基于中子平衡研究增殖燃料实现CANDLE模式的最优配置

寿期内中子通量、核素浓度和功率分布的轴向形状均保持恒定(Constant Axial shape of Neutron flux,nuclide densities and power shape During Life of Energy produced,CANDLE)是实现原位增殖-焚烧(Breed-and-Burn,B&B)模式的一种燃耗策略。CANDLE堆经易裂变燃料或外中子源进行点火,启动后由增殖燃料的燃烧实现自稳运行。若要CANDLE堆自稳运行于k_(eff)=1,必须对堆芯几何及燃料体积分数进行配置优化。最优配置方案可通过蒙特卡罗方法模拟CANDLE堆芯,根据有效增殖因子筛选得出。但该方法需耗费大量的计算时间,若采用1D模型近似模拟,并结合中子平衡方法进行分析,便可大幅节约计算时间,获得具有指导性意义的结果。本文将论证该方法的可行性,并应用该方法估算钠冷贫铀CANDLE堆半径在100 400 cm、燃料体积分数在35%60%变化时的最优配置。

Pulse cleaning flow models and numerical computation of candle ceramic filters

Analytical and numerical computed models are developed for reverse pulse cleaning system of candle ceramic filters. A standard turbulent model is demonstrated suitably to the designing computation of reverse pulse cleaning system from the experimental and one dimensional computational result. The computed results can be used to guide the designing of reverse pulse cleaning system, which is optimum Venturi geometry. From the computed results, the general conclusions and the designing methods are obtained.

NIR-responsive Collagen-based Sponge Coated with Polydimethylsiloxane/Candle Soot for Oil-Water Separation

To fabricate an oil-water separation material that is rich in source,eco-friendly,and responsive,in this study,we successfully developed a collagen-based sponge for application to oil-water separation based on a green and facile strategy.In this design,widely-available collagen(COL)was used as the substrate:it was immersed in polydimethylsiloxane(PDMS)suspension with candle soot(CS)nanoparticles,followed by hot curing.The resultant sponge(CS/PDMS-COL)possessed good hydrophobicity with a water contact angle of 148.3°under a low PDMS concentration of 2%.The results from field emission scanning electron microscope,Fourier transform infrared spectrometer,X-ray photoelectron spectrometer,and X-ray diffractometry demonstrated the successful coating of CS and PDMS on the surface of COL substrate.The CS/PDMS-COL can adsorb eight oils,with the adsorption capacity for trichloromethane reaching 95 g/g.With benzene as the target adsorbent,the separation efficiency was maintained at no less than 95%even after recycling 20 times.CS/PDMS-COL was also used to separate oil-in-water emulsion.Moreover,the sponge killed bacteria effectively due to its excellent near-infrared photothermal responsiveness.This study provides new insight into the preparation of facile oil-water separation materials based on naturally occurring biomaterials effortlessly.

Hold a Candle to the Devil

Student:1 don't understand the meaning of the phrase nei hu suo chang.Could you ex-plain it please?

Superhydrophobic photothermal coatings based on candle soot for prevention of biofilm formation

Bacterial biofilms formed on the material surfaces have posed a series of serious problems for human health and industries.The treatment of mature biofilms is particularly difficult because they are inher-ently highly resistant against antibiotics and other adverse factors.The prevention is strategically advan-tageous over the treatment,and thus the development of innovative surfaces with capability to inhibit biofilm formation is highly demanded.In this work,we developed a superhydrophobic photothermal coating for prevention of biofilm formation,which was based on candle soot with hierarchical structure and excellent light-to-heat conversion ability.This coating was fabricated by deposition of a candle soot layer on the substrate,followed by sequential chemical vapor deposition of tetraethoxysilane and immo-bilization of fluorinated silane to make the coating robust and superhydrophobic.The resulted coating could repel a majority of bacteria from the surface at the early stage,and then eradicate a small number of bacteria remained on the surface under a short-term irradiation of near-infrared laser.The combi-nation of anti-adhesive property and photothermal bactericidal property endowed the coating with good antibiofilm property to prevent biofilm formation for at least 2 weeks.This coating is facile for deposition on various substrates with good storage stability,showing great potential for diverse practical applications to solve the biofilm-associated problems of materials and devices.

CANDLE综合征

CANDLE综合征是2010年首次报道并命名的一种自身炎症性疾病.以周期性发热、发病年龄早、身高体重发育延迟、躯干、四肢反复发生的紫红色环状斑、眼睑水肿、嘴唇肥厚、脂肪萎缩、腹部膨隆,肝肿大、急性相反应物升高等为主要临床表现.皮损组织病理表现为真皮致密的不典型髓样单个核细胞浸润,混有成熟中性粒细胞、嗜酸性粒细胞、淋巴细胞及组织细胞,偶可累及皮下脂肪,免疫组化：CD68（＋）,LEDER染色（＋）,髓过氧化物酶染色（＋）.CANDLE综合征是一种蛋白酶体相关性单基因遗传病,近年来越来越多的突变位点被发现与CANDLE综合征的发生发展密相关,目前尚无有效的治疗方法.本病严重影响患者生活质量且预后大多不佳,糖皮质激素、免疫抑制剂及一些生物制剂对部分患者可取得一定疗效.

Double layered superhydrophobic PDMS-Candle soot coating with durable corrosion resistance and thermal-mechanical robustness

Nature-inspired superhydrophobic coatings with typical Cassie-Baxter contacts garner numerous interests for multifunctional applications.However,undesirable poor mechanical and thermal stability are still crucial bottlenecks for real-world employment.This work introduces a cost-effective,fluorine free and versatile strategy to achieve double-layered PDMS agglutinated candle soot coating with superior water-repellent superhydrophobicity.The surface morphologies,chemical compositions and wettability behaviors were investigated in detail.The mechanical stability,chemical stability and durable corrosion resistance of the fabricated PDMS-CS coating were evaluated through friction,calcination and electrochemical impedance spectroscopy.The results demonstrate a remarkably enhanced mechanical robustness and corrosion resistance,indicating PDMS units can act as an effective agglutinating agent between candle soot and underlying substrate.The synergistic effect of PDMS agglutination,porous network nanostructures and extremely low surface energy of incomplete combustion induced candle soot deposition contribute to the eventually robust corrosion resisting coating,which greatly increases the possibility for practical applications.

Mathematical Modeling of Flow Field in CeramicCandle Filter

Integrated gasification combined cycle (IGCC) is one of the candidates to achieve stringent environmental regulation among the clean coal technologies. Advancing the technology of the hot gas cleanupsystems is the most critical component in the development of the IGCC. Thus the aim of this study isto understand the flow field in the ceramic filter and the influence of ceramic filter in removal of theparticles contained in the hot gas flow. The numerical model based on the Reynolds stress turbulencemodel with the Darcy’s law in the porous region is adopted. It is found that the effect of the porosityin the flowfield is negligibly small while the effect of the filter length is significant. It is also found asthe permeability decreases, the reattachment point due to the flow separation moves upstream. Thisis because the fluid is sucked into the filter region due to the pressure drop before the flow separationoccurs. The particle follows well with the fluid stream and the particle is directly sucked into the filterdue to the pressure drop even in the flow separation region.

Three-Dimensional Flow Characteristics in One Ceramic Candle Filter

The objective of this study is to characterize the three-dimensional fluid flow in the vessel containing one ceramic candle filter. The three-dimensional governing equations are formulated in this study and the turbulent k - ε model is adopted for the numerical computation. It is found that the viscous force is dominant in the porous region with compared to inertia force. Pressure decreases linearly when the flow passing through the porous medium. When the face velocity is 0.03 m/s, the pressure drop is about 350 Pa. It has also been found that the fluid with the spiral motion to be sunk into the filter in the vessel.

From a Candle to Light

It is a warm morning in spring.The sunlight spills down all over the mountain.Everything seems quiet and peaceful.At the foot of the mountain is a small village. From the flag waving in the wind one can

Numerical Analysis of Flow Field in Ceramic Filter During Pulse Cleaning

In the commercial utilization of rigid ceramic filters, the performance of pulse cleaning has crucial effects on the long-term stable operation. In order to get a clear insight into the nature of this cleaning process and provide a solid basis for industrial applications, the flow in ceramic candle filter was investigated. The flow in the pulse-jetspace and inside the ceramic candle is regarded as two- dimensional, unsteady, compressible flow, and numerical simulation is carried out by computational fluid dynamics. The numerical predictions of flow field are in good agreement with the experimental measurements. Effects of the candle diameter, the separation distance between the nozzle and the candle injector and the length of the candle on the flowfield have been numerically analyzed to provide the basis for the optimum design of the pulse cleaning system.

Shijiazhuang Kelaisi Import & Export Trade Co., Ltd

Shijiazhuang kelaisi Import& Export Trade Co, Based on the concept of Reputation first, Quality first. we win a good fame from overseas clients and establish a good long-term cooperation with each other. Our products include: birthday candle, pillar candle, LED candle, glass candle, spiral candle, wedding candle, white candle, tea light candle and scented candle.

Recent advances in catalytic filters for integrated removal of dust and NOx from flue gas:fundamentals and applications

Catalytic filters including catalytic bag filters and catalytic filter candles, which couple the filters with denitrification catalysts to obtain the ability to simultaneously remove SOx, NOx and dust, have become the promising applied technology for the integrated flue gas treatment because of their huge advantages in reducing the initial investment, floor occupancy and maintenance cost. In this review, we will summarize the recent advances in the development of catalytic filters in terms of their process principles, filter material, denitrification catalysts, structure-function relationships and industrial applications. Moreover, suggestions about the current challenges and future opportunities are also given from the viewpoints of catalysts and filter material design, catalytic filter preparation methods, and their poisoning and regeneration, etc. With the further development of theory and engineering research, the extensive industrial application of catalytic filters in the field of multiple pollutants flue gas treatment is highly anticipated in the future.

A simple chemical method for the synthesis of Cu^(2+) engrafted MgAl_(2)O_(4) nanoparticles: Efficient fluoride adsorbents, photocatalyst and latent fingerprint detection

An adaptable, energy efficient chemical process is employed to synthesize Cu^2+engrafted MgAl2O4 nanoparticles(Mg1-xCuxAl2O4, x = 0, 0.1, 0.3, 0.5 abbreviated as MCA0, MCA1, MCA3,and MCA5 respectively), using chelating ligand and the calcination temperature was determined by the thermogravimetric analysis of the precursor mass.They acted as good fluoride adsorbent in the presence of co-ions, different pH(2–11) via chemisorption revealed from Fourier-transform infrared spectroscopy(FTIR) and photodegraded Methylene Blue(MB).The satisfactory results were for MCA1(specific surface area 25.05 m^2/g) with 97%fluoride removal at pH 7.0 for the 10 mg/L initial fluoride concentration for 1.5 g/L adsorbent dose with 45 min contact time obeying the Langmuir isotherm model with negative thermodynamic parameters and 4 mmol of MCA3 with 98.51% photodegradation for 10-5 mol/L MB solution obeying pseudo-second-order and pseudo-first-order kinetics respectively.The proposed photodegradation mechanism of MB was established by the FTIR and high-performance liquid chromatography(HPLC) analysis.The nanoparticles are cubic, estimated through X-ray diffraction(XRD) and transmission electron microscopy(TEM) analysis.The band gap energies, grain size, and the effective working pH were estimated by diffuse reflectance spectra(DRS), scanning electron microscope(SEM), and zero-point potential analysis respectively.A soil candle with MCA1 also fabricated for the household purpose and tested with some fluorinated field samples.The MCA3 was able to enhance the latent fingerprint on smooth surfaces.

Slippery Photothermal Trap for Outstanding Deicing Surfaces

Ice accumulation is a safety and operational threat in power lines,wind turbines,and transportations.Surfaces having both passive anti-icing and active deicing functionalities are very rare.Here,we report a self-cleaning slippery photothermal trap,which is icephobic passively and deice the surfaces actively by converting sun light to heat at the ice-substrate interface.The photothermal trap consists of three layers:a candle soot layer act as solar radiation absorber,a magnetic iron oxide Fe_(3)O_(4) nanoparticles layer act as heat spreader for lateral dispersal of sun light,and Room Temperature Vulcanized(RTV)insulation to reduce the transverse heat loss.Upon illumination under microsolar 300,the temperature of the surface increased by 40℃ within 200 s.The heat confinement at the magnetic Fe_(3)O_(4) na-noparticles layer leads to rapid increase of the surface temperature,ice start to melt and silicone lubricant facilitates the ice removal.The slippery photothermal trap removed the frozen droplet(10 fiL)within 40 s upon the illumination of sun light and the frozen droplet was completely converted into water after 7 min illumination of solar light at-20℃.The developed slippery photothermal trap also melted the fully frost covered layer within 100 s at-20℃ under sunlamp.The average defrosted length(25 mm)was also observed by irradiation of laser light for 45 s.The self-cleaning slippery photothermal coating showed outstanding deicing performance at subzero temperature for long term due to the infusion of silicone oil into the nanostructures and same chemical composition with binder.