技術(shu)文章

當(dang)前(qian)位(wei)置：首(shou)頁技術(shu)文章和晟快速導熱系數(shu)測試(shi)儀

和晟快速導熱系數(shu)測試(shi)儀

更(geng)新(xin)時間(jian)：2023-03-06

點(dian)擊次(ci)數：1417

瞬(shun)態(tai)平面熱(re)源(yuan)技術(shu)(TPS)是(shi)用(yong)於(yu)測量(liang)導熱(re)系數(shu)的壹種(zhong)新(xin)型的方法，由(you)瑞(rui)典 Chalmer 理工大(da)學的 Silas Gustafsson 教授在熱(re)線(xian)法的(de)基(ji)礎上(shang)發(fa)展(zhan)起(qi)來(lai)的。它(ta)測定(ding)材料(liao)熱(re)物(wu)性(xing)的(de)原(yuan)理是(shi)基(ji)於無(wu)限(xian)大介(jie)質中(zhong)階(jie)躍加熱的(de)圓(yuan)盤(pan)形熱源(yuan)產(chan)生(sheng)的瞬態(tai)溫度響應(ying)。利(li)用(yong)熱阻性材料(liao)做成(cheng)壹(yi)個平面的(de)探頭(tou)，同(tong)時作為(wei)熱(re)源(yuan)和溫度傳感(gan) 器。合(he)金(jin)的熱阻(zu)系數(shu)壹溫度和電阻(zu)的(de)關(guan)系呈線(xian)性關(guan)系，即(ji)通過了解電(dian)阻的變化(hua)可以知(zhi)道熱量(liang)的損(sun)失，從(cong) 而(er)反映了樣(yang)品(pin)的導(dao)熱性能(neng)。

二(er)、技術參(can)數

測試(shi)範圍(wei)	0.005~300W/(m*K)
測量(liang)溫度範圍(wei)	常(chang)溫(wen)~130℃
探頭(tou)直(zhi)徑	壹(yi)號(hao)探頭(tou) 7.5mm；二(er)號(hao)探頭(tou) 15mm
精度	≤2%
重(zhong)復(fu)性(xing)誤(wu)差(cha)	≤3%
測量(liang)時間(jian)	5~160s
樣(yang)品(pin)溫升(sheng)	＜15℃
電源(yuan)	220V
整機(ji)功(gong)率(lv)	＜500W
樣(yang)品(pin)規格	壹(yi)號(hao)探頭(tou)所測單(dan)個樣(yang)品(pin) (15153.75)mm 二號(hao)探頭(tou)所測單(dan)個樣(yang)品(pin) (30307.5)mm

產(chan)品(pin)特點(dian)：

1、測試(shi)範圍(wei)廣泛，測試(shi)性(xing)能(neng)穩(wen)定；

2、直(zhi)接(jie)測量(liang)，測試(shi)時間(jian)5-160s左右(you)可設置，能(neng)快速準確的測出(chu)導(dao)熱(re)系數(shu)，節(jie)約(yue)了(le)大量(liang)的時間(jian)；

3、不會和靜態(tai)法壹(yi)樣(yang)受(shou)到接(jie)觸(chu)熱阻(zu)的影(ying)響；

4、無(wu)須(xu)特別(bie)的樣(yang)品(pin)制(zhi)備，對樣(yang)品(pin)形狀(zhuang)並(bing)無(wu)特(te)殊(shu)要求(qiu)，塊(kuai)狀(zhuang)固體只需相對(dui)平滑(hua)的樣(yang)品(pin)表面並(bing)且(qie)滿足(zu)長(chang)寬至(zhi)
少(shao)為(wei)探頭(tou)直(zhi)徑的(de)兩倍(bei)即(ji)可；

5、對樣(yang)品(pin)實(shi)行無(wu)損(sun)檢測，意(yi)味(wei)著(zhe)樣(yang)品(pin)可以重(zhong)復(fu)使(shi)用；

6、探頭(tou)采(cai)用(yong)雙螺(luo)旋(xuan)線(xian)的結(jie)構進(jin)行設計(ji)，結(jie)合(he)專(zhuan)屬(shu)數學(xue)模(mo)型(xing)，利(li)用(yong)核心算法對(dui)探頭(tou)上(shang)采(cai)集的(de)數據(ju)進(jin)行分析

7、樣(yang)品(pin)臺的(de)結(jie)構設計(ji)巧(qiao)妙，操作方便(bian)，適(shi)合(he)放(fang)置不(bu)同(tong)厚(hou)度的樣(yang)品(pin)，同(tong)時簡潔美(mei)觀；

8、探頭(tou)上(shang)的(de)數(shu)據(ju)采集使(shi)用了(le)進(jin)口(kou)的數(shu)據(ju)采集芯(xin)片，該芯片(pian)的(de)高分(fen)辨率(lv)，能(neng)使(shi)測試(shi)結(jie)果更(geng)加準確可靠；

9、主機的控(kong)制(zhi)系統(tong)使用了(le)ARM 微處(chu)理(li)器，運算(suan)速(su)度比傳統(tong)的(de)微處(chu)理(li)器快，提高了(le)系統(tong)的分析處理能(neng)力(li)，計算(suan)結(jie)果更(geng)加準確；

10、儀器可用(yong)於(yu)塊(kuai)狀(zhuang)固體、膏狀(zhuang)固體、顆粒狀(zhuang)固體、膠體(ti)、液體(ti)、粉末、塗層、薄膜、保溫材料(liao)等(deng)熱(re)物(wu)性(xing)參(can)數的(de)測定(ding)；

11、智(zhi)能(neng)化(hua)的人(ren)機界(jie)面，彩(cai)色(se)液晶(jing)屏顯(xian)示，觸(chu)摸(mo)屏控(kong)制(zhi)，操作方便(bian)簡潔；

瞬(shun)態(tai)軟件.png

軟件特點(dian)：

1、支(zhi)持儀器系數(shu)校(xiao)準。

2、自動(dong)計(ji)算(suan)導熱(re)系數(shu)，熱擴散系數(shu)，相關系數(shu)，可以自(zi)動(dong)判(pan)斷(duan)結(jie)果是(shi)否(fou)符(fu)合(he)溫(wen)升(sheng)。

3、曲線(xian)可以壹(yi)鍵(jian)自(zi)適(shi)應，曲線(xian)放(fang)大，縮(suo)小，視(shi)圖拖(tuo)動。

4、支(zhi)持同(tong)時打開多(duo)條曲線(xian)，且(qie)數(shu)量(liang)不受(shou)限(xian)制(zhi)。

5、可生(sheng)成(cheng)報(bao)告(gao)，圖像(xiang)，結(jie)果，實(shi)驗信(xin)息等，模板(ban)可自(zi)定(ding)義(yi)。

6、軟(ruan)件(jian)內置試(shi)驗(yan)記錄、數據(ju)處理(li)和報(bao)告(gao)格式(shi)。

7、可到(dao)處(chu)數據(ju)，支(zhi)持 xls，tps,cvs,png 等格式(shi)導出(chu)，並(bing)支(zhi)持對(dui) xls，tps,cvs 等(deng)格式(shi)的導入。軟件(jian)具有遠程更(geng)新(xin)功(gong)能(neng)，可以自(zi)動(dong)獲(huo)取到新版本(ben)軟件，直(zhi)接(jie)安(an)裝。

8、支(zhi)持數(shu)據(ju)優(you)化，汙(wu)點(dian)數據(ju)去(qu)除，智(zhi)能(neng)化(hua)進(jin)行計算(suan)。

9、支(zhi)持中(zhong)文，英(ying)文，日(ri)語，韓(han)語切換(huan)。

導(dao)熱(re)4.jpg

部(bu)分采購(gou)高校(xiao)及(ji)機構(gou)

1、	二維石(shi)墨材料(liao)導(dao)熱(re)防(fang)腐塗層(ceng)制(zhi)備及(ji)性能(neng)優(you)化	大連理工大(da)學(xue)
2、	水稻(dao)稭(jie)稈砂(sha)漿復(fu)合(he)材料(liao)熱(re)工(gong)性(xing)能(neng)研究(jiu)	沈陽農業大(da)學
3、	陶(tao)瓷(ci)廢料(liao)制(zhi)備輕質(zhi)保溫泡沫陶(tao)瓷(ci)的研究(jiu)	華南理(li)工(gong)大學
4、	碳納(na)米管(guan)-膨(peng)脹石墨/環(huan)氧樹脂(zhi)復(fu)合(he)材料(liao)的(de)導(dao)熱(re)性能(neng)	中國科(ke)學(xue)院(yuan)過(guo)程工程研究(jiu)所
5、	高性(xing)能(neng)鋼(gang)結(jie)構防(fang)火塗(tu)層制(zhi)備性能(neng)及(ji)應用(yong)研究(jiu)	煙臺大(da)學(xue)
6、	真空絕(jue)熱板(ban)芯(xin)材木粉原(yuan)料(liao)的(de)隔(ge)熱(re)性能(neng)分(fen)析	福建農林大學
7、	水性(xing)納(na)米隔(ge)熱(re)保溫塗料(liao)的(de)制(zhi)備與性(xing)能(neng)研究(jiu)	深(shen)圳(zhen)恒(heng)固納(na)米科(ke)技(ji)有限(xian)公司
8、	氧化亞(ya)銅包覆(fu)正(zheng)二十(shi)烷(wan)相變材料(liao)微膠囊的制(zhi)備及(ji)其(qi)多功(gong)能(neng)性(xing)研究(jiu)	北京化工大(da)學(xue)
9、	結(jie)構保溫膨脹珍珠巖(yan)混凝土(tu)的試(shi)驗(yan)及(ji)性能(neng)研究(jiu)	河北建築(zhu)工程學院(yuan)
10、	棉纖維對(dui)保溫材料(liao)性(xing)能(neng)的(de)影響(xiang)	南通開放(fang)大學(xue)
11、	納(na)米填料(liao)改(gai)性(xing)環(huan)氧樹脂(zhi)復(fu)合(he)材料(liao)性(xing)能(neng)研究(jiu)	東北石油大學(xue)
12、	二硫化鉬(mu)改性酚(fen)醛(quan)樹脂(zhi)的(de)耐(nai)熱性及(ji)抗(kang)氧化性(xing)研究(jiu)	內蒙古(gu)農業大(da)學
13、	氣凝膠摻雜(za)玻化(hua)微珠砂(sha)漿性(xing)能(neng)的(de)研究(jiu)	江(jiang)蘇(su)省(sheng)既(ji)有建築(zhu)綠(lv)色(se)化(hua)改(gai)造工(gong)程技術研究(jiu)中(zhong)心
14、	保溫膨脹珍珠巖(yan)混凝土(tu)配合(he)比設計(ji)與分(fen)析	中鐵(tie)十八(ba)局(ju)集團(tuan)房地(di)產(chan)開(kai)發有限(xian)公司
15、	雙酚(fen)S環(huan)氧樹脂(zhi)的(de)合(he)成(cheng)及(ji)其(qi)膠粘劑(ji)的研制(zhi)	東華大學(xue)應(ying)用化學(xue)系
16、	高(gao)分子雜(za)化碳氣凝膠基(ji)復合(he)相(xiang)變材料(liao)的(de)組裝設計(ji)與性(xing)能(neng)研究(jiu)	桂(gui)林電子(zi)科(ke)技(ji)大(da)學(xue)
17、	光(guang)熱(re)轉化(hua)相(xiang)變微膠囊與溫(wen)敏相變凝(ning)膠的(de)制(zhi)備與性(xing)能(neng)研究(jiu)	江(jiang)南(nan)大(da)學(xue)
18、	氟(fu)化(hua)石(shi)墨烯/聚(ju)合(he)物(wu)功(gong)能(neng)塗(tu)層的(de)防腐性能(neng)研究(jiu)	大連理工大(da)學(xue)
19、	堅木單(dan)寧基(ji)泡沫(mo)材料(liao)的(de)制(zhi)備及(ji)其(qi)力學性(xing)能(neng)	福建農林大學
20、	高(gao)導(dao)熱(re)苯乙烯丙烯酸樹(shu)脂(zhi)復(fu)合(he)材料(liao)制(zhi)備及(ji)導熱(re)性能(neng)研究(jiu)	沈(shen)陽化工(gong)大(da)學
21、	新(xin)型(xing)高性(xing)能(neng)復(fu)合(he)相(xiang)變材料(liao)的(de)結(jie)構設計(ji)及(ji)性能(neng)研究(jiu)	桂(gui)林電子(zi)科(ke)技(ji)大(da)學(xue)
22、	水性(xing)納(na)米隔(ge)熱(re)保溫塗料(liao)的(de)制(zhi)備與性(xing)能(neng)研究(jiu)	深(shen)圳(zhen)恒(heng)固納(na)米科(ke)技(ji)有限(xian)公司
23、	MnO₂對鉬(mu)尾礦(kuang)基(ji)發泡(pao)陶(tao)瓷(ci)升(sheng)溫(wen)速率(lv)影(ying)響(xiang)的研究(jiu)	商(shang)洛(luo)學院(yuan)
24、	微納(na)米碳復(fu)合(he)水性(xing)散熱塗料(liao)的(de)制(zhi)備與性(xing)能(neng)研究(jiu)	華南理(li)工(gong)大學
25、	分(fen)層分(fen)區布(bu)料(liao)工(gong)藝(yi)制(zhi)備輕質(zhi)保溫發泡陶(tao)瓷(ci)的研究(jiu)	商(shang)洛(luo)學院(yuan)

部分使用導(dao)熱(re)系數(shu)客戶(hu)SCI論(lun)文

1、Hydrogel beads derived from chrome leather scraps for the preparation of lightweight gypsum

2、Size-controlled graphite nanoplatelets_ thermal conductivity enhancers for epoxy resin

3、Thermal, morphological, and mechanical characteristics of sustainable tannin bio-based foams reinforced with wood cellulosic fibers

4、Improved thermal conductivity of epoxy resin by graphene–nickel three-dimensional filler

5、A synergistic strategy for fabricating an ultralight and thermal insulating aramid nanofiber/polyimide aerogel

6、Fabrication of Graphene/TiO 2 /Paraffin Composite Phase Change Materials for Enhancement of Solar Energy Efficiency in Photocatalysis and Latent Heat Storage

7、Improved thermal conductivity of styrene acrylic resin with carbon nanotubes, graphene and boron nitride hybrid fillers

8、Preparation and characterization of paraffin/expanded graphite composite phase change materials with high thermal conductivity

9、Tailoring of bifunctional microencapsulated phase change materials with CdS/SiO2 double-layered shell for solar photocatalysis and solar thermal energy storage

10、Functional aerogels with sound absorption and thermal insulation derived from semi-liquefied waste bamboo and gelatin

11、Lamellar-structured phase change composites based on biomass-derived carbonaceous

sheets and sodium acetate trihydrate for high-efficient solar photothermal energy harvest

12、Construction of double cross-linking PEG/h-BN@GO polymeric energy-storage composites with high structural stability and excellent thermal performances

13、Gelatin as green adhesive for the preparation of a multifunctional biobased cryogel derived from bamboo industrial waste

14、A novel self-thermoregulatory electrode material based on phosphorene-decorated phase-change microcapsules for supercapacitors

15、Development of poly(ethylene glycol)/silica phase-change microcapsules with well-defined core-shell structure for reliable and durable heat energy storage

16、Experimental and numerical study on heat emission characteristics of ventilated air annular in tunneling roadway

17、Construction of polyaniline/carbon nanotubes-functionalized phase-change microcapsules for thermal management application of supercapacitors

18、Mechanical, thermal and acoustical characteristics of composite board kneaded by leather fiber and semi-liquefied bamboo

19、Tuning the oxidation degree of graphite toward highly thermally conductive graphite/epoxy composites

20、Thermal self-regulatory smart biosensor based on horseradish peroxidase-immobilized phase-change microcapsules for enhancing detection of hazardous substances

21、Morphology-controlled synthesis of microencapsulated phase change materials with TiO2 shell for thermal energy harvesting and temperature regulation

22、Size-tunable CaCO3@n-eicosane phase-change microcapsules for thermal energy storage

23、High-Efficiency Preparation of Reduced Graphene Oxide by a Two-Step Reduction Method and Its Synergistic Enhancement of Thermally Conductive and Anticorrosive Performance for Epoxy Coatings

24、Temperature and pH dual-stimuli-responsive phase-change microcapsules for multipurpose applications in smart drug delivery

25、Development of Renewable Biomass-Derived Carbonaceous Aerogel/Mannitol Phase-Change Composites for High Thermal-Energy-Release Efficiency and Shape Stabilization

26、Immobilization of laccase on phase-change microcapsules as self-thermoregulatory enzyme carrier for biocatalytic enhancement

27、Microencapsulating n-docosane phase change material into CaCO3/Fe3O4 composites for high-efficient utilization of solar photothermal energy

28、Integration of Magnetic Phase-Change Microcapsules with Black Phosphorus Nanosheets for Efficient Harvest of Solar Photothermal Energy

29、Surface construction of Ni(OH)2 nanoflowers on phase-change microcapsules for enhancement of heat transfer and thermal response

30、Design and fabrication of bifunctional microcapsules for solar thermal energy storage and solar photocatalysis by encapsulating paraffin phase change material into cuprous oxide

31、Design and construction of mesoporous silica/n-eicosane phase-change nanocomposites for supercooling depression and heat transfer enhancement

32、Development of reversible and durable thermochromic phase-change microcapsules for real-time indication of thermal energy storage and management

33、Nanoflaky nickel-hydroxide-decorated phase-change microcapsules as smart electrode materials with thermal self-regulation function for supercapacitor application

34、Biodegradable wood plastic composites with phase change microcapsules of honeycomb-BN-layer for photothermal energy conversion and storage

35、Hierarchical microencapsulation of phase change material with carbon-nanotubes/polydopamine/silica shell for synergistic enhancement of solar photothermal conversion and storage

36、Molecularly Imprinted Phase-Change Microcapsule System for Bifunctional Applications in Waste Heat Recovery and Targeted Pollutant Removal

37、Pomegranate-like phase-change microcapsules based on multichambered TiO2 shell engulfing multiple n-docosane cores for enhancing heat transfer and leakage prevention

38、Innovative Integration of Phase-Change Microcapsules with Metal–Organic Frameworks into an Intelligent Biosensing System for Enhancing Dopamine Detection

39、Morphology-controlled fabrication of magnetic phase-change microcapsules for synchronous efficient recovery of wastewater and waste heat

40、Polyimide/phosphorene hybrid aerogel-based composite phase change materials for high-efficient solar energy capture and photothermal conversion

上壹(yi)條(tiao)-70℃高(gao)低溫試(shi)驗(yan)箱(xiang)廠家(jia)
下壹條(tiao)和晟科(ke)技(ji)平板(ban)導(dao)熱(re)系數(shu)測試(shi)儀