基于MTBF的光电感烟探测器可靠性研究

针对火灾探测报警系统重要组成模块—光电感烟探测器-报警控制器,根据其在实际使用过程中的不完全故障数据,改良了前人对该问题的传统研究方法,并提出了分段定时截尾可靠性参数模型。该模型主要考虑火灾探测报警系统控制器工作时序性和故障处理时间的影响,采用自主提出的原始故障数据筛选统计方法,分别求得光电感烟模块的首次使用寿命与平均故障间隔时间的参数估计。该方法能够减少火灾探测报警系统初始使用寿命过长而产生的平均故障间隔时间的估计偏差,对于火灾探测报警系统整体使用寿命的估计和维修管理有着重要意义。同时基于序贯思想的动态截尾也克服了定时截尾模型无法准确判断试验停止时间的不足,在保证参数较为精确的前提下最大限度地节省时间和资源。     

Breakthrough CO2 adsorption in bio-based activated carbons

In this work, the effects of different methods of activation on CO₂ adsorption performance of activated carbon were studied. Activated carbons were prepared from biochar, obtained from fast pyrolysis of white wood, using three different activation methods of steam activation, CO₂ activation and Potassium hydroxide (KOH) activation. CO₂ adsorption behavior of the produced activated carbons was studied in a fixed-bed reactor set-up at atmospheric pressure, temperature range of 25–65°C and inlet CO₂ concentration range of 10–30 mol% in He to determine the effects of the surface area, porosity and surface chemistry on adsorption capacity of the samples. Characterization of the micropore and mesopore texture was carried out using N₂ and CO₂ adsorption at 77 and 273 K, respectively. Central composite design was used to evaluate the combined effects of temperature and concentration of CO₂ on the adsorption behavior of the adsorbents. The KOH activated carbon with a total micropore volume of 0.62 cm³/g and surface area of 1400 m²/g had the highest CO₂ adsorption capacity of 1.8 mol/kg due to its microporous structure and high surface area under the optimized experimental conditions of 30 mol% CO₂ and 25°C. The performance of the adsorbents in multi-cyclic adsorption process was also assessed and the adsorption capacity of KOH and CO₂ activated carbons remained remarkably stable after 50 cycles with low temperature (160°C) regeneration.