还原氧化石墨烯涂层织物的电加热性能

为研究可穿戴织物的电加热性能以及水洗对其性能的影响,通过简单安全可大规模产业化的无转移液相浸涂沉积法在涤纶针织物上沉积并原位还原,制备了还原氧化石墨烯(RGO)涂层织物加热器。借助扫描电子显微镜和傅里叶红外光谱仪对制备的RGO涂层涤纶织物进行表观形态与化学结构分析,同时研究了RGO涂层涤纶织物的导电、力学、电加热性能。结果表明:RGO涂层涤纶织物的电导率为430.9 mS/cm,在10 V电压下可达到65.58℃的稳定温度,最大升温速率为3.41℃/s;经过2次水洗循环后,在10 V的电压下,RGO涂层涤纶织物可达到43℃。本文研究表明,RGO涂层涤纶织物具有优异的电热性能,在医用电热、运动康复等领域具有良好的应用潜力。

导电涤棉纱的制备及其织物电加热性能

通过多巴胺对涤棉纱预处理,以葡萄糖为还原剂,将包覆有聚多巴胺层的涤棉纱置于硝酸银溶液中,在涤棉纱表面生成一层连续均匀致密的镀银层,制备了涤棉导电纱。通过扫描电子显微镜(SEM)、超景深三维显微、傅里叶红外光谱仪(FT-IR)、X射线衍射(XRD)、热重分析仪(TG)对镀银导电涤棉纱的结构和性能进行了表征。结果表明:在AgNO_(3)摩尔浓度为0.12 mol/L时,化学镀银涤棉纱的电阻为1.72Ω/cm;SEM观察显示纱线表面具有连续的镀银层,XRD分析得到镀银涤棉纱线的特征衍射峰与金属纳米银的衍射峰一致。四探针测试镀银导电涤棉纱作纬纱的平纹机织物的方阻为1.49Ω/□,在施加电压1.5 V时,约50 s后织物的温度达到50.9℃,以镀银导电涤棉纱作为纬纱制备的织物具备良好的电加热性能。

MXene/锦纶导电织物的制备及其电加热性能

以自制MXene(Ti_(3)C_(2)Tx)配制去离子水分散液,将锦纶织物浸渍到该分散液中得到MXene/锦纶导电织物。通过调整MXene分散液质量浓度、单次浸渍时间和浸渍次数,以方块电阻为指标,得到MXene/锦纶导电织物制备较优工艺,制备MXene/锦纶织物的方块电阻为(524±38)Ω/。然后用SEM照片、FTIR光谱和TGA曲线对其进行表征。利用阶跃电压测试和恒定电压循环测试表征电加热性能。结果表明,MXene/锦纶织物具有稳定可靠的电加热功能。

一款电加热羽绒服的加热性能评价

本文采用升温试验和GB/T11048-2008标准方法测试了一款电加热羽绒服的加热保温性能.通过数据结果对比发现该款电加热羽绒服在同等充电条件下,充电过程与起始温度具有一定的关系,其提升温度并不会等比例增加.同时对比同款普通羽绒服,可充电加热羽绒服可以小幅度提高其保温性能.

氧化石墨烯薄膜还原程度对测温与电热性能的影响

由于质量轻、韧性好、价格低廉且成型工艺简单等诸多优点,还原氧化石墨烯(reduced graphene oxide,rGO)薄膜在温度传感和电加热等领域颇受关注。分析了经不同温度热还原的rGO薄膜在微观结构、键合种类、力学及电学性能上的差异,以探究还原程度对rGO薄膜测温与加热能力的影响。结果表明,氧化石墨烯(graphene oxide,GO)薄膜内的C-O、C=O等含氧官能团在200℃还原后明显减少,碳原子的主要键合类型由C-C键变为C=C键。当还原温度升至600℃时,rGO薄膜内仍保留了部分含氧羟基官能团,C/O为7.18,而经800℃还原的rGO薄膜成分已趋近石墨烯。随着还原程度的增大,rGO薄膜的电阻率呈明显下降趋势,但氧原子的析出破坏了rGO薄膜的层间致密结构,使拉伸强度逐渐降低。当还原温度达到600℃时,电阻-温度曲线表现出优异的线性关系,室温电阻温度系数(temperature coefficient of resistance,TCR)为-1.60×10^(-3)/℃。在24 V直流驱动电压下,经600和800℃热还原的rGO薄膜可分别加热至242和367℃,但由于层间结构的松散和开裂,经800℃热还原的rGO薄膜的自发热升温曲线波动明显。因此,对于要求加热和测温双功能的应用场景,经600℃还原的rGO薄膜表现出更好的综合性能。

基于3D打印的CNT/PLA复合材料性能研究

通过熔融沉积成型(FDM)技术制备了碳纳米管(CNT)/聚乳酸(PLA)复合薄膜,研究了复合薄膜厚度对其电磁屏蔽性能和电加热性能的影响,同时考察了基于CNT/PLA复合薄膜的压阻式传感器的性能。结果表明:厚度为4 mm的CNT/PLA复合薄膜在频率为11.4 GHz下的电磁屏蔽效能为40.8 dB;在14 V的电压下,厚度为4 mm的CNT/PLA复合薄膜的表面最高温度可以达到65.9℃,且通过连续3次开关电压,其表面最高温度可稳定在65.9℃并持续1000 s;制备的压阻式传感器在压力为0~10 kPa和10~100 kPa下的灵敏度分别为0.043 kPa-1和0.004 kPa-1,具有良好的稳定性和分辨率。

石墨烯/聚丙烯腈皮芯结构纤维成型构筑及功能性

为开发新型复合纤维材料,提出以石墨烯为导电基材一步法构筑导电纤维的研究策略,采用微流控湿法纺丝工艺制备石墨烯/聚丙烯腈皮芯结构复合纤维,探究皮层和芯层纺丝液流量对石墨烯取向排列、纤维导电和电热性能影响规律。通过微观形貌观察发现,复合纤维皮层石墨烯取向随着纺丝液流量的变化呈现先增加后减小的趋势,皮层流量为0.10 mL/min时石墨烯取向最佳。高度取向的石墨烯赋予复合纤维优异的力学性能和导电性能,使复合纤维的强度和电导率分别达到241.38 MPa和3.94 S/cm。在4 V电压下,复合纤维表面的温度达到约48.3℃,热响应速率为2.0℃/s。研究表明通过调控不同的皮芯流量,调整复合纤维的结构和性能,可以成功制备出以石墨烯为基材的复合导电纤维。研究结果可为石墨烯复合加热纤维的开发提供参考。

Electrical conductivity of (Na_3AlF_6-40%K_3AlF_6)-AlF_3-Al_2O_3 melts

The effects of contents of AlF3 and Al2O3, and temperature on electrical conductivity of （Na3AlF6-40%K3AlF6）- AlF3-Al2O3 were studied by continuously varying cell censtant （CVCC） technique. The results show that the conductivities of melts increase with the increase of temperature, but by different extents. Every increasing 10 ℃ results in an increase of 1.85 × 10^-2, 1.86× 10^-2, 1.89 × 10^-2 and 2.20 × 10^-2 S/cm in conductivity for the （Na3AlF6-40%K3AlF6）-AlF3 melts containing 0%, 20%, 24%, and 30% AlF3, respectively. An increase of every 10 ℃ in temperature results an increase about 1.89× 10^-2, 1.94 × 10^-2, 1.95 × 10^-2, 1.99× 10^-2 and 2.10× 10^-2 S/cm for （Na3AlF6-40%K3AlF6）-AlF3-Al2O3 melts containing 0%, 1%, 2%, 3% and 4% Al2O3, respectively. The activation energy of conductance was calculated based on Arrhenius equation. Every increasing 1% of AlF3 results in a decrease of 0.019 and 0.020 S/cm in conductivity for （Na3AlF6-40%K3AlF6）-AlF3 melts at 900 and 1 000 ℃, respectively. Every increase of 1% Al2O3 results in a decrease of 0.07 S/cm in conductivity for （Na3AlF6-40%K3AlF6）-AlF3-Al2O3 melts. The activation energy of conductance increases with the increase in content of AlF3 and Al2O3.

Numerical simulation and experimental study on electrothermal properties of carbon/glass fiber hybrid textile reinforced concrete

Carbon/glass fiber hybrid textile reinforced concrete is a relatively new composite material with good mechanical capacity and excellent electrical conductivity.Both small-scale slab heating experiments and numerical simulation are presented in this paper.Temperature variation curves obtained during heating indicate the effects of environmental temperature,heat-conducting layer thickness and electric heating power.Comparison of temperature rising between the situations with and without thermal isolation layer is given as well.The results indicate that the textile can form a good conductive heating network and generate enough heat to raise the temperature in the concrete when connected to a power supply,while the resistance of the slab remains stable during the heating.Numerical results are in good accordance with the experiments.Real time snow-melting experiment was conducted to verify the feasibility of deicing.The electrothermal properties of textile can be utilized for deicing and snow melting in a safe,environmentally friendly and efficient way.