼胚及熱軋板中之至少一者之外周部之形狀。 The manufacturing equipment line according to any one of the items 25 to 30, wherein the thermoelectric power generating device has a shape surrounding a peripheral portion of at least one of the steel blank and the hot rolled sheet.
32.如上述25至31中任一項之製造設備線,其中,上述熱電發電裝置係至少設置有一處開口部,用於使熱電發電裝置進行退避。 The manufacturing apparatus line according to any one of the above-mentioned items 25 to 31, wherein the thermoelectric power generating apparatus is provided with at least one opening for retracting the thermoelectric generation device.
33.一種熱電發電方法,其係利用上述25至32中任一項 之製造設備線,接收鋼胚及熱軋板中之至少一者之熱而進行熱電發電。 33. A method of thermoelectric generation, which utilizes any of the above 25 to 32 The manufacturing equipment line receives the heat of at least one of the steel blank and the hot rolled sheet to perform thermoelectric power generation.
34.如上述33之熱電發電方法,其中,利用上述製造設備線之運行判斷手段而控制熱電發電單元之運行。 34. The thermoelectric power generation method according to 33 above, wherein the operation of the thermoelectric power generation unit is controlled by the operation determining means of the above-described manufacturing equipment line.
35.如上述1之製造設備線,其中,上述製造設備線係具有加熱爐、鍛接機及拉伸縮管機(Stretch reducer)、且將捲繞成熱軋鋼捲之鋼板製成管材之鍛接管設備線,上述熱電發電裝置被配置於從加熱爐至拉伸縮管機為止之鋼板及管材之搬送路徑中選出之至少一個位置,且將上述熱電發電單元配置對向於鋼板及管材中之至少一者。 35. The manufacturing equipment line according to the above 1, wherein the manufacturing equipment line has a heating furnace, a forging machine, and a Stretch reducer, and the forging pipe device for forming a steel sheet wound into a hot rolled steel coil into a pipe material In the wire, the thermoelectric generation device is disposed at at least one of a steel plate and a pipe transport path from the heating furnace to the stretch tube machine, and the thermoelectric power generation unit is disposed to face at least one of the steel plate and the pipe material. .
36.如上述35之製造設備線,其中,對應於鋼板及管材中之至少一者之溫度及/或熱電發電單元之輸出而設置上述熱電發電單元。 36. The manufacturing equipment line of 35 above, wherein the thermoelectric power generation unit is provided corresponding to a temperature of at least one of the steel sheet and the pipe and/or an output of the thermoelectric power generation unit.
37.如上述35或36之製造設備線,其中,對應於鋼板及管材中之至少一者之溫度及/或熱電發電單元之輸出,而相對於高溫部以靠近於低溫部之方式設置上述熱電發電單元。 37. The manufacturing apparatus line of 35 or 36, wherein the thermoelectricity is set in a manner close to the low temperature portion with respect to the high temperature portion corresponding to the temperature of at least one of the steel sheet and the tube and/or the output of the thermoelectric power generating unit. Power generation unit.
38.如上述35至37中任一項之製造設備線,其中,對應於鋼板及管材中之至少一者之溫度及/或熱電發電單元之輸出,而相對於低溫部將上述熱電發電單元中之熱電發電模組緊密地配置於高溫部。 The manufacturing equipment line of any one of the above-mentioned 35 to 37, wherein the temperature of the at least one of the steel sheet and the pipe and/or the output of the thermoelectric power generating unit is the same as that of the low temperature portion The thermoelectric power generation module is closely arranged at a high temperature portion.
39.如上述35至38中任一項之製造設備線,其中,上述移動手段係對應於測定鋼板及管材中之至少一者之溫度及/或熱電發電單元之輸出而求出之溫度及/或輸出,而進行該熱電發電單元與該鋼板及管材中之至少一者之距離之控制。 The manufacturing apparatus line according to any one of the above-mentioned items 35 to 38, wherein the moving means corresponds to determining a temperature of at least one of a steel sheet and a pipe and/or a temperature of the thermoelectric power generation unit and/or Alternatively, the control is performed to control the distance between the thermoelectric power generation unit and at least one of the steel plate and the pipe.
40.如上述35至39中任一項之製造設備線,其中,上述 熱電發電裝置進而包括有熱反射材。 40. The manufacturing equipment line of any one of the above 35 to 39, wherein The thermoelectric generation device further includes a heat reflective material.
41.如上述35至40中任一項之製造設備線,其中,上述熱電發電裝置係成為包圍鋼板及管材中之至少一者之外周部之形狀。 The manufacturing equipment line according to any one of the above-mentioned items, wherein the thermoelectric power generation device has a shape surrounding a peripheral portion of at least one of the steel sheet and the pipe.
42.如上述35至41中任一項之製造設備線,其中,上述熱電發電裝置係至少設置有一處開口部。 The manufacturing apparatus line according to any one of the above 35 to 41, wherein the thermoelectric power generating apparatus is provided with at least one opening.
43.一種熱電發電方法,其係利用上述35至42中任一項之製造設備線,接收鋼板及管材中之至少一者之熱而進行熱電發電。 43. A method of thermoelectric generation, which is characterized in that the heat of at least one of a steel sheet and a pipe is received by the manufacturing equipment line of any one of the above 35 to 42 to perform thermoelectric power generation.
根據本發明,由於可將熱電發電單元及熱源(鋼胚、粗軋鋼條、熱軋鋼帶、熱軋板、鋼板及管材)保持為發電效率良好之狀態,故而發電效率有效地提昇。其結果,與先前相比,可以高水準回收自熱源釋放之熱能。 According to the present invention, since the thermoelectric power generation unit and the heat source (steel blank, rough rolled steel strip, hot rolled steel strip, hot rolled sheet, steel sheet, and pipe) can be maintained in a state in which power generation efficiency is good, power generation efficiency is effectively improved. As a result, the heat energy released from the heat source can be recovered at a high level as compared with the prior art.
1‧‧‧熱電發電單元 1‧‧‧Thermal power generation unit
2‧‧‧移動手段 2‧‧‧Mobile means
3‧‧‧熱電發電裝置 3‧‧‧Thermal power generation unit
4‧‧‧輸送輥輪 4‧‧‧Conveying roller
5‧‧‧鋼材 5‧‧‧Steel
6‧‧‧熱電元件 6‧‧‧Thermal components
7‧‧‧電極 7‧‧‧Electrode
8‧‧‧熱電發電模組 8‧‧‧Thermal power generation module
9‧‧‧絕緣材料 9‧‧‧Insulation materials
10‧‧‧受熱手段 10‧‧‧heated means
11‧‧‧散熱手段 11‧‧‧heating means
21‧‧‧盛鋼桶 21‧‧‧Steel drum
22‧‧‧餵槽 22‧‧‧ Feeding trough
23‧‧‧鑄模 23‧‧‧Molding
24‧‧‧鋼胚冷卻裝置 24‧‧‧Steel embryo cooling device
25‧‧‧矯正輥等輥群 25‧‧‧Friction roller
26‧‧‧鋼胚切斷裝置 26‧‧‧Steel embryo cutting device
27‧‧‧溫度計 27‧‧‧ thermometer
28‧‧‧熱電發電裝置 28‧‧‧Thermal power generation unit
29‧‧‧引錠桿台 29‧‧‧Ingot bar
31‧‧‧餵槽 31‧‧‧ Feeding trough
32‧‧‧鑄模 32‧‧‧Molding
33‧‧‧鑄造機 33‧‧‧ casting machine
34‧‧‧保持爐 34‧‧‧maintaining furnace
35‧‧‧感應爐 35‧‧‧Induction furnace
36‧‧‧粗軋機 36‧‧‧Roughing mill
37‧‧‧精軋機 37‧‧‧ finishing mill
38‧‧‧水冷裝置 38‧‧‧Water cooling device
39‧‧‧捲取機 39‧‧‧Winding machine
40、41‧‧‧剪切機 40, 41‧‧‧ shearing machine
42‧‧‧帶狀鋼板剪切機 42‧‧‧Strip steel plate shearing machine
51‧‧‧鋼板 51‧‧‧ steel plate
52‧‧‧管材 52‧‧‧ pipes
53‧‧‧加熱爐 53‧‧‧heating furnace
54‧‧‧成形鍛接機 54‧‧‧Forming forging machine
55‧‧‧熱減徑管 55‧‧‧Hot reducer
56‧‧‧旋轉式熱鋸 56‧‧‧Rotary hot saw
57‧‧‧冷床 57‧‧‧Cold bed
58‧‧‧篩選器 58‧‧‧ Filter
59‧‧‧矯直器 59‧‧‧ Straightener
100‧‧‧熱反射材 100‧‧‧Hot reflective material
a、b、c、d‧‧‧距離 a, b, c, d‧‧‧ distance
A、B、C、D、E、F、G、H、I、J、K、L、M、N‧‧‧裝置之設置場所 Installation place of A, B, C, D, E, F, G, H, I, J, K, L, M, N‧‧‧ devices
圖1係說明本發明之一實施形態之模式圖。 BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing an embodiment of the present invention.
圖2係本發明之一實施形態之熱電發電單元之剖面圖。 Figure 2 is a cross-sectional view showing a thermoelectric power generation unit according to an embodiment of the present invention.
圖3係說明本發明之一實施形態之另一模式圖。 Fig. 3 is a schematic view showing another embodiment of an embodiment of the present invention.
圖4係表示本發明之一實施形態之熱電發電裝置之說明圖。 Fig. 4 is an explanatory view showing a thermoelectric generation device according to an embodiment of the present invention.
圖5係表示本發明之一實施形態之另一熱電發電裝置之說明圖。 Fig. 5 is an explanatory view showing another thermoelectric power generator according to an embodiment of the present invention.
圖6係表示本發明之一實施形態之熱電發電裝置之設置場所(熱軋設備)之圖。 Fig. 6 is a view showing an installation place (hot rolling facility) of the thermoelectric generation device according to the embodiment of the present invention.
圖7係表示本發明之一實施形態之熱電發電裝置之設置場所(連續鑄造設備)之圖。 Fig. 7 is a view showing a installation place (continuous casting equipment) of a thermoelectric generation device according to an embodiment of the present invention.
圖8係表示本發明之一實施形態之熱電發電裝置之設置場所(鋼板 製造設備)之圖。 Fig. 8 is a view showing a place where a thermoelectric power generator according to an embodiment of the present invention is installed (steel plate) Diagram of manufacturing equipment).
圖9係表示本發明之一實施形態之熱電發電裝置之設置場所(鍛接管設備)之圖。 Fig. 9 is a view showing a installation place (forging pipe device) of the thermoelectric generation device according to the embodiment of the present invention.
圖10係表示發電輸出比相對於鋼材與熱電發電單元之距離之關係之曲線圖。 Fig. 10 is a graph showing the relationship between the power generation output ratio and the distance between the steel material and the thermoelectric power generation unit.
圖11係表示發電輸出比相對於管材與熱電發電單元之距離之關係之曲線圖。 Fig. 11 is a graph showing the relationship between the power generation output ratio and the distance between the pipe and the thermoelectric power generation unit.
圖12係表示本發明之熱電發電單元之設置例之圖。 Fig. 12 is a view showing an example of the arrangement of the thermoelectric generation unit of the present invention.
圖13係表示本發明之熱電發電單元之鍛接管設備線中之設置例之圖。 Fig. 13 is a view showing an arrangement example in the forging pipe line of the thermoelectric generation unit of the present invention.
圖14係表示本發明之熱電發電單元中之熱電發電模組之配置例之剖面圖。 Fig. 14 is a cross-sectional view showing an arrangement example of a thermoelectric power generation module in the thermoelectric generation unit of the present invention.
圖15係表示本發明之熱電發電單元中之熱電發電模組之鍛接管設備線中之配置例之剖面圖。 Fig. 15 is a cross-sectional view showing an arrangement example of a forging pipe line of a thermoelectric power module in the thermoelectric generation unit of the present invention.
圖16(A)及(B)係表示本發明之附有反射材之熱電發電裝置之設置例之圖。 16(A) and 16(B) are views showing an installation example of a thermoelectric power generator with a reflector according to the present invention.
圖17(A)及(B)係表示本發明之附有反射材之熱電發電裝置之鍛接管設備線中之設置例之圖。 17(A) and (B) are views showing an example of installation in a forging pipe line of a thermoelectric power generator with a reflector according to the present invention.
圖18(A)及(B)係表示本發明之熱電發電單元之另一設置例之圖。 18(A) and 18(B) are views showing another example of installation of the thermoelectric generation unit of the present invention.
圖19(A)至(E)係表示本發明之熱電發電單元之鍛接管設備線中之另一設置例之圖。 19(A) to (E) are views showing another example of the arrangement of the forging pipe line of the thermoelectric generation unit of the present invention.
以下,具體地說明本發明。 Hereinafter, the present invention will be specifically described.
圖1係說明本發明之熱電發電裝置之一實施形態之模式圖。圖中, 1為熱電發電單元,2為移動手段,3為熱電發電裝置,4為輸送輥輪,以及5為熱源。 Fig. 1 is a schematic view showing an embodiment of a thermoelectric generation device according to the present invention. In the picture, 1 is a thermoelectric power generation unit, 2 is a moving means, 3 is a thermoelectric power generation device, 4 is a conveying roller, and 5 is a heat source.
本發明中,熱電發電裝置3包括與熱源5對向配置之熱電發電單元1、及熱電發電單元之移動手段2。再者,通常,熱源5位於輸送輥輪之上方。 In the present invention, the thermoelectric generation device 3 includes a thermoelectric power generation unit 1 disposed opposite to the heat source 5, and a moving means 2 of the thermoelectric generation unit. Further, usually, the heat source 5 is located above the conveying roller.
本發明中之熱源係熱軋裝置中之鋼胚、粗軋鋼條及熱軋鋼帶(以下,稱為鋼胚等之情形係指鋼胚、粗軋鋼條及熱軋鋼帶)、或連續鑄造裝置中之熱鋼胚(本發明中亦簡稱為鋼胚,若無特別聲明,包含於上述鋼胚等之中)、鑄造及軋壓步驟中之鋼胚或熱軋板(根據處理步驟粗軋鋼條、熱鋼板、熱軋板、鋼板、熱鋼帶、鋼帶、帶狀鋼板(strip)、厚板等之稱呼有所變化,但以下,本發明中稱為熱軋板等)、鍛接管製造裝置中之鋼板及管材(以下,亦簡稱為管材等)(以下,稱為熱源之情形係指上述所有熱源之統稱)。 The heat source in the present invention is a steel blank, a rough-rolled steel strip and a hot-rolled steel strip in a hot rolling apparatus (hereinafter, referred to as a steel blank or the like, referred to as a steel blank, a rough-rolled steel strip, and a hot-rolled steel strip), or a continuous casting apparatus. Hot steel embryo (also referred to as steel embryo in the present invention, if not stated otherwise, included in the steel embryo, etc.), steel or hot-rolled sheet in the casting and rolling steps (rough-rolling steel strip according to the treatment step, The names of hot steel sheets, hot rolled sheets, steel sheets, hot steel strips, steel strips, strips, thick plates, and the like are changed, but in the following, the present invention is referred to as a hot rolled sheet or the like, and a forged pipe manufacturing apparatus is used. Steel sheets and pipes in the middle (hereinafter, also referred to as pipes, etc.) (hereinafter, referred to as heat sources refers to the general term of all the heat sources mentioned above).
又,本發明之熱電發電裝置於熱源之寬度方向及長度方向包括至少一個熱電發電單元。而且,該熱電發電單元具有如下所示之與熱源對向之受熱手段、至少一個熱電發電模組、及散熱手段。 Further, the thermoelectric generation device of the present invention includes at least one thermoelectric power generation unit in the width direction and the longitudinal direction of the heat source. Further, the thermoelectric power generation unit has a heat receiving means opposite to the heat source, at least one thermoelectric power generation module, and a heat radiating means as shown below.
受熱手段雖因材質而異,但會成為熱電元件之高溫側溫度加上數度至數十度、有時為數百度左右之溫度。因此,受熱手段只要於該溫度下具有耐熱性或耐久性即可。例如除可使用銅或銅合金、鋁、鋁合金、陶瓷以外,可使用一般之鋼鐵材料。 Although the heat receiving means differs depending on the material, it may be a temperature of a high temperature side of the thermoelectric element plus a temperature of several degrees to several tens of degrees and sometimes several hundreds of degrees. Therefore, the heat receiving means may have heat resistance or durability at this temperature. For example, in general, a steel material such as copper or a copper alloy, aluminum, an aluminum alloy, or a ceramic can be used.
再者,鋁由於熔點較低,故而可使用於進行與熱源相對應之熱設計、且需要耐熱之情形。又,陶瓷由於導熱率較小,故而會於受熱手段中造成溫度差,但於產生在鋼胚等與鋼胚等之間無熱源之狀態之部位,亦可期待其蓄熱效果,故而可使用。 Further, since aluminum has a low melting point, it can be used for heat design corresponding to a heat source and heat resistance is required. Further, since the ceramic has a small thermal conductivity, it causes a temperature difference in the heat receiving means. However, it can be used in a portion where there is no heat source between the steel or the like and the steel or the like, and the heat storage effect can be expected.
另一方面,散熱手段為先前公知者即可,並無特別之限制,作為較佳之形態,例示包括散熱片之冷卻裝置、或有效利用接觸熱傳遞之水冷裝置、有效利用沸騰熱傳遞之散熱器、具有冷媒流路之水冷板等。 On the other hand, the heat dissipating means is not particularly limited, and a preferred embodiment includes a cooling device including a heat sink, a water cooling device that effectively utilizes contact heat transfer, and a heat sink that effectively utilizes boiling heat transfer. , water-cooled plate with refrigerant flow path, etc.
又,即便利用噴淋冷卻等對熱電發電單元之低溫側進行水冷,亦將低溫側高效率地冷卻。尤其係於將熱電發電單元設置於較熱源靠下方之情形時,即便應用噴淋冷卻,藉由將噴淋器適當配置,剩餘水落下至平台下,亦將熱電發電單元之低溫側高效率地冷卻,而不會將熱電發電單元之高溫側冷卻。於進行噴淋冷卻之情形時,噴淋冷媒所接觸而被冷卻之側成為散熱手段。 Moreover, even if the low temperature side of the thermoelectric power generation unit is water-cooled by shower cooling or the like, the low temperature side is efficiently cooled. In particular, when the thermoelectric power generation unit is disposed below the heat source, even if the shower cooling is applied, the low temperature side of the thermoelectric power generation unit is efficiently disposed by appropriately arranging the shower device and leaving the remaining water down to the platform. Cooling without cooling the high temperature side of the thermoelectric unit. In the case of spray cooling, the side to which the shower refrigerant contacts and is cooled becomes a heat sink.
本發明中所使用之熱電發電模組8係如圖2所示般,將由數十~數百對電極7連接作為熱電元件6之P型及N型之半導體而成之熱電元件群二維地排列,且進而包含配置於熱電元件群之兩側之絕緣材料9。又,上述熱電發電模組8亦可於兩側或單側具備導熱片或保護板。進而,該保護板亦可分別兼作受熱手段10或散熱手段11。 As shown in FIG. 2, the thermoelectric power module 8 used in the present invention is a thermoelectric element group in which tens to hundreds of pairs of electrodes 7 are connected as P-type and N-type semiconductors of the thermoelectric element 6 in two dimensions. Arranged, and further comprising insulating material 9 disposed on both sides of the thermoelectric element group. Further, the thermoelectric power module 8 may be provided with a heat conductive sheet or a protective plate on both sides or on one side. Furthermore, the protective plates can also serve as the heat receiving means 10 or the heat dissipating means 11, respectively.
於作為受熱手段10及/或散熱手段11之冷卻板本身為絕緣材料,或於表面被覆有絕緣材料之情形時,亦可取代絕緣材料9。圖中,1為熱電發電單元,6為熱電元件,7為電極,9為絕緣材料,及8為熱電發電模組,10為受熱手段,以及11為散熱手段。 When the cooling plate itself as the heat receiving means 10 and/or the heat dissipating means 11 is an insulating material, or when the surface is covered with an insulating material, the insulating material 9 may be replaced. In the figure, 1 is a thermoelectric power generation unit, 6 is a thermoelectric element, 7 is an electrode, 9 is an insulating material, and 8 is a thermoelectric power generation module, 10 is a heat receiving means, and 11 is a heat dissipating means.
本發明中,可於受熱手段與熱電發電模組之間、或散熱手段與熱電發電模組之間、或絕緣材料與保護板之間等,設置上述導熱片,以減小構件彼此之熱接觸電阻,而謀求熱電發電效率之進一步提昇。該導熱片只要為具有既定之導熱率,且可於熱電發電模組之使用環境下使用之片材,便無特別限制,以石墨片材等為例示。 In the present invention, the heat conducting sheet may be disposed between the heat receiving means and the thermoelectric power generating module, or between the heat radiating means and the thermoelectric power generating module, or between the insulating material and the protective plate, to reduce thermal contact between the members. Resistance, and seek for further improvement in the efficiency of thermoelectric power generation. The heat conductive sheet is not particularly limited as long as it has a predetermined thermal conductivity and can be used in the use environment of the thermoelectric power module, and a graphite sheet or the like is exemplified.
再者,本發明之熱電發電模組之大小較佳為1×10-2m2以下。其原因在於藉由使模組之大小為上述程度,可抑制熱電發電模組之變形。更佳為2.5×10-3m2以下。 Furthermore, the size of the thermoelectric power module of the present invention is preferably 1 × 10 -2 m 2 or less. The reason for this is that the deformation of the thermoelectric power module can be suppressed by making the size of the module to the above-described extent. More preferably, it is 2.5 × 10 -3 m 2 or less.
又,熱電發電單元之大小較佳為1m2以下。其原因在於藉由使單元為1m2以下,可抑制熱電發電模組之相互間、或熱電發電單元本身之變形。更佳為2.5×10-1m2以下。而且,藉由將1至數百個之範圍之該熱電發電模組連結,而形成熱電發電單元。 Further, the size of the thermoelectric power generation unit is preferably 1 m 2 or less. This is because the deformation of the thermoelectric power generation modules or the thermoelectric power generation unit itself can be suppressed by making the unit 1 m 2 or less. More preferably, it is 2.5 × 10 -1 m 2 or less. Further, the thermoelectric power generation unit is formed by connecting the thermoelectric power modules in the range of 1 to several hundred.
於本發明之製造設備線中,可將包括與熱軋設備之鋼胚等對向配置之熱電發電單元、及進行該熱電發電單元之一體移動之移動手段的熱電發電裝置備置於自粗軋機前至熱軋鋼帶搬送路徑為止之鋼胚搬送路徑、粗軋機、粗軋鋼條搬送路徑、精軋機及熱軋鋼帶搬送路徑中之任一位置。 In the manufacturing equipment line of the present invention, a thermoelectric power generation unit including a steel slab and the like arranged in a hot rolling facility, and a thermoelectric power generation device for moving the unit of the thermoelectric power generation unit can be placed in front of the rough rolling mill. Any one of the steel preform transfer path, the rough rolling mill, the rough rolling steel strip transfer path, the finishing mill, and the hot rolled steel strip transfer path up to the hot rolled steel strip transfer path.
又,於本發明之製造設備線中,可將包括與連續鑄造設備之鋼胚對向配置之熱電發電單元、及進行該熱電發電單元之一體移動之移動手段的熱電發電裝置備置於鋼胚冷卻裝置送出側、鋼胚切斷裝置中及鋼胚切斷裝置送出側中之任一位置。 Further, in the manufacturing equipment line of the present invention, the thermoelectric power generation unit including the steel preform disposed opposite to the continuous casting apparatus, and the thermoelectric power generation unit for moving the unit of the thermoelectric power generation unit may be placed in the steel embryo cooling. Any of the device delivery side, the steel blank cutting device, and the steel blank cutting device delivery side.
進而,於本發明之製造設備線中,可將包括與鋼板製造設備之鋼胚及/或熱軋板對向配置之熱電發電單元、及進行該熱電發電單元之一體移動之移動手段的熱電發電裝置備置於鋼胚鑄造機之鋼胚冷卻裝置及鋼胚切斷裝置中之鋼胚冷卻裝置送出側、鋼胚切斷裝置內及鋼胚切斷裝置送出側、以及軋壓線之保持爐、感應爐、軋壓機及滾子台中之保持爐之前、保持爐之後、感應爐之前、感應爐之後、軋壓機之前、軋壓機之後、滾子台上及滾子台間中之任一位置。 Further, in the manufacturing equipment line of the present invention, the thermoelectric power generation unit including the steel slab and/or the hot-rolled sheet which are arranged in the steel sheet manufacturing facility, and the thermoelectric power generation unit which moves the one of the thermoelectric power generation unit can be used. The device is placed in the steel embryo cooling device and the steel embryo cutting device of the steel embryo casting machine, the steel embryo cooling device delivery side, the steel embryo cutting device, the steel embryo cutting device delivery side, and the rolling line holding furnace, Any one of the induction furnace, the rolling mill, and the roller table before the furnace is maintained, after the furnace is maintained, before the induction furnace, after the induction furnace, before the rolling press, after the rolling mill, on the roller table, and between the roller tables position.
而且,於本發明之製造設備線中,可將包括與管材等對 向配置之熱電發電單元、及進行該熱電發電單元之一體移動之移動手段的熱電發電裝置備置於自加熱爐至拉伸縮管機為止之鋼板及管材之搬送路徑中之任一位置。 Moreover, in the manufacturing equipment line of the present invention, the pair of pipes and the like may be included. The thermoelectric power generation unit that arranges the thermoelectric power generation unit and the moving means for moving the one of the thermoelectric power generation units is placed at any one of the steel sheet and the pipe transport path from the heating furnace to the stretch tube machine.
即,本發明中,將熱電發電單元與上述熱源中之至少一熱源對向配置即可。 That is, in the present invention, the thermoelectric power generation unit may be disposed to face at least one of the heat sources.
又,本發明中,亦可為具有複數個熱電發電單元之熱電發電裝置,於如此般具有複數個熱電發電單元之情形時,於至少一個熱電發電單元中具有移動手段即可。 Further, in the present invention, the thermoelectric power generation device having a plurality of thermoelectric power generation units may be provided, and in the case where the plurality of thermoelectric power generation units are provided as described above, the moving means may be provided in at least one of the thermoelectric power generation units.
此處,本發明中之熱電發電裝置具有可實現上述熱電發電單元之一體移動之移動手段,可藉由該移動手段,而控制熱電發電單元與熱源之距離。距離控制較佳為使用動力缸進行。 Here, the thermoelectric generation device according to the present invention has a moving means for realizing movement of one of the thermoelectric power generation units, and the distance between the thermoelectric power generation unit and the heat source can be controlled by the moving means. The distance control is preferably performed using a power cylinder.
作為上述移動手段,如圖1及3所示,可列舉使熱電發電單元一體地上下升降移動者。又,亦可無特別問題地使用使熱電發電單元向前後左右移動者。 As the moving means, as shown in FIGS. 1 and 3, a thermoelectric power generation unit is integrally moved up and down. Further, the thermoelectric power generation unit can be used to move forward and backward and left and right without any problem.
又,上述移動手段亦可為控制如圖4所示之滑動式或如圖5所示之開閉式之移動的移動手段。再者,於溫度變動較少之處,控制距離之移動手段亦可為例如利用螺栓固定熱電發電單元、或利用滑動式之螺栓固定熱電發電單元者、且藉由鬆開該螺栓使其移動且再次將其擰緊而使熱電發電單元移動等手動移動手段。 Further, the moving means may be a moving means for controlling the sliding type as shown in FIG. 4 or the opening and closing type as shown in FIG. Further, in a place where the temperature variation is small, the moving means for controlling the distance may be, for example, a thermoelectric power generation unit fixed by bolts or a thermoelectric power generation unit fixed by a sliding bolt, and moved by loosening the bolt and The manual movement means such as moving the thermoelectric power generation unit by tightening it again.
進而,於進行如上所述之噴淋冷卻之情形時,既可使噴淋冷卻裝置本身與熱電發電單元等一體移動,亦可不使噴淋冷卻裝置本身與熱電發電單元等一體移動。 Further, in the case of the shower cooling as described above, the shower cooling device itself may be moved integrally with the thermoelectric power generation unit or the like, or the shower cooling device itself may not be moved integrally with the thermoelectric power generation unit or the like.
本發明中,為了調整熱電發電單元之距離、或使溫度計動作,亦可使用藉由熱電發電裝置轉換成之電力之一部分或全部。較 佳為包括分別預測藉由熱電發電裝置而生成之電力、及使熱電發電單元運行之消耗電力的電力預測手段,且包括基於生成電力及消耗電力而判斷是否使熱電發電單元運行之運行判斷手段。 In the present invention, in order to adjust the distance of the thermoelectric generation unit or to operate the thermometer, part or all of the electric power converted by the thermoelectric generation device may be used. More It is preferable to include a power prediction means for predicting whether or not to cause the thermoelectric power generation unit to operate based on the generated electric power and the electric power consumption, respectively, including the electric power prediction means for predicting the electric power generated by the thermoelectric generation device and the electric power consumption of the thermoelectric power generation unit.
即,於藉由對生成之電力之預測,而預測出使熱電發電單元運行之電力小於發電電力之情形時,可不使熱電發電單元動作。進而,於預測出超過熱電元件之耐熱溫度之情形時,使熱電發電單元退避,直到至少成為耐熱溫度以下。 In other words, when it is predicted that the electric power for operating the thermoelectric power generation unit is smaller than the generated electric power by predicting the generated electric power, the thermoelectric power generation unit may not be operated. Further, when it is predicted that the heat resistance temperature of the thermoelectric element is exceeded, the thermoelectric power generation unit is evacuated until it is at least the heat resistant temperature.
又,上述運行判斷手段可根據熱電發電單元之輸出,判斷是否可自發電區域向非發電區域移動。 Further, the operation determining means can determine whether or not the self-generated region can be moved to the non-power generating region based on the output of the thermoelectric power generating unit.
本發明中,熱源係利用由熱軋線中之鋼胚等之輻射、或連續鑄造線中之鋼胚之輻射、鑄造及軋壓裝置中之熱軋板等之輻射、鍛接管線中之管材等之輻射而產生之熱能。 In the present invention, the heat source utilizes radiation from a steel ore in a hot rolling line, or radiation of a steel in a continuous casting line, radiation in a hot rolling plate in a casting and rolling apparatus, a pipe in a forged line, or the like. The heat generated by the radiation.
熱軋線包括如圖6所示之加熱爐、粗軋機、精軋機、捲取機。再者,所謂熱軋步驟係指將於熱軋線之前步驟或加熱爐中加熱至1000~1200℃左右之約20~30t之鋼塊(鋼胚)利用粗軋機製成粗軋鋼條,進而利用精軋機製成板厚:1.2~25mm左右之熱軋鋼帶之步驟。再者,於本發明中,精軋機內之鋼材係指熱軋鋼帶。 The hot rolling line includes a heating furnace, a roughing mill, a finishing mill, and a coiler as shown in FIG. In addition, the hot rolling step refers to a steel block (steel blank) of about 20 to 30 tons which is heated to about 1000 to 1200 ° C in a step before the hot rolling line or in a heating furnace, and a rough rolling mill is used to make a rough rolled steel strip, and then utilized. The finishing mill is made into a plate thickness: a step of hot-rolled steel strip of about 1.2 to 25 mm. Further, in the present invention, the steel material in the finishing mill means a hot rolled steel strip.
連續鑄造裝置包括如圖7所示之盛鋼桶、餵槽、鑄模、鋼胚冷卻裝置、矯正輥等輥群及鋼胚切斷裝置。再者,圖中,21為盛鋼桶,22為餵槽,23為鑄模,24為鋼胚冷卻裝置,25為矯正輥等輥群,26為鋼胚切斷裝置,27為溫度計,28為熱電發電裝置,以及29為引錠桿台。 The continuous casting device includes a steel drum, a feeding tank, a mold, a steel embryo cooling device, a correction roller, and the like, and a steel blank cutting device as shown in FIG. Furthermore, in the figure, 21 is a steel drum, 22 is a feeding tank, 23 is a casting mold, 24 is a steel embryo cooling device, 25 is a roller group such as a correction roller, 26 is a steel blank cutting device, 27 is a thermometer, and 28 is a thermometer. The thermoelectric generation device, and 29, is a starter bar.
連續鑄造步驟係自將利用高爐製作之鋼液於經過二次精煉後放入至盛鋼桶,且搬運至連續鑄造機之最上部之時開始。然後,將鋼液自 最上部之盛鋼桶注入至餵槽。其後,鋼液自餵槽之底部被注入至鑄模,接觸於鑄模之鋼液自表面開始凝固,經過冷卻步驟而成為鋼胚。而且,進而包括切斷鋼胚之切斷步驟等。 The continuous casting step begins when the molten steel produced by the blast furnace is placed in a steel ladle after secondary refining and conveyed to the uppermost portion of the continuous casting machine. Then, the steel liquid from The uppermost steel drum is injected into the feed tank. Thereafter, the molten steel is injected into the mold from the bottom of the feed tank, and the molten steel contacting the mold starts to solidify from the surface, and becomes a steel embryo through the cooling step. Further, it further includes a cutting step of cutting the steel blank, and the like.
將鑄造及軋壓裝置示於圖8。首先,為了鑄造鋼胚,而配置包括餵槽31及鑄模32之鑄造機33,隨後配置有保持爐34、感應爐35、粗軋機36、精軋機37、水冷裝置38及捲取機39。 The casting and rolling apparatus are shown in Fig. 8. First, a casting machine 33 including a feeding tank 31 and a casting mold 32 is disposed for casting a steel slab, and then a holding furnace 34, an induction furnace 35, a roughing mill 36, a finishing mill 37, a water cooling device 38, and a coiler 39 are disposed.
配置於鑄造機之後方之保持爐可為通常之氣體燃燒爐。保持爐與感應爐之配置順序亦可替換。又,亦可使用在批量軋壓之情形時使用之加熱爐。 The holding furnace disposed after the casting machine can be a normal gas burning furnace. The order of configuration of the holding furnace and the induction furnace can also be replaced. Further, a heating furnace used in the case of batch rolling can also be used.
又,於鑄造機33與保持爐34之間,配置有剪切機40,且於粗軋機36之後方配置有剪切機41,於精軋機37之後方配置有帶狀鋼板剪切機42。 Further, a shearing machine 40 is disposed between the casting machine 33 and the holding furnace 34, and a shearing machine 41 is disposed behind the roughing mill 36, and a strip-shaped steel plate shearing machine 42 is disposed behind the finishing mill 37.
管材之生產線(鍛接管線)施行包括圖9所示之一系列步驟,將以熱軋鋼捲之形式供給之鋼板51利用加熱爐53加熱至1250℃左右後,利用成形鍛接機54將其鍛接成管狀,隨後利用熱減徑管55製成所需直徑之管材52,且利用旋轉式熱鋸17切斷成所需之長度後,利用冷床57進行冷卻,利用矯直器59進行矯正,進而,實施管端部之去角。再者,58為篩選器。 The pipe production line (forging line) is subjected to a series of steps shown in Fig. 9, and the steel sheet 51 supplied in the form of a hot rolled steel coil is heated to about 1250 ° C by the heating furnace 53, and then forged into a tubular shape by a forming forging machine 54. Then, the pipe 52 of a desired diameter is formed by the heat reducing pipe 55, and is cut into a desired length by the rotary heat saw 17, and then cooled by the cooling bed 57, corrected by the straightener 59, and further, Perform the chamfering of the end of the tube. Furthermore, 58 is a filter.
本發明中,除具有移動手段以外,亦可具有根據上述鋼胚等(包括與熱電發電單元所對向之位置及適合溫度測定之附近)之溫度(以下,簡稱為鋼胚等之溫度)及/或熱電發電單元之輸出而設置之熱電發電單元。如上述圖6所示,可藉由根據鋼胚等之溫度及/或熱電發電單元之輸出,將該熱電發電單元設置於自粗軋機前經由精軋機至熱軋鋼帶搬送路徑為止之任一位置(圖中A至E),而與實際操作中之熱源 之溫度變動等對應,進行有效率之發電。 In the present invention, in addition to the moving means, it may have a temperature (hereinafter, simply referred to as a temperature of a steel or the like) based on the steel preform or the like (including a position opposite to a position of the thermoelectric power generation unit and a temperature suitable for measurement) / or a thermoelectric power generation unit provided by the output of the thermoelectric power generation unit. As shown in FIG. 6 above, the thermoelectric power generation unit can be disposed at any position from the finish rolling mill to the hot-rolled steel strip transfer path from the rough rolling mill according to the temperature of the steel preform or the like and/or the output of the thermoelectric power generating unit. (A to E in the figure), and the heat source in actual operation According to the temperature fluctuations, etc., efficient power generation is performed.
又,本發明中,除具有移動手段以外,如圖7所示,亦可具有根據鋼胚中之任一者(包括與熱電發電單元所對向之位置及適合溫度測定之附近)之溫度(以下,簡稱為鋼胚之溫度)及/或熱電發電單元之輸出而設置之熱電發電單元。而且,可藉由根據鋼胚之溫度及/或熱電發電單元之輸出,將該熱電發電單元設置於自鋼胚冷卻裝置送出側至鋼胚切斷裝置之上游、鋼胚切斷裝置之下方及鋼胚切斷裝置送出側為止之任一位置(圖中F),而與實際操作中之熱源之溫度變動等對應,進行有效率之發電。 Further, in the present invention, in addition to the moving means, as shown in Fig. 7, it may have a temperature according to any one of the steel slabs (including the position opposite to the thermoelectric power generation unit and the vicinity of the suitable temperature measurement) ( Hereinafter, the thermoelectric power generation unit provided for the output of the thermoelectric power generation unit is simply referred to as the temperature of the steel preform. Moreover, the thermoelectric power generation unit can be disposed from the delivery side of the steel embryo cooling device to the upstream of the steel blank cutting device, below the steel blank cutting device, and according to the temperature of the steel preform and/or the output of the thermoelectric power generating unit. At any position (F in the figure) on the delivery side of the steel blank cutting device, efficient power generation is performed in accordance with the temperature fluctuation of the heat source in actual operation.
進而本發明中,除具有移動手段以外,如圖8所示,亦可具有根據鋼胚等(包括與熱電發電單元所對向之位置及適合溫度測定之附近)之溫度(以下,簡稱為鋼胚等之溫度)及/或熱電發電單元之輸出而設置之熱電發電單元。而且,可藉由根據鋼胚等之溫度及/或熱電發電單元之輸出,將該熱電發電單元設置於鋼胚鑄造機之鋼胚冷卻裝置及鋼胚切斷裝置中之鋼胚冷卻裝置送出側、鋼胚切斷裝置內及鋼胚切斷裝置送出側(圖8G)、以及軋壓線之保持爐或感應爐附近及搬送台上(圖8H)、粗軋機附近(圖8I)、精軋前之較除鏽裝置靠上游側(圖8J)、精軋機內(圖8K)及熱軋板搬送路徑上(圖8L)中之任一位置,而與實際操作中之熱源之溫度變動等對應,進行有效率之發電。 Further, in the present invention, in addition to the moving means, as shown in FIG. 8, it may have a temperature according to a steel blank or the like (including the position opposite to the thermoelectric power generation unit and the vicinity of the suitable temperature measurement) (hereinafter, simply referred to as steel). A thermoelectric power generation unit provided by the temperature of the embryo or the like and/or the output of the thermoelectric power generation unit. Further, the thermoelectric power generation unit can be disposed on the delivery side of the steel embryo cooling device in the steel embryo cooling device and the steel blank cutting device of the steel blank casting machine according to the temperature of the steel or the like and/or the output of the thermoelectric power generation unit. , in the steel blank cutting device and on the delivery side of the steel cutting device (Fig. 8G), and in the vicinity of the holding furnace or induction furnace of the rolling line and on the transfer table (Fig. 8H), near the roughing mill (Fig. 8I), and finish rolling The former rust removing device corresponds to any one of the upstream side (Fig. 8J), the finishing mill (Fig. 8K), and the hot-rolled sheet conveying path (Fig. 8L), and corresponds to the temperature change of the heat source in actual operation. , for efficient power generation.
又,本發明中,除具有如上所述之移動手段以外,亦可具有根據上述管材等之任一者(包括與熱電發電單元所對向之位置及適合溫度測定之附近)之溫度(以下,簡稱為管材等之溫度)及/或熱電發電單元之輸出而設置之熱電發電單元。如圖9所示,可藉由根據各管材等之溫度及/或熱電發電單元之輸出,將該熱電發電單元設置於自鍛 接管線之加熱爐至鍛接機為止之鋼板搬送路徑或管材搬送路徑(例如圖中M及N)中之任一位置,而與實際操作中之熱源之溫度變動等對應,進行有效率之發電。 Further, in the present invention, in addition to the above-described moving means, it may have a temperature according to any of the above-described pipes (including the position opposite to the thermoelectric power generation unit and the vicinity of the suitable temperature measurement) (hereinafter, A thermoelectric power generation unit that is simply referred to as a temperature of a pipe or the like and/or an output of a thermoelectric power generation unit. As shown in FIG. 9, the thermoelectric power generation unit can be set to self-forging by the temperature of each pipe or the like and/or the output of the thermoelectric power generation unit. Efficient power generation is performed in accordance with any of the steel plate transfer path or the pipe transfer path (for example, M and N in the figure) from the heating furnace of the pipeline to the forging machine, in accordance with the temperature fluctuation of the heat source in actual operation.
再者,本發明中之熱電發電裝置(熱電發電單元)之設置係於任一設備線中,均可亦設置於熱源之下方,而不限於熱源之上方,設置部位亦不限於1處,亦可為複數處。 Furthermore, the thermoelectric power generation device (thermoelectric power generation unit) of the present invention is disposed in any device line, and may be disposed under the heat source, and is not limited to the heat source, and the installation portion is not limited to one. Can be plural.
又,既可附有升降功能地設置於鋼胚切斷裝置之上游側,亦可設置於鋼胚切斷裝置之下方。進而,就不增加設備之構造之方面而言,較佳為亦安裝於回收調整用鋼胚之所謂引錠桿台下方。 Moreover, it may be provided on the upstream side of the steel blank cutting device with the lifting function, or may be provided below the steel blank cutting device. Further, in terms of not increasing the structure of the apparatus, it is preferably attached to the lower side of the so-called starter bar for recovering the steel for adjustment.
為維持熱電發電單元之高運行率,較佳為於靠近熱源之時間較長之場所,設置熱電發電單元。例如可列舉熱軋設備線中自加熱爐排出之鋼胚到達粗軋機為止之搬送台上(圖6A)、且除去加熱時等在表面生成之氧化皮之除鏽裝置之入料側或送出側、或進行鋼胚之寬度調整之精整壓力機附近、粗軋機附近(圖6B)、或精軋機前且粗軋鋼條相對長時間滯留之精軋前之較除鏽裝置靠上游側(圖6C)、精軋機內(圖6D)、熱軋鋼帶搬送路徑上(圖6E)等。 In order to maintain a high operating rate of the thermoelectric power generation unit, it is preferable to provide a thermoelectric power generation unit in a place where the time is close to the heat source. For example, in the hot rolling equipment line, the steel sheet discharged from the heating furnace reaches the conveying table until the rough rolling mill (Fig. 6A), and the feeding side or the sending side of the scale removing device which is formed on the surface during heating or the like is removed. Or the vicinity of the finishing press for adjusting the width of the steel blank, near the roughing mill (Fig. 6B), or before the finishing mill and before the finish rolling of the rough rolled steel strip, the upstream side of the finer removing device (Fig. 6C) ), in the finishing mill (Fig. 6D), on the hot-rolled steel strip transport path (Fig. 6E).
又,於精軋機前之將粗軋鋼條自粗軋機搬送至精軋機之期間之位置,存在利用外罩覆蓋搬送台之部位,以抑制粗軋鋼條之溫度降低。該外罩可開閉,如於抑制溫度降低之情形時關閉外罩,於不使用軋壓機之情形時打開外罩之使用方法為常用方法.。 Further, in the position where the rough rolled steel bar is conveyed from the roughing mill to the finish rolling mill before the finish rolling mill, there is a portion where the transfer table is covered by the outer cover to suppress a decrease in the temperature of the rough rolled steel strip. The outer cover can be opened and closed, such as closing the outer cover when the temperature is lowered, and the method of opening the outer cover when the rolling press is not used is a common method.
可將本發明之熱電發電單元安裝於上述外罩。 The thermoelectric power generation unit of the present invention can be attached to the above-described outer cover.
此處之粗軋鋼條之溫度為約1100℃左右,為將單側冷卻以確保發電所需之溫度差,而設置受熱手段及散熱手段,藉此,熱電單元之發電效率有效地提昇。 Here, the temperature of the rough-rolled steel bar is about 1100 ° C, and the heating means and the heat-dissipating means are provided for cooling the one side to ensure the temperature difference required for power generation, whereby the power generation efficiency of the thermoelectric unit is effectively improved.
於鋼板製造設備線中,作為靠近上述熱源之時間較長之場所,可列舉自加熱爐排出之鋼胚到達粗軋機為止之搬送台上(圖8H)、且除去加熱時等在表面生成之氧化皮之除鏽裝置(未圖示)之入料側或送出側、或進行鋼胚之寬度調整之精整壓力機附近(未圖示)、粗軋機附近(圖8I)、或精軋機前且粗軋鋼條相對長時間滯留之精軋前之較除鏽裝置靠上游側(圖8J)、精軋機內(圖8K)、熱軋板搬送路徑上(圖8L)等。 In the steel sheet manufacturing equipment line, as a place where the heat source is close to the heat source, the steel sheet discharged from the heating furnace reaches the transfer table until the rough rolling mill (Fig. 8H), and the oxidation generated on the surface during heating is removed. The vicinity of the finishing press or the delivery side of the skin descaling device (not shown), or the finishing press for adjusting the width of the steel blank (not shown), near the roughing mill (Fig. 8I), or before the finishing mill The coarse-rolled steel strip is relatively upstream of the rust removing device before the finish rolling (Fig. 8J), the finishing mill (Fig. 8K), and the hot-rolled sheet conveying path (Fig. 8L).
又,於鋼板製造設備線中,於精軋機前之將粗軋鋼條自粗軋機搬送至精軋機之期間之位置,亦存在利用外罩覆蓋搬送台之部位,以抑制粗軋鋼條之溫度降低。該外罩可開閉,如於抑制溫度降低之情形時關閉外罩,於不使用軋壓機之情形時打開外罩之使用方法為常用方法。 Further, in the steel sheet manufacturing equipment line, the portion where the rough-rolled steel strip is conveyed from the roughing mill to the finishing mill before the finishing mill also has a portion covering the conveying table by the outer cover to suppress the temperature drop of the rough-rolled steel strip. The outer cover can be opened and closed, such as closing the outer cover when the temperature is lowered, and the method of opening the outer cover when the rolling press is not used is a common method.
可將本發明之熱電發電單元安裝於上述外罩。 The thermoelectric power generation unit of the present invention can be attached to the above-described outer cover.
此處之粗軋鋼條之溫度為約1100℃左右,藉由設置用以將單側冷卻以確保發電所需之溫度差之散熱手段,而將熱電單元之發電效率有效地提昇。 Here, the temperature of the rough-rolled steel bar is about 1100 ° C, and the power generation efficiency of the thermoelectric unit is effectively improved by providing a heat-dissipating means for cooling the one side to ensure the temperature difference required for power generation.
於熱源與熱電發電裝置保持著微小之空間通過時產生電,於熱電發電裝置附近無熱源時自熱轉換為電氣之效率變差,但於此種情形時,經由電力調節器等而使其與系統電力相連,便可無問題地利用所產生之電氣。再者,於作為獨立電源使用之情形時,可與太陽光發電同樣地,使用蓄電池吸收所產生之電力之變動進行使用。 When the heat source and the thermoelectric power generation device maintain a small space, electricity is generated, and when the heat source is not in the vicinity of the thermoelectric power generation device, the efficiency of self-heating to electrical is deteriorated. However, in this case, the power conditioner or the like is used to The system is electrically connected and can be used without problems. Further, when it is used as an independent power source, it can be used in the same manner as in solar power generation, using fluctuations in power generated by battery absorption.
因於鋼胚冷卻裝置送出側至鋼胚切斷裝置之位置,始終存在作為熱源之鋼胚,故而熱電發電之輸出量變大。因此,作為熱電發電裝置之設置位置較佳。 Since the steel blank as the heat source is always present at the position from the delivery side of the steel embryo cooling device to the steel blank cutting device, the output of the thermoelectric power generation becomes large. Therefore, the installation position as the thermoelectric generation device is preferable.
另一方面,於鋼胚切斷裝置送出側,於自鋼胚切斷至下次鋼胚切斷之期間,作為熱源之鋼胚通過熱電發電單元附近之比例為間歇性,而使熱電發電輸出量減小。因此,例如較佳為以使切斷後之鋼胚搬送與連續鑄造速度為相同程度,且作為熱源之鋼胚位於熱電發電裝置附近之方式,使熱電發電輸出量增大。若將鋼胚之搬送速度設為V1,將連續鑄造速度設為V0,則滿足V1≧V0即可,更佳為成為V0≦V1≦1.1×V0之條件。若於鋼胚通過熱電發電裝置附近後,使鋼胚之搬送速度提高至先前製程程度進行搬送,則可忽視對物流之影響,同時可進行效率良好之熱電發電,因此,較佳為以此方式進行搬送。再者,本發明中,所謂熱電發電裝置附近係指以熱電發電單元自鋼胚受到之熱量計,較鋼胚切斷裝置之位置減少至90%左右之處。其原因在於若熱量未達90%,則無法進行有效率之熱電發電。 On the other hand, on the delivery side of the steel blank cutting device, during the period from the cutting of the steel embryo to the cutting of the next steel embryo, the ratio of the vicinity of the thermoelectric power generation unit to the vicinity of the thermoelectric power generation unit is intermittent, and the thermoelectric power generation output is made. The amount is reduced. Therefore, for example, it is preferable to increase the output of the thermoelectric power generation so that the steel preform after the cutting and the continuous casting speed are the same, and the steel embryo as the heat source is located in the vicinity of the thermoelectric power generator. When the conveyance speed of the steel preform is V 1 and the continuous casting speed is V 0 , it is sufficient to satisfy V 1 ≧V 0 , and more preferably, it is a condition of V 0 ≦V 1 ≦1.1×V 0 . If the steel embryo is passed through the vicinity of the thermoelectric power generation device and the steel blank transfer speed is increased to the previous process level for transportation, the influence on the flow can be neglected, and the efficient thermoelectric power generation can be performed. Therefore, it is preferable in this way. Carry out the transfer. Further, in the present invention, the vicinity of the thermoelectric power generation device means that the position of the steel preform cutting device is reduced to about 90% by the amount of heat received by the thermoelectric power generation unit from the steel embryo. The reason is that if the heat is less than 90%, efficient thermoelectric power generation cannot be performed.
又,可於熱電發電裝置之上游側設置溫度計,根據該溫度計之測定值,可控制熱電發電單元與鋼胚等之距離。藉由具有該功能,即便於製品批次之更換等於鋼胚等之溫度中產生變動等之情形時,亦可適當地對應於該溫度變動等進行熱電發電,結果,熱電發電之效率提昇。 Further, a thermometer can be provided on the upstream side of the thermoelectric generation device, and the distance between the thermoelectric generation unit and the steel embryo can be controlled based on the measured value of the thermometer. By having such a function, even when the replacement of the product lot is equal to a change in the temperature of the steel or the like, the thermoelectric power generation can be appropriately performed in accordance with the temperature fluctuation or the like, and as a result, the efficiency of the thermoelectric power generation is improved.
再者,上述溫度計較佳為放射溫度計等非接觸型,於線斷續地停止之情形時,亦可每停止一次,便使熱電耦接觸而進行測量。作為測定之頻度,理想的是將溫度計設置於線上且自動地定期進行測定,於製造條件經變更之情形時,作業者亦可以手動進行測定。 Further, the thermometer is preferably a non-contact type such as a radiation thermometer. When the line is intermittently stopped, the thermocouple may be contacted and measured every time it is stopped. As the frequency of the measurement, it is preferable that the thermometer is placed on the line and the measurement is automatically performed periodically, and when the manufacturing conditions are changed, the operator can perform the measurement manually.
而且,若預先求出熱源之溫度、與熱電發電之效率最佳之距離之關係,則可根據上述溫度計之測定值,與該溫度變動相應地適當控制例如圖1及3所示之熱電發電單元1與熱源5之距離。 Further, when the relationship between the temperature of the heat source and the optimum temperature of the thermoelectric power generation is obtained in advance, the thermoelectric power generation unit shown in, for example, FIGS. 1 and 3 can be appropriately controlled in accordance with the measured value of the thermometer. 1 The distance from the heat source 5.
進而,可根據熱電發電單元之輸出,控制熱電發電單元與熱源之距離。圖10表示於將鋼材之溫度設為850、900及950℃、且將熱電發電單元中之熱電發電模組間隔設為70mm時,對表示自鋼材至熱電發電單元之距離、與將額定輸出時之發電輸出比設為1之情形時之發電輸出比之關係之曲線圖進行調查所得之結果。 Further, the distance between the thermoelectric generation unit and the heat source can be controlled according to the output of the thermoelectric power generation unit. 10 shows the distance from the steel material to the thermoelectric power generation unit and the rated output when the temperature of the steel material is 850, 900, and 950 ° C and the interval between the thermoelectric power generation modules in the thermoelectric power generation unit is 70 mm. The result of investigating the graph of the relationship between the power generation output ratio when the power generation output ratio is set to 1.
藉由求出如上述圖10所示之關係,可根據熱電發電單元之輸出,調節鋼材與熱電發電單元之距離。本發明中,將熱源設為鋼胚等來代替上述鋼材,以熱電發電單元之輸出變大之方式調整熱電發電單元與鋼胚等之距離。此時,既可使用實際測量輸出,亦可使用根據鋼胚等之溫度等預測之輸出值。 By determining the relationship as shown in FIG. 10 described above, the distance between the steel material and the thermoelectric power generation unit can be adjusted according to the output of the thermoelectric power generation unit. In the present invention, the heat source is made of a steel or the like instead of the steel material, and the distance between the thermoelectric power generation unit and the steel or the like is adjusted so that the output of the thermoelectric power generation unit becomes large. In this case, the actual measurement output may be used, or an output value predicted based on the temperature of the steel or the like may be used.
又,於鍛接管設備線之情形時,圖11表示於將熱電發電單元中之熱電發電模組間隔及管材之溫度作為參數時,對自管材至熱電發電單元之距離、與將額定輸出時之發電輸出比設為1之情形時之發電輸出比之關係進行調查所得之結果,可藉由於管材之溫度為1150℃之情形時,使熱電發電單元與管材等之距離為150mm,又,於管材之溫度為1000℃之情形時,進行控制使之移動以使上述距離為60mm,而可進行效率最佳之熱電發電。 Moreover, in the case of forging the pipe line, FIG. 11 shows the distance from the pipe to the thermoelectric generation unit and the rated output when the thermoelectric power module interval and the temperature of the pipe in the thermoelectric power generation unit are used as parameters. When the power generation output ratio is set to 1, the relationship between the power generation output ratio and the power generation output ratio is investigated. The distance between the thermoelectric power generation unit and the pipe material is 150 mm, and the pipe material is used because the temperature of the pipe material is 1150 ° C. When the temperature is 1000 ° C, control is performed to move so that the above distance is 60 mm, and thermoelectric power generation with optimum efficiency can be performed.
藉由求出如上述圖11所示之關係,可根據熱電發電單元之輸出,調節管材與熱電發電單元之距離。本發明中,亦可將熱源設為鋼板來代替上述管材,且以熱電發電單元之輸出變大之方式調整熱電發電單元與鋼板之距離。又,於調整上述距離時,既可使用實際測量輸出,亦可使用根據管材等之溫度等預測之輸出值。 By determining the relationship as shown in FIG. 11 described above, the distance between the pipe and the thermoelectric power generation unit can be adjusted according to the output of the thermoelectric power generation unit. In the present invention, the heat source may be a steel plate instead of the pipe material, and the distance between the thermoelectric power generation unit and the steel sheet may be adjusted such that the output of the thermoelectric power generation unit becomes larger. Further, when the distance is adjusted, the actual measurement output may be used, or an output value predicted based on the temperature of the pipe or the like may be used.
如上所述,熱電發電單元之輸出較佳為以成為額定輸出之方式進行設定,必須考慮熱電發電單元之耐熱溫度上限進行設定, 以不使熱電元件受損。於考慮耐熱上限之情形時,可適當降低發電輸出比之目標,較佳為降低至0.7左右。由於輸出與溫度差之平方成正比,故而上述發電輸出比係溫度差相當於額定輸出時之溫度差之8成左右。 As described above, the output of the thermoelectric power generation unit is preferably set so as to be a rated output, and it is necessary to set the upper limit of the heat-resistant temperature of the thermoelectric power generation unit. So as not to damage the thermoelectric elements. When considering the upper limit of heat resistance, the power generation output ratio can be appropriately reduced, and it is preferably lowered to about 0.7. Since the output is proportional to the square of the temperature difference, the above-mentioned power generation output ratio temperature difference is equivalent to about 80% of the temperature difference at the rated output.
於與鋼胚等對向地設置熱電發電單元之情形時,熱源與熱電發電單元之距離並無特別限制,較佳為30~800mm左右之範圍,且較佳為以將熱電元件之高溫面側與低溫面側之溫度差維持於高位、且使輸出穩定於高位之方式進行設置。此處,使輸出穩定於高位較佳為設為上述目標輸出之0.5左右,進而較佳為設為0.7左右。由於輸出與溫度差之平方成正比,故而上述發電輸出比係溫度差分別相當於額定輸出時之溫度差之7成、8成左右。再者,即便上方部分較熱電發電單元更大地敞開,亦無問題。 In the case where the thermoelectric power generation unit is disposed opposite to the steel or the like, the distance between the heat source and the thermoelectric power generation unit is not particularly limited, and is preferably in the range of about 30 to 800 mm, and preferably the high temperature side of the thermoelectric element. The temperature difference from the low temperature surface side is maintained at a high level, and the output is stabilized at a high level. Here, it is preferable that the output is stabilized at a high level to be about 0.5 of the target output, and more preferably about 0.7. Since the output is proportional to the square of the temperature difference, the power generation output ratio temperature difference is equivalent to about 70% and 80% of the temperature difference at the rated output. Furthermore, even if the upper portion is more open than the thermoelectric power generation unit, there is no problem.
本發明中,亦可根據熱源之尺寸或品種,預先設定熱電發電單元之位置。又,亦可根據與尺寸或品種相對應之每一熱電發電單元之輸出電力實績,預先設定熱電發電單元之位置。進而,亦可根據每一熱電發電單元之輸出電力實績及/或藉由溫度等預測之輸出電力預測,與尺寸、品種相對應地預先設定熱電發電單元之設置場所。而且,於導入設備時,亦可預先決定熱電發電單元與熱源之距離、或熱電發電單元中之熱電發電模組之配置。 In the present invention, the position of the thermoelectric power generation unit may be set in advance according to the size or variety of the heat source. Further, the position of the thermoelectric power generation unit may be set in advance based on the output power performance of each thermoelectric power generation unit corresponding to the size or the size. Further, it is also possible to preset the installation location of the thermoelectric power generation unit in accordance with the size and the variety, based on the output power performance of each thermoelectric power generation unit and/or the predicted output power predicted by temperature or the like. Further, when the device is introduced, the distance between the thermoelectric power generation unit and the heat source or the arrangement of the thermoelectric power generation module in the thermoelectric power generation unit may be determined in advance.
例如若於熱軋設備中之鋼胚之尺寸為寬度:900mm,溫度為1200℃之情形時,使熱電發電單元與鋼胚之距離為720mm,又,於鋼胚之尺寸為寬度:900mm,溫度為1100℃之情形時,以使上述距離為530mm使其移動,則可進行效率最佳之熱電發電。 For example, if the size of the steel blank in the hot rolling equipment is 900 mm in width and 1200 ° C in temperature, the distance between the thermoelectric power generation unit and the steel embryo is 720 mm, and the size of the steel embryo is 900 mm in width. In the case of 1100 ° C, the thermoelectric power generation with the best efficiency can be performed by moving the above distance to 530 mm.
又,若於鋼胚之尺寸為寬度:900mm,溫度為1000℃ 之情形時,將熱電發電單元與鋼胚之距離控制為640mm,又,於鋼胚之尺寸為寬度:900mm,溫度為950℃之情形時,將上述距離控制為530mm,則可進行效率最佳之熱電發電。 Also, if the size of the steel embryo is 900mm, the temperature is 1000°C. In the case of the case, the distance between the thermoelectric power generation unit and the steel embryo is controlled to be 640 mm, and when the size of the steel embryo is 900 mm and the temperature is 950 ° C, the above distance can be controlled to 530 mm, and the efficiency can be optimized. Thermoelectric power generation.
若於熱軋設備中之熱軋鋼帶之溫度為1000℃之情形時,使熱電發電單元與熱軋鋼帶之距離為280mm,又,於熱軋鋼帶之溫度為950℃之情形時,以使上述距離為90mm使其移動,則可進行效率最佳之熱電發電。 If the temperature of the hot-rolled steel strip in the hot rolling equipment is 1000 ° C, the distance between the thermoelectric power generation unit and the hot-rolled steel strip is 280 mm, and when the temperature of the hot-rolled steel strip is 950 ° C, When the distance is 90mm to move it, the most efficient thermoelectric power generation can be performed.
又,於鋼板製造設備中之熱軋板之溫度為1000℃之情形時,使熱電發電單元與熱軋板之距離為280mm,又,於熱軋板之溫度為950℃之情形時,以使上述距離為90mm進行控制而使之移動,則可進行效率最佳之熱電發電。 Further, when the temperature of the hot-rolled sheet in the steel sheet manufacturing facility is 1000 ° C, the distance between the thermoelectric power generation unit and the hot-rolled sheet is 280 mm, and when the temperature of the hot-rolled sheet is 950 ° C, When the above distance is 90 mm and controlled to move, the most efficient thermoelectric power generation can be performed.
本發明中,如圖12所示,可將熱電發電單元設置於與除管材等以外之熱源之溫度及/或熱電發電單元之輸出相對應之距離處。其原因在於:藉由設為該設置樣態,與僅平坦地設置熱電發電單元之情形相比,可減小熱電發電單元之移動距離或次數,而可降低電力成本。 In the present invention, as shown in FIG. 12, the thermoelectric power generation unit can be disposed at a distance corresponding to the temperature of the heat source other than the pipe material and/or the output of the thermoelectric power generation unit. The reason for this is that, by setting the setting state, the moving distance or the number of times of the thermoelectric power generating unit can be reduced as compared with the case where the thermoelectric power generating unit is provided only flatly, and the power cost can be reduced.
例如若於圖12之中央部分之熱源為鋼胚或粗軋鋼條之情形時,將其與單元之距離設為720mm,且以使幅端部之距離為640mm進行控制而使之移動,又,於熱源為熱軋鋼帶之情形時,將其與單元之距離設為280mm,且以使幅端部之距離為200mm進行控制而使之移動,則可高效率地進行熱電發電。 For example, if the heat source in the central portion of FIG. 12 is a steel or rough rolled steel strip, the distance from the unit is set to 720 mm, and the distance between the ends of the web is controlled to be 640 mm, and then moved. When the heat source is a hot-rolled steel strip, the distance from the unit is set to 280 mm, and the distance between the ends of the web is controlled to be 200 mm, so that the thermoelectric power generation can be performed efficiently.
又,本發明中,於熱源為管材等之情形時,如圖13所示,可將熱電發電單元設置於與管材等之溫度及/或熱電發電單元之輸出相對應之距離處。其原因在於:藉由設為該設置樣態,與僅平坦地 設置熱電發電單元之情形相比,可減小熱電發電單元之移動距離或次數,而可降低電力成本。 Further, in the present invention, when the heat source is a pipe material or the like, as shown in FIG. 13, the thermoelectric power generation unit can be installed at a distance corresponding to the temperature of the pipe material or the output of the thermoelectric power generation unit. The reason is: by setting the setting state, and only flatly Compared with the case of setting the thermoelectric power generation unit, the moving distance or the number of times of the thermoelectric power generation unit can be reduced, and the power cost can be reduced.
例如於圖13之中央部分,於將管材更換為鋼板之鋼板搬送路徑中,若將單元與鋼板之距離控制為90mm,且於幅端部將距離控制為60mm,則可高效率地進行熱電發電。另一方面,於管材搬送路徑中,若將單元與管材之距離控制為120mm,於端部(係指管材中之溫度降低範圍)將距離控制為60mm,則可高效率地進行熱電發電。 For example, in the central portion of Fig. 13, in the steel plate transfer path in which the pipe is replaced with a steel plate, if the distance between the unit and the steel plate is controlled to be 90 mm, and the distance is controlled to 60 mm at the end portion, the thermoelectric generation can be efficiently performed. . On the other hand, in the pipe conveyance path, if the distance between the unit and the pipe is controlled to be 120 mm, and the distance (the temperature reduction range in the pipe) is controlled to be 60 mm, the thermoelectric generation can be performed efficiently.
由於鋼胚等之寬度方向(與鋼胚等之前進方向成直角之方向)之溫度於自鋼胚等或鋼板之端部測量時,於板厚~板厚之2倍左右之長度之部位(本發明中稱為幅端部)急遽降低之情況較多,故而較佳為預先控制熱電發電單元使之移動。其原因在於:於上述幅端部,相對於使熱電發電單元移動之電力而言所獲得之電力較少之結果可能性較大。 When the temperature in the width direction of the steel or the like (the direction perpendicular to the advance direction of the steel ore) is measured from the end of the steel or the steel plate, the length of the plate is about twice the thickness of the plate ( In the present invention, the term "end end portion" is often sharply lowered. Therefore, it is preferable to control the thermoelectric power generation unit to move it in advance. The reason for this is that at the above-mentioned web end portion, it is highly likely that the electric power obtained with respect to the electric power for moving the thermoelectric power generation unit is small.
根據上述熱電發電單元之輸出等進行設置之實施形態由於可將熱電發電單元設置為橢圓之一半之形狀,故而與無熱電發電單元之情形相比,由於熱流之行為變化,故而具有保溫效果優異之優點,其結果,可成為熱能之回收效率優異之熱電發電裝置。 According to the embodiment in which the output of the thermoelectric power generation unit or the like is provided, since the thermoelectric power generation unit can be formed in a shape of one half of an ellipse, the behavior of the heat flow is changed as compared with the case where the thermoelectric power generation unit is not provided, so that the heat retention effect is excellent. As a result, the thermoelectric power generation device having excellent heat energy recovery efficiency can be obtained.
再者,針對本實施形態,可藉由追加控制上述熱電發電單元與鋼胚等之距離之手段,而成為一種熱電發電裝置,從而即便於存在實際操作中之熱源之溫度變動等之情形時,亦可更高效率地進行應對。 In addition, in the present embodiment, it is possible to provide a thermoelectric power generation device by additionally controlling the distance between the thermoelectric power generation unit and the steel or the like, and even if there is a temperature change or the like of the heat source during actual operation, It can also be handled more efficiently.
本發明中之熱電發電裝置可如圖14所示般,可根據熱源之溫度、溫度分佈、形態係數及/或熱電發電單元之輸出,相對於低溫部而於高溫部使熱電發電單元中之熱電發電模組之配置密度更密。此時,較佳為以使輸出穩定於高位進行設置。此處,使輸出穩定於高 位較佳為設為上述目標輸出之0.5左右,進而較佳為設為0.7左右。由於輸出與溫度差之平方成正比,故而上述發電輸出比係溫度差分別相當於額定輸出時之溫度差之7成、8成左右。 In the thermoelectric power generation device of the present invention, as shown in FIG. 14, the thermoelectric power in the thermoelectric power generation unit can be made at a high temperature portion with respect to the low temperature portion according to the temperature, temperature distribution, form factor, and/or output of the thermoelectric power generation unit of the heat source. The power module is denser in configuration. At this time, it is preferable to set the output to be stable at a high level. Here, make the output stable to high The bit is preferably set to about 0.5 of the target output, and more preferably set to about 0.7. Since the output is proportional to the square of the temperature difference, the power generation output ratio temperature difference is equivalent to about 70% and 80% of the temperature difference at the rated output.
又,該裝置亦適合幾乎無溫度之變更之連續線。其原因在於:藉由預先測定熱源之溫度分佈及/或熱電發電單元之輸出,且反映至上述配置密度,而與僅以固定間隔設置熱電發電單元之情形相比,可使熱電發電單元之發電效率最佳化。 Moreover, the device is also suitable for continuous lines with almost no temperature changes. The reason for this is that the power generation of the thermoelectric power generation unit can be made by comparing the temperature distribution of the heat source and/or the output of the thermoelectric power generation unit to the above-described arrangement density as compared with the case where the thermoelectric power generation unit is provided only at regular intervals. Optimize efficiency.
作為變更上述配置密度之具體例,若於熱源之正上方部(中央部分)、即高溫部,將熱電發電單元中之熱電發電模組緊密地配置,且於鋼胚等之幅端部、即低溫部,將寬度方向之熱電發電單元中之熱電發電模組稀疏地配置,則可成為使各熱電發電單元之發電效率有效地提昇之熱電發電裝置。 As a specific example of changing the arrangement density, the thermoelectric power generation module in the thermoelectric power generation unit is closely arranged in the upper portion (central portion) of the heat source, that is, in the high temperature portion, and is formed at the end portion of the steel preform or the like, that is, In the low temperature portion, the thermoelectric power generation modules in the thermoelectric power generation unit in the width direction are sparsely arranged, and the thermoelectric power generation device that efficiently increases the power generation efficiency of each of the thermoelectric power generation units can be used.
例如於圖14中,若於熱源為鋼胚或粗軋鋼條之情形時,於將鋼材溫度設為1200℃,將熱電發電單元與鋼材間之距離設為640mm時,將單元中央部分之熱電發電模組之配置設為55mm間隔,幅端部設為60mm間隔,又,於熱源為熱軋鋼帶,且鋼材溫度:1000℃、熱電發電單元與鋼材間之距離:280mm之情形時,將單元中央部分之熱電發電模組之配置設為60mm間隔,幅端部設為63mm間隔,則可高效率地進行熱電發電。 For example, in FIG. 14, when the heat source is a steel or rough rolled steel bar, when the temperature of the steel material is 1200 ° C and the distance between the thermoelectric power generation unit and the steel material is 640 mm, the thermoelectric power generation in the central portion of the unit is performed. The configuration of the module is set to 55mm interval, the end of the width is set to 60mm interval, and when the heat source is hot-rolled steel strip, and the steel temperature is 1000°C, and the distance between the thermoelectric power generation unit and the steel material is 280mm, the center of the unit is used. Some of the thermoelectric power modules are arranged at intervals of 60 mm, and the end portions are set at intervals of 63 mm, so that thermoelectric power generation can be performed efficiently.
於圖14中,若於熱源為1000℃之鋼胚,鋼胚與熱電發電單元之距離為640mm之情形時,將單元中央部分之熱電發電模組之配置設為55mm間隔,幅端部設為60mm間隔,則可高效率地進行熱電發電。 In Fig. 14, if the steel source with a heat source of 1000 ° C and the distance between the steel embryo and the thermoelectric power generation unit is 640 mm, the arrangement of the thermoelectric power generation module in the central portion of the unit is set to 55 mm intervals, and the end of the width is set to At 60 mm intervals, thermoelectric power generation can be performed efficiently.
於圖14中,於熱源為鋼胚或粗軋鋼條之情形時,若將 單元中央部分之熱電發電模組之配置設為55mm間隔,幅端部設為60mm間隔,又,於熱源為熱軋板之情形時,將單元中央部分之熱電發電模組之配置設為60mm間隔,幅端部設為63mm間隔,則可高效率地進行熱電發電。 In Figure 14, when the heat source is a steel or rough rolled steel strip, The configuration of the thermoelectric power module in the central part of the unit is set to 55 mm interval, and the end of the unit is set to 60 mm. Further, when the heat source is a hot rolled plate, the configuration of the thermoelectric power module in the central portion of the unit is set to 60 mm. When the width of the end portion is set to 63 mm, thermoelectric power generation can be performed efficiently.
又,亦可將上述圖10所示之熱電發電單元中之熱電發電模組間隔作為參數,而對熱電發電單元之輸出進行調查,且將調查結果作為用以設定本發明之熱電發電模組間隔之資料而使用。 Further, the thermoelectric power generation module in the thermoelectric power generation unit shown in FIG. 10 may be used as a parameter, and the output of the thermoelectric power generation unit may be investigated, and the result of the investigation may be used as a thermoelectric power generation module interval for setting the present invention. Use for the information.
上述實施形態係既可使單元中之熱電發電模組之配置較稀或較密,亦可將單元本身設置得較稀或較密。 In the above embodiment, the configuration of the thermoelectric power generation module in the unit can be made thinner or denser, and the unit itself can be set to be thinner or denser.
於將熱源設為管材等之情形時,若於管材等之正上方部(中央部分)、即高溫部,將熱電發電單元中之熱電發電模組緊密地配置,於管材等之端部、即低溫部,將寬度方向之熱電發電單元中之熱電發電模組稀疏地配置,則可成為使各熱電發電單元之發電效率有效地提昇之熱電發電裝置。 When the heat source is used as a pipe material or the like, the thermoelectric power generation module in the thermoelectric power generation unit is closely arranged at the upper portion (central portion) of the pipe material or the like, that is, at the high temperature portion, at the end portion of the pipe material or the like, that is, In the low temperature portion, the thermoelectric power generation modules in the thermoelectric power generation unit in the width direction are sparsely arranged, and the thermoelectric power generation device that efficiently increases the power generation efficiency of each of the thermoelectric power generation units can be used.
例如於圖15中,於熱源為管材之情形時,若將單元中央部分之熱電發電模組之配置設為65mm間隔,端部設為80mm間隔,則可高效率地進行熱電發電。又,亦可將上述圖11所示之熱電發電單元中之熱電發電模組間隔作為參數,而對熱電發電單元之輸出進行調查,且將調查結果作為用以設定本發明之熱電發電模組間隔之資料而使用。 For example, in Fig. 15, when the heat source is a pipe material, thermoelectric power generation can be performed efficiently when the arrangement of the thermoelectric power modules in the central portion of the unit is 65 mm intervals and the ends are at intervals of 80 mm. Further, the thermoelectric power generation module in the thermoelectric power generation unit shown in FIG. 11 may be used as a parameter, and the output of the thermoelectric power generation unit may be investigated, and the result of the investigation may be used as a thermoelectric power generation module interval for setting the present invention. Use for the information.
上述實施形態係既可使單元中之熱電發電模組之配置較稀或較密,亦可將單元本身設置得較稀或較密。 In the above embodiment, the configuration of the thermoelectric power generation module in the unit can be made thinner or denser, and the unit itself can be set to be thinner or denser.
又,上述配置密度之變更尤其適合於鋼胚等之上方向無設備之設置容許程度之情形。再者,本實施形態亦可藉由進一步追加 控制熱電發電單元與鋼胚等之距離之手段,而即便於存在實際操作中之熱源之溫度變動等之情形時,亦一面適當地控制熱電發電單元與鋼胚等之距離,一面進一步高效率地進行發電。 Further, the above-described change in the arrangement density is particularly suitable for the case where the upper direction of the steel or the like is not allowed in the apparatus. Furthermore, this embodiment can also be further added A means for controlling the distance between the thermoelectric power generation unit and the steel or the like, and even if there is a temperature change of the heat source in actual operation or the like, the temperature of the thermoelectric power generation unit and the steel embryo are appropriately controlled, and the efficiency is further efficiently Power generation.
本發明中之根據熱電發電單元之輸出係指與熱源之溫度對應地變更位置、或變更熱電發電模組之疏密度,亦包括如下應對:於將熱電發電單元設置於初始位置時等,於存在單元間之輸出差之情形時,將輸出較小之單元移動至輸出變大之位置,具體而言,亦包含相對於熱源近接並設置之對應。又,所謂根據溫度係包括不僅以熱源之溫度為基準,而且亦以熱源之溫度分佈或形態係數為基準之情況。 The output of the thermoelectric power generation unit in the present invention means changing the position according to the temperature of the heat source or changing the density of the thermoelectric power module, and also includes the following: when the thermoelectric power generation unit is installed at the initial position, etc. In the case of a difference in output between cells, the cell with the smaller output is moved to the position where the output becomes larger, and specifically, the correspondence with the heat source is closely connected and set. Further, the temperature system includes not only the temperature of the heat source but also the temperature distribution or the shape coefficient of the heat source.
本發明中之熱電發電裝置如圖16(A)及(B)或圖17(A)及(B)所示般,可進而包括彙聚熱之熱反射材。圖中,100為熱反射材。可藉由使用熱反射材,而使對各熱電發電單元之集熱效果提昇,從而可進行效率良好之熱電發電。 The thermoelectric power generator of the present invention may further include a heat reflecting material that collects heat as shown in Figs. 16(A) and (B) or Figs. 17(A) and (B). In the figure, 100 is a heat reflective material. By using a heat reflective material, the heat collecting effect of each thermoelectric power generation unit can be improved, and efficient thermoelectric power generation can be performed.
就集熱效率之方面而言,熱反射材較佳為如圖16(A)或圖17(A)所示般設置於熱源5及熱源52之兩側(圖16(A)中,鋼胚等之前進方向係自圖式裏側朝向近前側)。 In terms of heat collecting efficiency, the heat reflecting material is preferably disposed on both sides of the heat source 5 and the heat source 52 as shown in Fig. 16 (A) or Fig. 17 (A) (Fig. 16 (A), steel embryo, etc. The forward direction is from the inner side of the drawing toward the front side).
本發明中之熱反射材之形狀可為具有平面、或曲面、又、V字或U字之截面者。再者,熱反射材可具有平面~凹面,但由於焦點中之像差因依凹面之熱反射材之入射角而變化,故而較佳為以相對於既定之入射角使像差變得最小之方式設置一熱反射材或複數個熱反射材面群,以具有最佳之熱反射材形狀(曲率)。 The shape of the heat reflective material in the present invention may be a flat surface, or a curved surface, and a V-shaped or U-shaped cross section. Furthermore, the heat reflective material may have a planar to concave surface, but since the aberration in the focus changes due to the incident angle of the concave heat reflective material, it is preferable to minimize the aberration with respect to a predetermined incident angle. In a manner, a heat reflective material or a plurality of heat reflective material surface groups are disposed to have an optimum heat reflecting material shape (curvature).
本實施形態由於可如圖16或圖17所示般將熱聚集至熱電發電單元之任意之部位,故而如下所述,有熱電發電裝置之設置容許程度進一步提昇之優點。 In the present embodiment, since heat can be collected in any part of the thermoelectric power generation unit as shown in FIG. 16 or FIG. 17, there is an advantage that the allowable degree of installation of the thermoelectric power generation device is further improved as described below.
例如藉由如圖16(A)或圖17(A)所示般,平衡性佳地將熱聚集至熱電發電單元,即便使用使熱電發電單元位於先前公知之設置位置之熱電發電裝置,亦可使各熱電發電單元之發電效率最佳化。進而,如圖16(B)或圖17(B)所示,可將彙聚至任意部位之熱能照射至熱電發電單元。本實施形態之優點在於即便於熱電發電單元之設置面積有限之情形時,或於無法獲得大面積之熱電發電單元之情形時等,亦可藉由使熱電發電單元移動,且使熱反射材100適當地移動,而進行效率良好之熱電發電。又,熱反射材100可藉由設置驅動部,且依據外部信號改變角度,而變更上述集熱部位。 For example, as shown in FIG. 16(A) or FIG. 17(A), heat is concentrated to the thermoelectric power generation unit with good balance, even if a thermoelectric power generation device that places the thermoelectric power generation unit at a previously known installation position is used. The power generation efficiency of each thermoelectric power generation unit is optimized. Further, as shown in FIG. 16(B) or FIG. 17(B), heat energy concentrated at an arbitrary portion can be irradiated to the thermoelectric power generation unit. An advantage of this embodiment is that the thermoelectric power generation unit can be moved and the heat reflective material 100 can be moved even when the installation area of the thermoelectric power generation unit is limited or when a large-area thermoelectric power generation unit cannot be obtained. Move it properly and perform efficient thermoelectric power generation. Further, the heat reflecting material 100 can be changed by setting the driving portion and changing the angle in accordance with an external signal.
因此,根據本發明中之熱源之溫度及/或熱電發電單元之輸出所設置之熱電發電單元不僅包括距離經設定之單元,而且包括可藉由如上所述之熱反射材而進行距離或角度之變更之單元。 Therefore, the thermoelectric power generating unit provided according to the temperature of the heat source and/or the output of the thermoelectric power generating unit of the present invention includes not only the distance-set unit but also the distance or angle which can be made by the heat-reflecting material as described above. The unit of change.
再者,作為本發明中之熱反射材,只要可反射熱能(紅外線),便無特別規定,考慮設置場所、物品之採購成本等,可適當選擇鏡面拋光後之鐵等金屬或於耐熱磚等實施鍍錫所得者等。 In addition, as long as the heat-reflecting material in the present invention can reflect heat energy (infrared rays), there is no particular regulation, and it is possible to appropriately select a metal such as iron after mirror polishing or a heat-resistant brick in consideration of the installation place and the procurement cost of the article. Those who have achieved tin plating and the like.
進而,熱反射材100之設置場所可考慮如上述圖16(A)及(B)或圖17(A)及(B)之熱源之兩側,亦可與熱電發電單元之設置位置相應地,設置於熱源之下部或上部。 Further, the installation place of the heat reflective material 100 may be considered on both sides of the heat source of FIGS. 16(A) and (B) or FIGS. 17(A) and (B), or may be corresponding to the installation position of the thermoelectric power generation unit. Set to the lower or upper part of the heat source.
圖18(A)及(B)或圖19(A)及(B)表示本發明之熱電發電單元之設置例。 18(A) and (B) or Figs. 19(A) and (B) show examples of installation of the thermoelectric generation unit of the present invention.
本發明中之熱電發電單元亦可如圖18(A)及(B)所示般設為包圍鋼胚等(熱源5)之外周部之形狀,或如圖19(A)及(B)所示般設為包圍管材等(熱源52)之外周部之形狀。 The thermoelectric power generation unit of the present invention may be formed to surround the outer periphery of the steel or the like (heat source 5) as shown in Figs. 18(A) and (B), or as shown in Figs. 19(A) and (B). It is generally assumed to surround the outer peripheral portion of the pipe or the like (heat source 52).
本發明中,於將熱電發電單元設置於熱源之側面或下方之情形 時,由於因來自熱源之熱所產生之對流影響,故而較佳為以將熱電發電裝置與熱源之距離:ds、與其上方之距離:du進行比較時滿足ds≦du之關係之方式進行設置。 In the present invention, the thermoelectric power generation unit is disposed on the side or below the heat source. In the case of convection due to heat from the heat source, it is preferable to set the distance between the thermoelectric power generation device and the heat source: ds and the distance from the upper side: du to satisfy the relationship of ds≦du.
因此,若圖18及19中例示之距離:a及c相當於上述距離:du,則距離:b及d相當於上述距離:ds。再者,圖中以同一記號表示之b亦可為分別不同之距離,重要的是各距離滿足上述du及ds之關係。 Therefore, if the distances illustrated in FIGS. 18 and 19: a and c correspond to the above distance: du, the distances: b and d correspond to the above distance: ds. Furthermore, b denoted by the same symbol in the figure may be different distances, and it is important that each distance satisfies the relationship of du and ds.
如此般,本發明中,尤其係於如上所述之包圍鋼胚等之外周部之熱電發電單元之情形時,即便於同一裝置內,亦可適當改變熱源與熱電發電單元之距離。 In the present invention, in particular, in the case of the thermoelectric power generation unit surrounding the outer periphery of the steel or the like as described above, the distance between the heat source and the thermoelectric power generation unit can be appropriately changed even in the same apparatus.
於未將熱電發電單元設置於整面之情形時,若以不使熱源之熱釋放至外部之方式設置板(保溫板),則可進行有效率之熱電發電。保溫板之材質只要為鐵或鎳鉻合金等金屬(合金)或陶瓷等一般用作高溫物之保溫板者,且可承受設置場所之溫度,便無特別限制,較佳為板之放射率較小,減少來自熱源之放射熱被板吸收之情況,而使來自熱源之放射熱朝向熱電發電單元。 When the thermoelectric power generation unit is not disposed on the entire surface, if the plate (insulation plate) is provided so that the heat of the heat source is not released to the outside, efficient thermoelectric power generation can be performed. The material of the heat insulating plate is not particularly limited as long as it is a metal (alloy) such as iron or a nickel-chromium alloy or a ceramic, and is generally used as a heat insulating plate for a high-temperature object, and is not particularly limited, and preferably has a higher emissivity of the plate. Small, reducing the absorption of radiant heat from the heat source by the plate, and causing the radiant heat from the heat source to face the thermoelectric power generation unit.
如圖18(A)或圖19(A)般,本發明之熱電發電裝置可至少設置一處開口部,以使用其移動手段使熱電發電裝置退避。 As shown in Fig. 18(A) or Fig. 19(A), the thermoelectric generation device of the present invention can be provided with at least one opening to evacuate the thermoelectric generation device using the moving means.
該開口部通常由熱電發電單元覆蓋,於開始操作時,使熱電發電單元自該開口部移動,而不使熱電發電裝置受損地穩定地搬送鋼胚等。再者,本實施形態亦可為使用複數個熱電發電裝置包圍熱源。 The opening is usually covered by the thermoelectric power generation unit, and when the operation is started, the thermoelectric power generation unit is moved from the opening, and the steel or the like is stably conveyed without causing damage to the thermoelectric generation device. Furthermore, in this embodiment, a plurality of thermoelectric power generators may be used to surround the heat source.
本發明中,藉由使用上述移動手段,可於鋼胚等、或熱軋板等、管材等之前端或後端等成為熱源之非穩定狀態,使包括熱電發電單元及使熱電發電單元移動之移動手段之熱電發電裝置整體自發電區域移動至退避位置,或再次移動至發電區域,以防止因鋼板之高 度變動等所導致之裝置之物理性/機械性破損。藉此,不僅可保護熱電發電單元不會因耐熱溫度而產生破損,而且可保護熱電發電裝置不會物理性/機械性地破損。 In the present invention, by using the above-described moving means, the thermoelectric power generation unit and the thermoelectric power generation unit can be moved in a non-steady state such as a steel or the like, a hot-rolled sheet, or the like, a front end or a rear end of the pipe or the like. The thermal power generation device of the moving means moves from the power generation area to the retracted position as a whole, or moves to the power generation area again to prevent the steel plate from being high. The physical/mechanical damage of the device caused by the degree of change or the like. Thereby, not only the thermoelectric power generation unit can be protected from damage due to the heat-resistant temperature, but also the thermoelectric power generation device can be protected from physical/mechanical damage.
於通板初期或通材初期等,如圖1所示,為了不使熱源碰撞至熱電發電裝置,而使其處於作為使鋼胚等移動之搬送路徑之基準而使用之旁路上升1000mm以上後之狀態。隨後,於熱源之高度變動變小時,藉由移動裝置而使熱電發電裝置為如圖3所示般靠近熱源之狀態。藉此,與先前相比,顯然可實現有效率之熱電發電。再者,於板厚相對較厚者、或連續通材且熱源之高度變動較小之情形時,使熱電發電裝置為連續靠近熱源之狀態。熱源與熱電發電裝置較佳為相隔10mm以上。 As shown in Fig. 1, in order to prevent the heat source from colliding with the thermoelectric power generator, the bypass used for the movement of the steel or the like is increased by 1000 mm or more, as shown in Fig. 1 . State. Subsequently, when the height of the heat source fluctuates, the thermoelectric power generating device is brought into a state close to the heat source as shown in Fig. 3 by moving the device. Thereby, it is apparent that efficient thermoelectric power generation can be achieved compared to the prior art. Further, in the case where the thickness is relatively thick or the continuous material is continuous and the height of the heat source fluctuates little, the thermoelectric generation device is brought into a state of being continuously close to the heat source. The heat source and the thermoelectric power generating device are preferably separated by more than 10 mm.
由於若移動距離變大,則設備費用亦增大,故而於上下移動之情形時,可移動至3000mm之遠方。較佳為退避距離為10mm至1000mm。 Since the equipment cost also increases if the moving distance becomes large, it can be moved to a distance of 3000 mm when moving up and down. Preferably, the retraction distance is from 10 mm to 1000 mm.
以上,對使熱電發電裝置於上下方向移動之例進行了說明,於橫向移動、或使其退避之情形時,如圖4所示,使用滑動式之移動手段,使其移動至退避位置。其移動距離為使熱電發電裝置整體自搬送路徑之寬度退避。例如於鋼胚鑄造機中,設為可移動3500mm左右、於製品寬度更窄之軋壓線中可移動2000mm左右之裝置。進而,於寬度較寬之厚板之軋壓線中,必須退避5m以上。又,於如管(pipe)般製品之大小較小之情形時,使其退避之移動距離為300mm左右便足夠。 As described above, the example in which the thermoelectric power generator is moved in the vertical direction has been described. When the vehicle is moved laterally or retracted, as shown in FIG. 4, the sliding type moving means is used to move to the retracted position. The moving distance is such that the entire thermoelectric power generation device is retracted from the width of the transport path. For example, in a steel blank casting machine, it is a device that can move about 3,500 mm and can move about 2000 mm in a rolling line having a narrower product width. Further, in the rolling line of the thick plate having a wide width, it is necessary to retreat by 5 m or more. Further, in the case where the size of the product such as a pipe is small, it is sufficient to make the retracting movement distance of about 300 mm.
其次,於使用如圖5所示之開閉式之移動手段之情形時,如圖所示,需要使熱電發電裝置開閉、移動至角度90°之空間,亦 可使其於90°至180°之範圍內開閉移動。由於亦存在熱電發電裝置本身之重量,故而較佳為反轉180°,而於退避時使裝置穩定。 Next, when using the opening and closing type moving means as shown in FIG. 5, as shown in the figure, it is necessary to open and close the thermoelectric power generating device and move it to a space of an angle of 90°. It can be opened and closed in the range of 90° to 180°. Since the weight of the thermoelectric power generating device itself is also present, it is preferable to reverse 180°, and the device is stabilized at the time of retraction.
亦可於熱電發電裝置之上游側及/或下游側安裝距離感測器,利用距離感測器之值,對熱電裝置之位置進行前饋及/或反饋控制。 A distance sensor may also be installed on the upstream side and/or the downstream side of the thermoelectric power generation device, and the position of the thermoelectric device may be fed forward and/or feedback controlled by the value of the distance sensor.
又,上述實施形態可分別任意地進行組合。 Further, the above embodiments can be arbitrarily combined.
例如於僅調整距離,以獲得最佳之熱電發電效率之情形時,熱電發電單元成為曲率極大之橢圓弧狀之設置時等,亦可組合使用熱反射材之實施形態等,而可緩和該曲率。 For example, when only the distance is adjusted to obtain an optimum thermoelectric power generation efficiency, the thermoelectric power generation unit may be in the form of an elliptical arc having a large curvature, or an embodiment of the heat reflective material may be used in combination, and the curvature may be alleviated. .
當然,不用說本發明亦可同時包括所有實施形態。 Of course, it is needless to say that the present invention can also include all embodiments at the same time.
本發明之熱電發電方法可以如圖6所示,於包括對鋼胚進行粗軋而製成粗軋鋼條之粗軋機、及對粗軋鋼條進行精軋而製成熱軋鋼帶之精軋機的熱軋設備線中,將包括與鋼胚、粗軋鋼條及熱軋鋼帶中之至少一者對向配置之熱電發電單元、及進行該熱電發電單元之一體移動之移動手段的熱電發電裝置設置於自粗軋機前至熱軋鋼帶搬送路徑為止之鋼胚搬送路徑、粗軋機、粗軋鋼條搬送路徑、精軋機及熱軋鋼帶搬送路徑中之任一位置。 The thermoelectric power generation method of the present invention can be as shown in FIG. 6, and includes a roughing mill that rough-rolls a steel blank to form a rough-rolled steel strip, and a hot rolling mill that performs finish rolling on the rough-rolled steel strip to form a hot-rolled steel strip. In the rolling equipment line, a thermoelectric generation unit including a thermal power generation unit disposed opposite to at least one of a steel blank, a rough-rolled steel strip, and a hot-rolled steel strip, and a moving electric device that moves the one of the thermoelectric power generation unit are disposed. Any one of the steel preform transfer path, the rough rolling mill, the rough rolling steel strip transfer path, the finishing mill, and the hot rolled steel strip transfer path from the rough rolling mill to the hot rolled steel strip transfer path.
又,本發明之熱電發電方法可以如圖7所示,於包括連續鑄造熱鋼胚之連續鑄造裝置、冷卻熱鋼胚之鋼胚冷卻裝置、及切斷熱鋼胚之熱鋼胚切斷裝置的連續鑄造設備線中,將包括與熱鋼胚對向配置之熱電發電單元、及進行該熱電發電單元之一體移動之移動手段的熱電發電裝置設置於鋼胚冷卻裝置送出側至鋼胚切斷裝置之上游、鋼胚切斷裝置之下方及鋼胚切斷裝置送出側中之任一位置。 Moreover, the thermoelectric power generation method of the present invention can be used as a continuous casting device including continuous casting of hot steel blanks, a steel embryo cooling device for cooling hot steel embryos, and a hot steel blank cutting device for cutting hot steel embryos, as shown in FIG. In the continuous casting equipment line, a thermoelectric power generation unit including a thermal steel power generation unit disposed opposite to the hot steel embryo, and a thermoelectric power generation unit that moves the one of the thermoelectric power generation unit are disposed on the steel embryo cooling device delivery side to the steel blank cutting One of the upstream of the device, the lower side of the steel blank cutting device, and the steel blank cutting device delivery side.
進而,本發明之熱電發電方法可以如圖8所示,於包括鋼胚鑄造機及軋壓線之鋼板製造設備線中,將包括與鋼胚及熱軋板中 之至少一者對向配置之熱電發電單元、及進行該熱電發電單元之一體移動之移動手段的熱電發電裝置設置於選自鋼胚鑄造機之鋼胚冷卻裝置及鋼胚切斷裝置中之鋼胚冷卻裝置送出側、鋼胚切斷裝置內及鋼胚切斷裝置送出側、以及軋壓線之保持爐、感應爐、軋壓機及滾子台中之保持爐之前、保持爐之後、感應爐之前、感應爐之後、軋壓機之前、軋壓機之後、滾子台上及滾子台間中之至少一個位置。 Further, the thermoelectric power generation method of the present invention can be included in a steel sheet and a hot rolled sheet in a steel sheet manufacturing equipment line including a steel blank casting machine and a rolling line as shown in FIG. The thermoelectric power generation unit that is disposed opposite to at least one of the thermoelectric power generation unit and the moving means for moving the thermoelectric power generation unit is disposed in a steel selected from the steel embryo cooling device and the steel blank cutting device of the steel blank casting machine The delivery side of the embryo cooling device, the steel blank cutting device and the steel blank cutting device feeding side, and the holding furnace in the rolling line holding furnace, the induction furnace, the rolling press, and the roller table, before the furnace is maintained, and the induction furnace At least one of the previous, after the induction furnace, before the rolling press, after the rolling press, on the roller table, and between the roller tables.
而且,本發明之熱電發電方法可以如圖9所示,於鍛接管設備線中,將包括與管材等中之至少一者對向配置之熱電發電單元、及進行該熱電發電單元之一體移動之移動手段之熱電發電裝置設置於自加熱爐至拉伸縮管機為止之鋼板及管材之搬送路徑中之任一位置。 Further, in the thermoelectric power generation method of the present invention, as shown in FIG. 9, in the forging pipe line, a thermoelectric power generation unit that is disposed to face at least one of a pipe material and the like, and a body of the thermoelectric power generation unit may be moved. The thermoelectric power generation device of the moving means is installed at any one of the steel plate and the pipe transport path from the heating furnace to the stretch tube machine.
又,本發明之熱電發電方法係適當選擇、或組合使用複數個如圖1、3至5、及12至19所示之形態中之任一熱電發電裝置者。即,以具有可實現熱電發電單元之一體移動之移動手段的熱電發電裝置為基本構成,進而,該熱電發電單元係可根據熱源之溫度及/或熱電發電單元之輸出而設置,或根據熱源之溫度及/或熱電發電單元之輸出,與高溫部相比於低溫部使其靠近而設置,或根據熱源之溫度及/或熱電發電單元之輸出,與低溫部相比於高溫部將熱電發電單元中之熱電發電模組緊密地配置,或包括熱反射材,或包圍熱源之外周部,或至少設置一處開口部以供熱電發電裝置退避。 Further, in the thermoelectric generation method of the present invention, any one of the thermoelectric power generators of any of the forms shown in Figs. 1, 3 to 5, and 12 to 19 is appropriately selected or used in combination. That is, the thermoelectric power generation device having a moving means capable of realizing movement of one of the thermoelectric power generation units is basically configured, and the thermoelectric power generation unit can be provided according to the temperature of the heat source and/or the output of the thermoelectric power generation unit, or according to the heat source. The temperature and/or the output of the thermoelectric power generation unit is set closer to the low temperature portion than the high temperature portion, or the thermoelectric power generation unit is compared with the low temperature portion and the high temperature portion according to the temperature of the heat source and/or the output of the thermoelectric power generation unit. The thermoelectric power generation module is closely arranged, or includes a heat reflective material, or surrounds the periphery of the heat source, or at least one opening is provided for the thermoelectric power generation device to retreat.
再者,於實施時,亦可併用上述複數個實施形態之熱電發電裝置。 Further, in the implementation, the thermoelectric power generator of the above-described plural embodiments may be used in combination.
為了確認本發明之熱電發電裝置之效果,而使用為圖2所示之構成、且具有1m2之面積之熱電發電單元,將熱電發電單元設置於圖6之C之位置,而實施確認各熱電發電單元之輸出之試驗。 In order to confirm the effect of the thermoelectric power generator of the present invention, a thermoelectric power generation unit having a configuration of FIG. 2 and having an area of 1 m 2 was used, and the thermoelectric power generation unit was placed at the position of C in FIG. Test of the output of the power generation unit.
發明例1係實施如下試驗:於粗軋鋼條之通板開始時,將熱電發電裝置與粗軋鋼條之距離設為3000mm,於粗軋鋼條前端通過後,使熱電發電裝置移動,而將其與粗軋鋼條之距離控制為720mm。再者,使用粗軋鋼條溫度於寬度方向中央為約1200℃、幅端部(表示自粗軋鋼條之幅端面起算於寬度方向約80mm以內之範圍,以下,稱為幅端部A之情形係指相同之範圍)溫度為1100℃、且寬度:900mm、厚度:40mm之粗軋鋼條。 In the first invention, the following test was carried out: when the through-plate of the rough-rolled steel strip was started, the distance between the thermoelectric power generator and the rough-rolled steel strip was set to 3000 mm, and after the front end of the rough-rolled steel strip was passed, the thermoelectric generation device was moved, and the thermoelectric power generation device was moved. The distance of the rough rolled steel bar is controlled to be 720 mm. Further, the temperature of the rough-rolled steel strip is about 1200 ° C in the center in the width direction, and the end portion of the web (indicating that the end face of the rough-rolled steel strip is within a range of about 80 mm in the width direction, hereinafter referred to as the end portion A) Refers to the same range) rough rolled steel bars with a temperature of 1100 ° C and a width of 900 mm and a thickness of 40 mm.
其結果,相對於額定輸出而獲得75%之輸出。又,幅端為62%之輸出。 As a result, an output of 75% is obtained with respect to the rated output. Also, the output is 62% of the output.
發明例2係於粗軋鋼條之通板開始時,將熱電發電裝置與粗軋鋼條之距離設為3000mm,於粗軋鋼條前端通過後,使熱電發電裝置移動。實施將熱電發電裝置與粗軋鋼條之距離控制為720mm之試驗。再者,使用粗軋鋼條溫度遍及寬度方向整體為約1200℃、且寬度:900mm、厚度:40mm之粗軋鋼條。 In the second example of the invention, when the through-plate of the rough-rolled steel strip is started, the distance between the thermoelectric power generator and the rough-rolled steel strip is set to 3000 mm, and after the leading end of the rough-rolled steel strip passes, the thermoelectric generation device is moved. A test was conducted to control the distance between the thermoelectric power generating device and the rough rolled steel bar to 720 mm. Further, a rough rolled steel bar having a temperature of the rough rolled steel bar of about 1200 ° C in the width direction and a width of 900 mm and a thickness of 40 mm was used.
其結果,相對於額定輸出,寬度方向大致成為如額定輸出般之發電,但於幅端部A為83%之輸出。 As a result, the width direction is approximately equal to the rated output with respect to the rated output, but the output is 83% at the end portion A.
發明例3係實施如下試驗:使熱電發電單元為圖12所示之構成,於中央部分,將熱電發電單元與鋼胚之距離控制為720mm,於幅端部A將該距離控制為640mm。再者,粗軋鋼條係使用與上述發明例2大小相同且溫度分佈相同者。 In the inventive example 3, the thermoelectric power generation unit was configured as shown in Fig. 12, and the distance between the thermoelectric power generation unit and the steel embryo was controlled to 720 mm in the center portion, and the distance was controlled to 640 mm at the web end portion A. Further, the rough-rolled steel strip was used in the same manner as in the above-described Invention Example 2, and the temperature distribution was the same.
其結果,於寬度方向整體大致獲得額定輸出。 As a result, the rated output is substantially obtained as a whole in the width direction.
發明例4係實施如下試驗:使熱電發電單元為圖14所示之構成,將熱電發電單元中之熱電發電模組於中央部分配置為55mm間隔,於幅端部A配置為60mm間隔,且將單元與鋼胚之距離控制為640mm。再者,粗軋鋼條係使用與上述發明例2大小相同且溫度分佈相同者。 In the fourth invention, the thermoelectric power generation unit is configured as shown in FIG. 14 , and the thermoelectric power generation module in the thermoelectric power generation unit is disposed at a central portion of 55 mm intervals, and at the web end portion A at intervals of 60 mm, and The distance between the unit and the steel embryo is controlled to be 640 mm. Further, the rough-rolled steel strip was used in the same manner as in the above-described Invention Example 2, and the temperature distribution was the same.
其結果,於寬度方向大致獲得額定輸出。 As a result, the rated output is roughly obtained in the width direction.
發明例5係實施如下試驗:使熱電發電單元及熱源之外周為圖16(A)所示之構成,且配置將熱彙聚至熱電發電單元之熱反射材。再者,粗軋鋼條係使用與上述發明例2大小相同且溫度分佈相同者。 Inventive Example 5 was carried out by conducting a test in which the thermoelectric power generation unit and the heat source were arranged as shown in Fig. 16(A), and a heat reflecting material that condensed heat to the thermoelectric power generation unit was disposed. Further, the rough-rolled steel strip was used in the same manner as in the above-described Invention Example 2, and the temperature distribution was the same.
其結果,熱電發電單元可大致獲得額定輸出。 As a result, the thermoelectric power generation unit can roughly obtain the rated output.
發明例6係實施如下試驗:進而以包圍粗軋鋼條之外周部設置具有4個熱電發電單元之熱電發電裝置。再者,粗軋鋼條係使用與上述發明例2大小相同且溫度分佈相同者。 Inventive Example 6 was carried out by conducting a test in which a thermoelectric power generator having four thermoelectric power generation units was provided around the outer periphery of the rough rolled steel strip. Further, the rough-rolled steel strip was used in the same manner as in the above-described Invention Example 2, and the temperature distribution was the same.
其結果,熱電發電單元之數量增加,與發明例4相比亦可獲得其2.2倍之輸出。 As a result, the number of thermoelectric power generation units increased, and the output of 2.2 times was obtained as compared with Inventive Example 4.
發明例7係實施如下控制:僅使粗軋鋼條上方之熱電發電單元可移動,且設置如圖18(A)所示之開口部。 Inventive Example 7 is controlled by moving only the thermoelectric power generation unit above the rough rolled steel strip and providing an opening as shown in Fig. 18(A).
即,實施如下試驗:於粗軋鋼條之通板開始時,將上方設為開口部,於穩定通板後使上方之熱電發電裝置靠近粗軋鋼條。再者,粗軋鋼條係使用與上述發明例2大小相同且溫度分佈相同者。 That is, the following test was carried out: when the through-plate of the rough-rolled steel strip was started, the upper portion was set as an opening portion, and after the plate was stabilized, the upper thermoelectric power generator was brought close to the rough-rolled steel strip. Further, the rough-rolled steel strip was used in the same manner as in the above-described Invention Example 2, and the temperature distribution was the same.
其結果,可獲得額定輸出,並且由於其他熱電發電單元不可動,故而可減低使該熱電發電單元可動時所需之操作成本。 As a result, the rated output can be obtained, and since other thermoelectric power generating units are not movable, the operation cost required to make the thermoelectric power generating unit movable can be reduced.
比較例1係使用與上述發明例1相同之熱電發電單元, 且將熱電發電單元設置於與上述發明例1相同之場所。於該設置時,將熱電發電裝置與粗軋鋼條之距離設為3000mm,以不使熱電發電裝置受損,而進行試驗。再者,粗軋鋼條係使用與上述發明例2大小相同且溫度分佈相同者。 In Comparative Example 1, the same thermoelectric power generation unit as in the above-described Invention Example 1 was used. Further, the thermoelectric power generation unit was placed in the same place as in the first invention example described above. At the time of this setting, the distance between the thermoelectric power generator and the rough rolled steel bar was set to 3000 mm, and the test was performed without damaging the thermoelectric power generator. Further, the rough-rolled steel strip was used in the same manner as in the above-described Invention Example 2, and the temperature distribution was the same.
其結果,僅可獲得額定輸出之1%左右之輸出。 As a result, only an output of about 1% of the rated output can be obtained.
根據上述發明例1~7及比較例1之結果,可確認到使用有本發明之熱軋設備線之優異之發電效果。再者,以上實施例1係使用粗軋鋼條之上方之附有移動手段之熱軋設備線,根據粗軋鋼條之溫度或設置場所附近之溫度,變更熱電發電單元之設置場所等,但確認到即便根據鋼胚及熱軋鋼帶之溫度、或熱電發電單元之輸出,變更設置場所或設置形態等,只要按照本發明,亦可獲得相同之結果。 According to the results of the above-described Invention Examples 1 to 7 and Comparative Example 1, it was confirmed that the excellent power generation effect using the hot rolling equipment line of the present invention was obtained. Further, in the first embodiment, the hot rolling equipment line with the moving means above the rough rolled steel strip is used, and the setting place of the thermoelectric power generation unit is changed according to the temperature of the rough rolled steel strip or the temperature in the vicinity of the installation place, but it is confirmed. Even if the temperature of the steel blank and the hot-rolled steel strip or the output of the thermoelectric power generation unit is changed, the installation place, the installation form, and the like are changed, and the same result can be obtained according to the present invention.
為了確認本發明之熱電發電裝置之效果,而使用為圖2所示之構成、且具有1m2之面積之熱電發電單元,將熱電發電單元設置於圖7之F之位置,而實施確認各熱電發電單元之輸出之試驗。 In order to confirm the effect of the thermoelectric power generator of the present invention, a thermoelectric power generation unit having a configuration of FIG. 2 and having an area of 1 m 2 was used, and the thermoelectric power generation unit was placed at the position of F in FIG. Test of the output of the power generation unit.
發明例8係實施如下試驗:於熱鋼胚之通材開始時,將熱電發電裝置與熱鋼胚之距離設為3000mm,於熱鋼胚前端通過後,使熱電發電裝置移動,而將其與熱鋼胚之距離控制為720mm。再者,使用熱鋼胚溫度於寬度方向中央為約1000℃、幅端部(表示自熱鋼胚之幅端面起算於寬度方向約80mm以內之範圍,以下,稱為幅端部B之情形係指相同之範圍)溫度為950℃、且寬度:900mm、厚度:250mm之熱鋼胚。 Inventive Example 8 is a test in which the distance between the thermoelectric power generator and the hot steel billet is set to 3000 mm at the start of the hot steel preform, and the thermoelectric power generating device is moved after passing through the front end of the hot steel billet, and the thermoelectric power generating device is moved. The distance of the hot steel embryo is controlled to be 720 mm. Further, the temperature of the hot steel is about 1000 ° C in the center in the width direction, and the end portion of the width (indicating that the end face of the hot steel billet is within a range of about 80 mm in the width direction, and hereinafter referred to as the end portion B) Refers to the same range of hot steel embryos with a temperature of 950 ° C and a width of 900 mm and a thickness of 250 mm.
其結果,相對於額定輸出而獲得75%之輸出。又,幅端為62%之 輸出。 As a result, an output of 75% is obtained with respect to the rated output. Also, the end is 62% Output.
發明例9係使用與發明例8相同之熱電發電單元,於熱鋼胚之通材開始時,將熱電發電裝置與熱鋼胚之距離設為3000mm,於熱鋼胚前端通過後,使熱電發電裝置移動。實施將熱電發電裝置與熱鋼胚之距離控制為640mm之試驗。再者,使用熱鋼胚溫度遍及寬度方向整體為約1000℃、且寬度:900mm、厚度:250mm之熱鋼胚。 In the ninth aspect of the invention, the thermoelectric power generation unit similar to that of the eighth invention is used. When the hot steel preform is started, the distance between the thermoelectric power generator and the hot steel billet is set to 3000 mm, and the thermoelectric power generation is performed after the hot steel embryo is passed through the front end. The device moves. A test was conducted to control the distance between the thermoelectric power generation device and the hot steel embryo to 640 mm. Further, a hot steel embryo having a hot steel billet temperature of about 1000 ° C and a width of 900 mm and a thickness of 250 mm was used throughout the width direction.
其結果,相對於額定輸出,寬度方向大致成為如額定輸出般之發電,但於幅端部B為83%之輸出。 As a result, the width direction is approximately equal to the rated output with respect to the rated output, but the output is 83% at the end portion B.
發明例10係實施如下試驗:使熱電發電單元為圖12所示之構成,於中央部分,將熱電發電單元與鋼胚之距離控制為640mm,於幅端部B將該距離控制為530mm。再者,熱鋼胚係使用與上述發明例9大小相同且溫度分佈相同者。 Inventive Example 10 was carried out by the following test: The thermoelectric power generation unit was constructed as shown in Fig. 12, and the distance between the thermoelectric power generation unit and the steel preform was controlled to 640 mm in the center portion, and the distance was controlled to 530 mm at the end portion B. Further, the hot steel embryo system was the same size as the above-described Invention Example 9 and had the same temperature distribution.
其結果,於寬度方向整體大致獲得額定輸出。 As a result, the rated output is substantially obtained as a whole in the width direction.
發明例11係實施如下試驗:使熱電發電單元為圖14所示之構成,將熱電發電單元中之熱電發電模組於中央部分配置為55mm間隔,於幅端部B配置為60mm間隔,且將單元與鋼胚之距離控制為640mm。再者,熱鋼胚係使用與上述發明例9大小相同且溫度分佈相同者。 In the eleventh invention, the thermoelectric power generation unit is configured as shown in FIG. 14 , and the thermoelectric power generation module in the thermoelectric power generation unit is disposed at a central portion of 55 mm intervals, and at the web end portion B at a spacing of 60 mm, and The distance between the unit and the steel embryo is controlled to be 640 mm. Further, the hot steel embryo system was the same size as the above-described Invention Example 9 and had the same temperature distribution.
其結果,於寬度方向大致獲得額定輸出。 As a result, the rated output is roughly obtained in the width direction.
發明例12係實施如下試驗:使熱電發電單元及其外周為圖16(A)所示之構成,且配置將熱彙聚至熱電發電單元之熱反射材。再者,熱鋼胚係使用與上述發明例2大小相同且溫度分佈相同者。 In the invention example 12, the thermoelectric power generation unit and its outer periphery were configured as shown in Fig. 16(A), and the heat reflective material that condensed heat to the thermoelectric power generation unit was disposed. Further, the hot steel embryo system was the same size as the above-described Invention Example 2 and had the same temperature distribution.
其結果,熱電發電單元可大致獲得額定輸出。 As a result, the thermoelectric power generation unit can roughly obtain the rated output.
發明例13係實施如下試驗:進而以包圍熱鋼胚之外周 部設置具有4個熱電發電單元之熱電發電裝置。再者,熱鋼胚係使用與上述發明例2大小相同且溫度分佈相同者。 Inventive Example 13 was carried out by the following test: further to surround the outer periphery of the hot steel embryo A thermoelectric power generation device having four thermoelectric power generation units is provided. Further, the hot steel embryo system was the same size as the above-described Invention Example 2 and had the same temperature distribution.
其結果,熱電發電單元之數量增加,與發明例11相比亦可獲得其2.2倍之輸出。 As a result, the number of thermoelectric power generation units increased, and 2.2 times of the output was obtained as compared with Inventive Example 11.
發明例14係進行如下運行操作:僅使熱鋼胚上方之熱電發電單元可移動,且設置如圖18(A)所示之開口部。 Inventive Example 14 was carried out by operating only the thermoelectric power generation unit above the hot steel preform and providing an opening as shown in Fig. 18(A).
即,實施如下試驗:於熱鋼胚之通材開始時,將上方設為開口部,於穩定通材後使上方之熱電發電裝置靠近熱鋼胚。再者,熱鋼胚係使用與上述發明例2大小相同且溫度分佈相同者。 That is, the test was carried out in that the upper portion was set as an opening at the start of the hot steel preform, and the upper thermoelectric power generator was brought close to the hot steel after the material was stabilized. Further, the hot steel embryo system was the same size as the above-described Invention Example 2 and had the same temperature distribution.
其結果,可獲得額定輸出,並且由於其他熱電發電單元不可動,故而可減低使該熱電發電單元可動時所需之操作成本。 As a result, the rated output can be obtained, and since other thermoelectric power generating units are not movable, the operation cost required to make the thermoelectric power generating unit movable can be reduced.
比較例2係使用與上述發明例8相同之熱電發電單元,且將熱電發電單元設置於與上述發明例8相同之場所。但是,於設置該熱電發電裝置時,將熱電發電裝置與熱鋼胚之距離設為3000mm,以不使熱電發電裝置受損,而進行試驗。再者,熱鋼胚係使用與上述發明例2大小相同且溫度分佈相同者。 In Comparative Example 2, the same thermoelectric power generation unit as that of the above-described Invention Example 8 was used, and the thermoelectric power generation unit was placed in the same place as the above-described Invention Example 8. However, when the thermoelectric power generator was installed, the distance between the thermoelectric power generator and the hot steel billet was set to 3000 mm, and the test was performed without damaging the thermoelectric power generator. Further, the hot steel embryo system was the same size as the above-described Invention Example 2 and had the same temperature distribution.
其結果,僅可獲得額定輸出之1%左右之輸出。 As a result, only an output of about 1% of the rated output can be obtained.
根據上述發明例8~14及比較例2之結果,確認到使用有本發明之連續鑄造設備線之優異之發電效果。再者,以上實施例2係使用熱鋼胚之上方之附有移動手段之連續鑄造設備線,雖根據熱鋼胚之溫度或設置場所附近之溫度,變更熱電發電單元之設置場所等,但確認到即便根據熱電發電單元之輸出,變更設置場所或設置形態等,只要按照本發明,亦可獲得相同之結果。 According to the results of the above-described Invention Examples 8 to 14 and Comparative Example 2, it was confirmed that the power generation effect of the continuous casting equipment line of the present invention was excellent. Further, in the second embodiment, the continuous casting equipment line with the moving means above the hot steel blank is used, and the setting place of the thermoelectric power generation unit is changed depending on the temperature of the hot steel blank or the temperature in the vicinity of the installation place, but it is confirmed. Even if the installation place, the installation form, and the like are changed according to the output of the thermoelectric power generation unit, the same result can be obtained according to the present invention.
為了確認本發明之熱電發電裝置之效果,而使用如圖2所示之構成、且具有1m2之面積之熱電發電單元,將熱電發電單元設置於圖8之G之位置,而實施確認各熱電發電單元之輸出之試驗。 In order to confirm the effect of the thermoelectric power generator of the present invention, a thermoelectric power generation unit having a configuration of 1 m 2 as shown in FIG. 2 was used, and the thermoelectric power generation unit was placed at the position G of FIG. Test of the output of the power generation unit.
發明例15係實施如下試驗:於鋼胚之通板開始時,將熱電發電裝置與鋼胚之距離設為3000mm,於鋼胚前端通過後,使熱電發電裝置移動,而將其與鋼胚之距離控制為720mm。再者,使用鋼胚溫度(本實施例中簡稱為鋼胚溫度之情形係指鋼胚之中央部分之溫度)於寬度方向中央為約1200℃、幅端部(表示自鋼胚之幅端面起算於寬度方向約80mm以內之範圍,以下,稱為幅端部C之情形係指相同之範圍)溫度為1100℃、且寬度:900mm、厚度:40mm之鋼胚。 Inventive Example 15 is a test in which the distance between the thermoelectric generation device and the steel embryo is set to 3000 mm at the start of the passage of the steel blank, and after passing through the front end of the steel embryo, the thermoelectric generation device is moved to be combined with the steel embryo. The distance control is 720mm. Further, the use of the steel embryo temperature (in the present embodiment, simply referred to as the temperature of the steel blank refers to the temperature of the central portion of the steel blank) is about 1200 ° C in the center in the width direction, and the end portion of the web (indicating from the end face of the steel blank) The range of about 80 mm in the width direction, hereinafter referred to as the end portion C, refers to the same range of steel embryos having a temperature of 1,100 ° C and a width of 900 mm and a thickness of 40 mm.
其結果,相對於額定輸出,而於寬度方向中央獲得75%之輸出。又,幅端部C為62%之輸出。 As a result, 75% of the output is obtained in the center in the width direction with respect to the rated output. Also, the end portion C is 62% of the output.
發明例16係於鋼胚之通板開始時,將熱電發電裝置與鋼胚之距離設為3000mm,於鋼胚前端通過後,使熱電發電裝置移動。實施將熱電發電裝置與鋼胚之距離控制為720mm之試驗。再者,使用鋼胚溫度遍及寬度方向整體為約1200℃、且寬度:900mm、厚度:40mm之鋼胚。 In the invention example 16, when the steel sheet is started, the distance between the thermoelectric power generator and the steel embryo is set to 3000 mm, and after passing through the front end of the steel preform, the thermoelectric power generator is moved. A test was conducted to control the distance between the thermoelectric generation device and the steel embryo to 720 mm. Further, a steel blank having a steel preform temperature of about 1200 ° C and a width of 900 mm and a thickness of 40 mm was used throughout the width direction.
其結果,相對於額定輸出,寬度方向中央大致成為如額定輸出般之發電,但於幅端部C為83%之輸出。 As a result, the center in the width direction is approximately the same as the rated output with respect to the rated output, but the output is 83% at the end portion C.
發明例17係實施如下試驗:使熱電發電單元為圖12所示之構成,於中央部分,將熱電發電單元與鋼胚之距離控制為720mm,於幅端部C將該距離控制為640mm。再者,鋼胚係使用與上述發明例16大小相同且溫度分佈相同者。 Inventive Example 17 was carried out by the following test: The thermoelectric power generation unit was constructed as shown in Fig. 12, and the distance between the thermoelectric power generation unit and the steel preform was controlled to 720 mm in the center portion, and the distance was controlled to 640 mm at the end portion C. Further, the steel blank system was the same size as the above-described Invention Example 16 and had the same temperature distribution.
其結果,於寬度方向整體大致獲得額定輸出。 As a result, the rated output is substantially obtained as a whole in the width direction.
發明例18係實施如下試驗:使熱電發電單元為圖14所示之構成,將熱電發電單元中之熱電發電模組於中央部分配置為55mm間隔,於幅端C配置為60mm間隔,且將單元與鋼胚之距離控制為640mm。再者,鋼胚係使用與上述發明例16大小相同且溫度分佈相同者。 Inventive Example 18 is a test in which the thermoelectric power generation unit has the configuration shown in Fig. 14, and the thermoelectric power generation module in the thermoelectric power generation unit is disposed at a central portion of 55 mm intervals, and at the end portion C at a spacing of 60 mm, and the unit is placed. The distance from the steel embryo is controlled to be 640 mm. Further, the steel blank system was the same size as the above-described Invention Example 16 and had the same temperature distribution.
其結果,於寬度方向大致獲得額定輸出。 As a result, the rated output is roughly obtained in the width direction.
發明例19係實施如下試驗:使熱電發電單元及熱源之外周為圖16(A)所示之構成,且配置將熱彙聚至熱電發電單元之熱反射材。再者,鋼胚係使用與上述實施例16大小相同且溫度分佈相同者。 Inventive Example 19 was carried out by conducting a test in which the thermoelectric power generation unit and the heat source were arranged as shown in Fig. 16(A), and a heat reflecting material that condensed heat to the thermoelectric power generation unit was disposed. Further, the steel germ system was the same size as the above-described Example 16 and the temperature distribution was the same.
其結果,熱電發電單元可大致獲得額定輸出。 As a result, the thermoelectric power generation unit can roughly obtain the rated output.
發明例20係實施如下試驗:進而以包圍鋼胚之外周部之方式設置具有4個熱電發電單元之熱電發電裝置。再者,鋼胚係使用與上述發明例16大小相同且溫度分佈相同者。 In Inventive Example 20, the following test was carried out: Further, a thermoelectric power generator having four thermoelectric power generation units was provided so as to surround the outer peripheral portion of the steel slab. Further, the steel blank system was the same size as the above-described Invention Example 16 and had the same temperature distribution.
其結果,熱電發電單元之數量增加,與發明例18相比亦可獲得其2.2倍之輸出。 As a result, the number of thermoelectric power generation units increased, and 2.2 times of the output was obtained as compared with Inventive Example 18.
發明例21係實施如下控制:僅使鋼胚上方之熱電發電單元可移動,且設置如圖18(A)所示之開口部。 Inventive Example 21 is controlled such that only the thermoelectric power generation unit above the steel blank is movable, and an opening portion as shown in Fig. 18(A) is provided.
即,實施如下試驗:於鋼胚之通板開始時,預先使熱電發電單元自上方之開口部退避,於穩定通板後,使上方之熱電發電裝置靠近鋼胚。再者,鋼胚係使用與上述發明例16大小相同且溫度分佈相同者。 That is, the test was carried out in such a manner that the thermoelectric power generation unit was previously evacuated from the upper opening portion at the start of the passage of the steel blank, and the upper thermoelectric power generation device was brought close to the steel embryo after the plate was stabilized. Further, the steel blank system was the same size as the above-described Invention Example 16 and had the same temperature distribution.
其結果,可獲得額定輸出,並且由於不使其他熱電發電單元運行,故而可減低使該熱電發電單元運行時所需之操作成本。 As a result, the rated output can be obtained, and since other thermoelectric generation units are not operated, the operation cost required to operate the thermoelectric generation unit can be reduced.
比較例3係使用與上述發明例15相同之熱電發電單 元,且將熱電發電單元設置於與上述發明例15相同之場所。於該設置時,將熱電發電裝置與鋼胚之距離設為3000mm,以不使熱電發電裝置受損,而進行試驗。再者,鋼胚係使用與上述發明例16大小相同且溫度分佈相同者。 In Comparative Example 3, the same thermoelectric power generation list as in the above-described inventive example 15 was used. The thermoelectric power generation unit was placed in the same place as the above-described inventive example 15. At the time of this setting, the distance between the thermoelectric generation device and the steel embryo was set to 3000 mm, and the test was performed without damaging the thermoelectric generation device. Further, the steel blank system was the same size as the above-described Invention Example 16 and had the same temperature distribution.
其結果,僅可獲得額定輸出之1%左右之輸出。 As a result, only an output of about 1% of the rated output can be obtained.
比較例4進行於鋼胚之通板開始時不使熱電發電單元退避之試驗。其結果,於鋼胚之通板開始時,鋼胚接觸於熱電發電單元,而使熱電發電裝置破損。 In Comparative Example 4, a test was conducted in which the thermoelectric power generation unit was not evacuated at the start of the passage of the steel blank. As a result, at the beginning of the passage of the steel blank, the steel embryo contacts the thermoelectric power generation unit, and the thermoelectric power generation device is broken.
根據上述發明例15~21以及比較例3及4之結果,可確認到本發明之進行鑄造及軋壓之鋼板製造設備線之優異之發電效果。再者,以上實施例3係使用鋼胚之上方之附有移動手段之進行鑄造及軋壓之鋼板製造設備線,根據鋼胚之溫度或設置場所附近之溫度,雖變更熱電發電單元之設置場所等,但確認到即便根據熱軋板及熱軋鋼帶等之溫度、或熱電發電單元之輸出,變更設置場所或設置形態等,只要按照本發明,亦可獲得相同之結果。 According to the results of the above-described Invention Examples 15 to 21 and Comparative Examples 3 and 4, it was confirmed that the power generation effect of the steel sheet manufacturing equipment line for casting and rolling of the present invention was excellent. Further, in the above-described third embodiment, the steel sheet manufacturing equipment line for casting and rolling with the moving means above the steel blank is used, and the setting place of the thermoelectric power generation unit is changed depending on the temperature of the steel preform or the temperature in the vicinity of the installation place. In addition, it has been confirmed that the same result can be obtained according to the present invention even if the temperature of the hot-rolled steel sheet, the hot-rolled steel strip, or the like, or the output of the thermoelectric power generation unit is changed, and the installation place or the installation form is changed.
為了確認本發明之熱電發電裝置之效果,而使用為圖2所示之構成、且具有1m2之面積之熱電發電單元,將熱電發電單元設置於圖9之N之位置,而實施確認各熱電發電單元之輸出之試驗。 In order to confirm the effect of the thermoelectric power generator of the present invention, a thermoelectric power generation unit having a configuration of FIG. 2 and having an area of 1 m 2 was used, and the thermoelectric power generation unit was placed at the position of N in FIG. Test of the output of the power generation unit.
發明例22係實施如下試驗:於管材之通材開始時,將熱電發電裝置與管材之距離設為3000mm,於管材前端通過後,使熱電發電裝置移動,而將其與管材之距離控制為155mm。再者,使用管材溫度為約1200℃、且外徑:120mm之管材。 In the invention example 22, the distance between the thermoelectric power generation device and the pipe material was set to 3000 mm at the start of the pipe material, and the thermoelectric power generation device was moved after the pipe end was passed, and the distance from the pipe material was controlled to 155 mm. . Further, a pipe having a pipe temperature of about 1200 ° C and an outer diameter of 120 mm was used.
其結果,相對於額定輸出而獲得75%之輸出。又,端部為62%之輸出。 As a result, an output of 75% is obtained with respect to the rated output. Also, the end is 62% of the output.
發明例23係使用與發明例22相同之熱電發電單元,於管材之通材開始時,將熱電發電裝置與管材之距離設為3000mm,於管材前端通過後,使熱電發電裝置移動。實施將熱電發電裝置與管材之距離控制為125mm之試驗。再者,使用管材溫度遍及寬度方向整體為約1200℃、且外徑:120mm之管材。 In the invention example 23, the thermoelectric power generation unit similar to the invention example 22 was used. When the material of the pipe material was started, the distance between the thermoelectric power generation device and the pipe material was set to 3000 mm, and the thermoelectric power generation device was moved after the pipe end was passed. A test was conducted to control the distance between the thermoelectric power generation device and the pipe to 125 mm. Further, a pipe material having a pipe temperature of about 1200 ° C and an outer diameter of 120 mm throughout the width direction was used.
其結果,相對於額定輸出,寬度方向大致成為如額定輸出般之發電,但端部為83%之輸出。 As a result, the width direction is approximately equal to the rated output with respect to the rated output, but the end is 83% of the output.
發明例24係實施如下試驗:使熱電發電單元為圖13所示之構成,於中央部分,將熱電發電單元與管材之距離控制為155mm,於端部將該距離控制為125mm。再者,管材係使用與上述發明例23大小相同且溫度分佈相同者。 Inventive Example 24 was carried out by the following test: The thermoelectric power generation unit was constructed as shown in Fig. 13, and the distance between the thermoelectric power generation unit and the pipe material was controlled to 155 mm in the center portion, and the distance was controlled to 125 mm at the end portion. Further, the pipe was used in the same manner as in the above-described Invention Example 23, and the temperature distribution was the same.
其結果,於寬度方向整體大致獲得額定輸出。 As a result, the rated output is substantially obtained as a whole in the width direction.
發明例25係實施如下試驗:使熱電發電單元為圖15所示之構成,將熱電發電單元中之熱電發電模組於中央部分配置為55mm間隔,於端部配置為60mm間隔,將單元與管材之距離控制為125mm。再者,管材係使用與上述發明例23大小相同且溫度分佈相同者。 In the invention example 25, the thermoelectric power generation unit is configured as shown in Fig. 15, and the thermoelectric power generation module in the thermoelectric power generation unit is disposed at a central portion of 55 mm intervals, and at the end portions at intervals of 60 mm, the unit and the tube are disposed. The distance is controlled to 125mm. Further, the pipe was used in the same manner as in the above-described Invention Example 23, and the temperature distribution was the same.
其結果,於寬度方向大致獲得額定輸出。 As a result, the rated output is roughly obtained in the width direction.
發明例26係實施如下試驗:使熱電發電單元及熱源之外周為圖17(A)所示之構成,且配置將熱彙聚至熱電發電單元之熱反射材。再者,管材係使用與上述發明例23大小相同且溫度分佈相同者。 In Inventive Example 26, the test was carried out in such a manner that the thermoelectric power generation unit and the heat source were configured as shown in Fig. 17(A), and the heat-reflecting material that condensed the heat to the thermoelectric power generation unit was disposed. Further, the pipe was used in the same manner as in the above-described Invention Example 23, and the temperature distribution was the same.
其結果,熱電發電單元可大致獲得額定輸出。 As a result, the thermoelectric power generation unit can roughly obtain the rated output.
發明例27係實施如下試驗:進而以包圍管材之外周部 之方式設置具有4個熱電發電單元之熱電發電裝置。再者,管材係使用與上述發明例23大小相同且溫度分佈相同者。 Inventive Example 27 was carried out by the following test: further to surround the outer circumference of the pipe In this manner, a thermoelectric generation device having four thermoelectric generation units is provided. Further, the pipe was used in the same manner as in the above-described Invention Example 23, and the temperature distribution was the same.
其結果,熱電發電單元之數量增加,與發明例25相比亦可獲得其2.2倍之輸出。 As a result, the number of thermoelectric power generation units increased, and the output of 2.2 times was obtained as compared with Inventive Example 25.
發明例28係進行如下運行操作:僅使管材上方之熱電發電單元可移動,且設置如圖19(A)所示之開口部。 Inventive Example 28 is an operation operation in which only the thermoelectric power generation unit above the pipe is movable, and an opening portion as shown in Fig. 19(A) is provided.
即,實施如下試驗:於管材之通材開始時,將上方設為開口部,於穩定通材後使上方之熱電發電裝置靠近管材。再者,管材係使用與上述發明例23大小相同且溫度分佈相同者。 That is, the test was carried out in which the upper portion was set as an opening at the start of the material of the pipe, and the thermoelectric power generator above was placed close to the pipe after the material was stabilized. Further, the pipe was used in the same manner as in the above-described Invention Example 23, and the temperature distribution was the same.
其結果,可獲得額定輸出,並且由於其他熱電發電單元不可動,故而可減低使該熱電發電單元可動時所需之操作成本。 As a result, the rated output can be obtained, and since other thermoelectric power generating units are not movable, the operation cost required to make the thermoelectric power generating unit movable can be reduced.
比較例5係使用與上述發明例22相同之熱電發電單元,且將熱電發電單元設置於與上述發明例22相同之場所。但是,於設置該熱電發電裝置時,將熱電發電裝置與管材之距離設為3000mm,以不使熱電發電裝置受損,而進行試驗。再者,管材係使用與上述發明例23大小相同且溫度分佈相同者。 In Comparative Example 5, the same thermoelectric power generation unit as in the above-described Invention Example 22 was used, and the thermoelectric power generation unit was placed in the same place as the above-described Invention Example 22. However, when the thermoelectric power generator was installed, the distance between the thermoelectric power generator and the pipe was set to 3000 mm, and the test was performed without damaging the thermoelectric generator. Further, the pipe was used in the same manner as in the above-described Invention Example 23, and the temperature distribution was the same.
其結果,僅可獲得額定輸出之1%左右之輸出。 As a result, only an output of about 1% of the rated output can be obtained.
根據上述發明例22~28及比較例5之結果,可確認到使用有本發明之鍛接管設備線之優異之發電效果。再者,以上實施例4係使用管材之上方之附有移動手段之熱電發電裝置,根據管材之溫度或設置場所附近之溫度,雖變更熱電發電單元之設置場所等,但確認到即便根據鋼板之溫度或熱電發電單元之輸出,變更設置場所或設置形態等,只要按照本發明,亦可獲得相同之結果。 According to the results of the above-mentioned Invention Examples 22 to 28 and Comparative Example 5, it was confirmed that the power generation effect excellent in the use of the forging pipe line of the present invention was obtained. In the fourth embodiment, the thermoelectric power generation device with the moving means above the pipe is used, and the installation place of the thermoelectric power generation unit or the like is changed depending on the temperature of the pipe or the temperature in the vicinity of the installation site, but it is confirmed that even according to the steel plate The temperature or the output of the thermoelectric power generation unit, the change of the installation place or the installation form, and the like can be obtained in accordance with the present invention.
根據本發明,由於可將自鋼胚等產生之熱有效地轉換為電力,故而有助於製造工廠中之節能化。 According to the present invention, since heat generated from a steel or the like can be efficiently converted into electric power, it contributes to energy saving in a manufacturing plant.
1‧‧‧熱電發電單元 1‧‧‧Thermal power generation unit
2‧‧‧移動手段 2‧‧‧Mobile means
3‧‧‧熱電發電裝置 3‧‧‧Thermal power generation unit
4‧‧‧輸送輥輪 4‧‧‧Conveying roller
5‧‧‧鋼材 5‧‧‧Steel
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