西格馬-四大超高溫優(yōu)勢(shì)
A Thousand Degrees-four ultra-high temperature advantages
一. 知名品牌-超高溫電爐行業(yè)的知名品牌
(1)2006年西格馬是國(guó)內(nèi)熱處理設(shè)備行業(yè)行業(yè)中***家全部使用陶瓷纖維作為爐膛材料的高溫電爐生產(chǎn)廠家,也是***家把國(guó)家標(biāo)準(zhǔn)中實(shí)驗(yàn)電爐的***高溫度1600℃提高到1700℃的生產(chǎn)廠家。因此,西格馬成為國(guó)內(nèi)知名的實(shí)驗(yàn)電爐品牌企業(yè)。
(1)In 2006, Sigma is high temperature furnace manufacturer which the first domestic electric industry all use ceramic fiber as chamber material . It is also the first manufacturer that national standards to the maximum temperature of 1600 ℃ laboratory furnace up to 1700 ℃. Therefore, Sigma become the well-known experimental furnace brands.
(2) 2008年開(kāi)始,西格馬開(kāi)始逐步把1800℃、2000℃、2200℃、3000℃實(shí)驗(yàn)電爐作為公司的主導(dǎo)產(chǎn)品,印刷在西格馬供貨目錄中,西格馬首先把內(nèi)蒙古稀土研究院生產(chǎn)的鉻酸鑭發(fā)熱體、北京鋼鐵研究總院生產(chǎn)的二氧化鋯發(fā)熱體應(yīng)用于超高溫實(shí)驗(yàn)電爐。
(2) From 2008, Sigma began to gradually put the 1800℃, 2000℃, 2200℃, 3000℃ experimental furnace as the company's leading product, printed on sigma supplier directory. Sigma first use Inner Mongolia Rare Earth Research Institute produced lanthanum chromite heating element, Beijing Iron and steel Research Institute produced zirconia heat generator in ultra high temperature laboratory furnace.
(3) 西格馬于2010年發(fā)明了二硼化鋯復(fù)合陶瓷發(fā)熱體,該發(fā)熱體不僅可以在正空氣氛下使用,還可以在氧化氣氛條件下使用,這一技術(shù)填充了國(guó)內(nèi)外的空白。利用該發(fā)熱體生產(chǎn)的超高溫電爐在國(guó)內(nèi)外銷售。
(3) In 2010,Sigma invent the zirconium diboride composite ceramic heating element. It is not only be used in air atmosphere, also be used in an oxidizing atmosphere conditions, this technology fills the gaps at home and abroad. With this heat element production ultra-high temperature furnace sale in the domestic and international.
(4) 2010年西格馬公司申報(bào)的超高溫電爐獲得了河南省創(chuàng)新基金30萬(wàn)元,同年獲得了科技部創(chuàng)新基金60萬(wàn)元。
(4) In 2010,Sigma declared ultra-high-temperature furnace won Henan Province innovation fund of RMB300000, the same year won the Ministry of Science Innovation Fund RMB600,000.
(5) 2009-2014年期間,西格馬先后發(fā)明了二氧化鋯傳感器、二硼化鋯復(fù)合陶瓷傳感器、超高溫難熔合金熱電偶、碳化鋯復(fù)合陶瓷傳感器、二硼化鋯復(fù)合陶瓷發(fā)熱體、碳化鋯復(fù)合陶瓷發(fā)熱體等20多項(xiàng)超高溫方面的***發(fā)明,這是國(guó)內(nèi)外超高溫******多企業(yè)。
(5) During 2009-2014, Sigma has invented the Zirconia sensor, zirconium diboride composite ceramic sensor, ultra high temperature refractory alloys thermocouples, zirconium carbide ceramic composite sensor, zirconium diboride composite ceramic heating element, zirconium carbide compound ceramic heating element and other more than 20 items ultra-high temperature patented inventions, this is patent for ultra-high temperature up to enterprises at home and abroad.
(6) 2013年開(kāi)始至今,西格馬把二硼化鋯復(fù)合陶瓷傳感器、二硼化鋯復(fù)合陶瓷發(fā)熱體應(yīng)用于藍(lán)寶石晶體生長(zhǎng)爐,先后發(fā)明了十幾項(xiàng)***發(fā)明,溫場(chǎng)梯度移動(dòng)法—藍(lán)寶 石晶體生長(zhǎng)理論對(duì)藍(lán)寶石行業(yè)的影響將是不可估量的。其中,二硼化鋯復(fù)合陶瓷傳感器在2100℃條件下,可以長(zhǎng)期使用10天以上。
(6) Since the start of 2013, the Sigma use zirconium diboride composite ceramic sensor, zirconium diboride composite ceramic heating element in sapphire crystal growth furnace, has invented a dozen patented inventions, temperature field gradient law movement - sapphire crystal growth theory on sapphire industry will be immeasurable. Among them, zirconium diboride composite ceramic sensor at 2100 ℃ conditions, long-term use for more than 10 days.
(7) 2014年西格馬與上海交通大學(xué)合作研發(fā)的應(yīng)用于核燃料泄露試驗(yàn)的超高溫電爐,使用溫度可以達(dá)到2850℃。
(7) In 2014, Sigma cooperation with the Shanghai Jiaotong University developed ultra-high-temperature furnace used in nuclear fuel leak test, the temperature can reach 2850 ℃.
(8) 2015年西格馬與中國(guó)科技大學(xué)合作研發(fā)的應(yīng)用于航天發(fā)動(dòng)機(jī)尾氣檢測(cè)的超高溫電爐,使用溫度可以達(dá)到2600℃,爐內(nèi)壓力可以達(dá)到50個(gè)大氣壓。
(8) In 2015, Sigma cooperation with the China University of Technology research and development of ultra-high-temperature furnace used in aerospace engine exhaust testing, the use of temperature can reach 2600 ℃, the furnace pressure may be up to 50 atmospheres.
二. 原創(chuàng)發(fā)明------***超高溫電爐行業(yè)技術(shù)進(jìn)步
(1) 西格馬原創(chuàng)發(fā)明了二硼化鋯復(fù)合陶瓷傳感器、二硼化鋯復(fù)合陶瓷發(fā)熱體、超高溫電爐為超高溫行業(yè)的發(fā)展奠定了發(fā)展的基礎(chǔ),一個(gè)穩(wěn)定的、環(huán)保的、綠色的超高溫溫場(chǎng)的形成,為超高溫行業(yè)材料性能的檢測(cè)提供基礎(chǔ)保證。
(1) Sigma original invention zirconium diboride composite ceramic sensor, zirconium diboride composite ceramic heating element for the development of ultra-high temperature, ultra-high temperature furnace industry has laid a foundation for the development. A stable, environmentally friendly, ultra gentle green forming the field and provide basic guarantee for the detection of ultra-high temperature performance material industry.
(2) 西格馬二硼化鋯復(fù)合陶瓷傳感器理論使用溫度可以達(dá)到2600℃,實(shí)際中應(yīng)經(jīng)使用到2150℃,這一技術(shù)比行業(yè)中使用溫度***高的鎢錸熱電偶,還要高出300℃,這一技術(shù)對(duì)超高溫行業(yè)的貢獻(xiàn)是不可估量的。
(2) Sigma zirconium diboride composite ceramic sensor theory using temperature can reach 2600 ℃, the actual use should be to 2150 ℃, this technology uses the highest temperature tungsten-rhenium thermocouples than the industry, but also higher than 300 ℃, which a contribution to the ultra-high temperature technology industry is immeasurable.
(3) 西格馬超高溫發(fā)熱體、超高溫傳感器和超高溫電爐是超高溫行業(yè)發(fā)展的基礎(chǔ)設(shè)備,是奠定超高溫行業(yè)的基礎(chǔ)理論。
(3) Sigma ultra- high temperature heating element, ultra-high temperature sensor and ultra-high temperature furnace is the basis for the development of ultra-high temperature equipment industry, it is to lay the basic theory of ultra-high temperature industry.
三. 開(kāi)放實(shí)驗(yàn)室------超高溫加熱和計(jì)量工程技術(shù)中心
公司投資300多萬(wàn)元,建造了一個(gè)1500m2、面向公眾開(kāi)放型的超高溫實(shí)驗(yàn)室。在這個(gè)實(shí)驗(yàn)室里使用自主研發(fā)的超高溫電爐,可以進(jìn)行 1200℃、1400℃、1700℃、1800℃、2000℃、2200℃、2500℃、3000℃ 真空、氣氛、氧化條件下的燒結(jié)實(shí)驗(yàn)、熱壓燒結(jié)實(shí)驗(yàn)、熔點(diǎn)測(cè)試實(shí)驗(yàn),超高溫?zé)o機(jī)材料的力學(xué)性能測(cè)試試驗(yàn)等。
開(kāi)放型的超高溫實(shí)驗(yàn)室,實(shí)行收費(fèi)制度,可以進(jìn)行委托按用戶工藝要求進(jìn)行燒結(jié)實(shí)驗(yàn),用戶通過(guò)直接租賃超高溫實(shí)驗(yàn)室、由用戶的工程師自己動(dòng)手燒結(jié)實(shí)驗(yàn),設(shè)備購(gòu)買(mǎi)前的各種材料的燒結(jié)實(shí)驗(yàn)。
河南省計(jì)量科學(xué)研究院超高溫工程技術(shù)中心
2011年我公司和河南省計(jì)量科學(xué)研究院共同投資合作建立“河南省計(jì)量院超高溫工程技術(shù)研究中心”,該中心以二硼化鋯復(fù)合陶瓷熱電偶的分度、超高溫?zé)犭娕紮z定規(guī)程和超高溫材料性能檢測(cè)為主要課題和研究方向,努力使之成為省級(jí)工程技術(shù)研究中心或者國(guó)家工程技術(shù)研究中心。
超高溫工程技術(shù)研究中心可以進(jìn)行1000-3000℃的溫度測(cè)試和設(shè)備檢驗(yàn)、標(biāo)準(zhǔn)溫度計(jì)量、單鉑銠熱電偶、雙鉑銠熱電偶、各種溫度計(jì)量?jī)x器設(shè)備校正和測(cè)試,超高溫材料的性能測(cè)試等。
我們的超高溫產(chǎn)品已經(jīng)出口到韓國(guó)、巴西、法國(guó)、俄羅斯、伊朗、斯里蘭卡、泰國(guó)等國(guó)家。
我們?yōu)橹袊?guó)科學(xué)院生產(chǎn)的2600℃高溫高壓實(shí)驗(yàn)爐,溫度均勻性達(dá)到±6℃/150mm;
我們?yōu)樯虾=淮笊a(chǎn)超高溫試驗(yàn)爐,爐溫達(dá)到2850℃;
我們?yōu)橹袊?guó)核動(dòng)力研究院生產(chǎn)氧化爐,在氧化氣氛條件下,超高溫箱式電阻爐的工作溫度達(dá)到1850℃。
7. Investing more than half a million dollars, we built a 1500m2 ultra-high temperature laboratory, in which you can make sintering test, hot-pressing test, melting point test, ultra-high temperature material mechanics property in vacuum,atmosphere and oxidation environment under 1200℃, 1400℃, 1700℃, 1800℃, 2000℃, 2200℃, 2500℃, 3000℃.
Adopted charges, the ultra-high temperature laboratory is open to the public. Users can entrust us to sinter materials according to their demands or sinter materials by their own engineer through lease our ultra-high temperature laboratory. They can also make sintering experiment of various materials before purchasing equipment.
Ultra-high temperature engineering technology center of Henan Institute of Metrology
In 2011, cooperated with Henan measuring academy of sciences, we established the ultra-high temperature engineering technology center of Henan Institute of Metrology, the main subject of which is zirconium diboride composite ceramic thermocouple’s indexing, verification regulations of ultra-high temperature thermocouple and test of ultra-high temperature material’s property.
The ultra-high temperature engineering technology center can be engaged in testing equipment inspection at range of 1000-3000℃, standard temperature measurement, calibration and examination of single platinum rhodium thermocouple, double platinum rhodium thermocouple and various temperature measuring instruments and performance test of ultra-high temperature materials.
Our ultra-high temperature products have been exported to South Korea, Brazil, France, Russia, Iran, Sri Lanka, Thailand and other countries.
We produce 2600 ℃ high temperature and pressure laboratory furnace to the Chinese Academy of Sciences, temperature uniformity to reach ± 6 ℃ / 150mm;
We produce ultra-high-temperature test furnace to Shanghai Jiaotong University, the furnace temperature reached 2850 ℃;
We produce oxidation furnace to China Nuclear Power Institute of Industrial, in an oxidizing atmosphere, ultra-high temperature box resistance furnace temperature reached 1850 ℃.
四. 超高溫理論-----超高溫方面的重大理論發(fā)明
一、 SIGMA超高溫的定義:在氧化氣氛條件下,1800℃以上的溫場(chǎng)稱為超高溫溫場(chǎng),能夠長(zhǎng)期接觸式測(cè)定1800℃以上的溫場(chǎng)的溫度傳感器稱為超高溫傳感 器,能夠在1800℃以上長(zhǎng)期使用的發(fā)熱元件稱為超高溫發(fā)熱元件,能夠在1800℃以上長(zhǎng)期使用的的箱式電阻爐稱為超高溫箱式電阻爐。
二、 標(biāo)準(zhǔn)高溫固定點(diǎn)(high temperature fixed points,HTFPs)的研究主要是為了解決ITS-90溫標(biāo)在高溫段僅一個(gè)固定點(diǎn)對(duì)溫度測(cè)量帶來(lái)的誤差,而為下一代溫標(biāo)在更高溫度提供新的固定點(diǎn), 國(guó)際上公認(rèn)的是CCT(溫度咨詢顧問(wèn)委員會(huì))下面的CCT-WG5組織發(fā)布的高溫固定點(diǎn)物質(zhì)是一些金屬的碳共晶與碳包晶,Co-C(名義溫度 1324℃),Pt-C(名義溫度1738℃),Re-C(名義溫度2474℃) 和WC-C(名義溫度2750℃)等。
三、 超高溫標(biāo)準(zhǔn)溫場(chǎng)和溫度測(cè)定方法:利用標(biāo)準(zhǔn)B型熱電偶和高溫固定點(diǎn),校準(zhǔn)精密紅外測(cè)溫儀,利用B型熱電偶和精密紅外測(cè)溫儀的溫度連續(xù)性,畫(huà)出爐膛的標(biāo)準(zhǔn)溫度 和測(cè)量溫度曲線,再測(cè)定若干個(gè)溫度點(diǎn)的溫度場(chǎng)中氣體對(duì)激光的吸收強(qiáng)度,從而測(cè)定氣體對(duì)激光的吸收強(qiáng)度和溫度之間的關(guān)系,把氣體對(duì)激光的吸收強(qiáng)度與溫度的關(guān) 系曲線作為超高溫溫度標(biāo)準(zhǔn)。根據(jù)該曲線設(shè)定相應(yīng)程序,即可通過(guò)氣體對(duì)激光的吸收強(qiáng)度來(lái)確定溫度的高低,也可以準(zhǔn)確檢定其他超高溫測(cè)量的標(biāo)準(zhǔn)設(shè)備。
四、超高溫領(lǐng)域的概念:是指在超高溫測(cè)量技術(shù)建立標(biāo)準(zhǔn)以后,對(duì)超高溫材料的超高溫性能就可以定量的測(cè)試,超高溫材料在應(yīng)用過(guò)程中的糾紛就可以判定,超高溫材料的發(fā)展就有規(guī)劃的依據(jù),從事超高溫材料的研究,超高溫材料的檢測(cè),超高溫計(jì)量,超高溫材料的銷售等領(lǐng)域。
一、 SIGMA Ultra-high temperature definition: in an oxidizing atmosphere conditions, above 1800 ℃ ultra-high temperature field called field gentle. Long-term contact measuring temperatures above 1800 ℃ temperature field sensor is called ultra-high temperature sensor. Long-term use of heating element above 1800 ℃ is called ultra-high temperature heating element. It is possible above 1800 ℃ long-term use of the box-type resistance furnace known as ultra-high temperature box resistance furnace.
二、 Study (high temperature fixed points, HTFPs) is mainly to solve the ITS-90 temperature scale error in the high temperature section only a fixed point on the temperature measurement, the temperature scale for the next generation and provide new fixed at a higher temperature point, internationally recognized high-temperature fixed point substance CCT (temperature consultancy Committee) following CCT-WG5 organization published some metal-carbon eutectic and peritectic carbon, co-C (nominal temperature of 1324 ℃), Pt- C (nominal temperature of 1738 ℃), Re-C (nominal temperature of 2474 ℃) and the WC-C (nominal temperature of 2750 ℃) and so on.
三、 Ultra-high temperature standard temperature and temperature measurement method: using a standard B-type thermocouple and temperature fixed-point calibration precision infrared thermometer, the use of B-type thermocouple and precision infrared thermometer temperature continuity draw standard temperature and measuring the temperature profile of furnace chamber, and then measuring the temperature of the gas field in several temperature points absorption intensity of laser light, thereby determining the relationship between the gas laser absorption intensity and temperature, and the curve of the laser gas absorption strength and temperature as UHT temperature standards. According to the curve to set the appropriate procedures, to the absorption intensity of the laser is determined by the temperature level of the gas to be accurate test ultra-high temperature measurements of other standard equipment.
四、 Concept of ultra-high temperature areas: It is that after establish standards in the ultra high temperature measurement technology, for ultra-high temperature performance of ultra-high temperature materials can be quantitatively tested, ultra-high temperature material dispute in the application process can determine, the development of ultra-high temperature materials on a planned basis, research in ultra-high temperature materials, testing of ultra-high temperature materials, ultra high temperature measurement, sales of ultra-high temperature materials and other fields.