• Title/Summary/Keyword: $CO_2$열반응

Search Result 3, Processing Time 0.017 seconds

Effects of Solid Propellant Cases on the Thermal Response of Nozzle Liner (노즐 내열재 열반응에 미치는 고체 추진제 연소가스의 영향)

  • Hwang, Ki-Young;Yim, Yoo-Jin;Ham, Hee-Cheol;Kang, Yoon-Goo;Bae, Joo-Chan
    • Journal of the Korean Society of Propulsion Engineers
    • /
    • v.11 no.2
    • /
    • pp.26-36
    • /
    • 2007
  • The thermal response characteristics of nozzle liner for a solid rocket motor applying highly aluminized PCP or HTPB propellant with slotted tube grain have been investigated. The SEM photographs of aluminum oxide particles taken from nozzle liner show that the PCP propellant with the finer and less contents of oxidizer can offer greater possibility for increasing aluminum agglomeration than the HTPB propellant. The PCP propellant shows locally greater mechanical erosion at 4 circumferential areas of the nozzle entrance in line with grain slot due to the impingement of large particles, but the HTPB propellant shows greater thermochemical ablation at the nozzle blast tube, the throat insert and the exit cone because of relatively much more mole fraction of $H_2O\;and\;CO_2$ in combustion gases.

Recoverty of Lithium Carbonate and Nickel from Cathode Active Material LNO(Li2NiO2) of Precursor Process Byproducts (전구체 공정부산물 LNO(Li2NiO2)계 양극활물질로부터 탄산리튬 및 니켈 회수연구)

  • Pyo, Je-Jung;Wang, Jei-Pil
    • Resources Recycling
    • /
    • v.28 no.4
    • /
    • pp.30-36
    • /
    • 2019
  • In this study, Li powder was recovered from the by-product of LNO ($Li_2NiO_2$) process, which is the positive electrode active material of waste lithium ion battery, through the $CO_2$ thermal reaction process. In the process of recovering Li powder, the $CO_2$ injection amount is 300 cc/min. The $Li_2NiO_2$ award was phase-separated into the $Li_2CO_3$ phase and the NiO phase by holding at $600^{\circ}C$ for 1 min. After this, the collected sample:distilled water = 1:50 weight ratio, and after leaching, the solution was subjected to vacuum filtration to recover $Li_2CO_3$ from the solution, and the NiO powder was recovered. In order to increase the purity of Ni, it was maintained in $H_2$ atmosphere for 3 hours to reduce NiO to Ni. Through the above-mentioned steps, the purity of Li was 2290 ppm and the recovery was 92.74% from the solution, and Ni was finally produced 90.1% purity, 92.6% recovery.

Thermal Decomposition and Ablation Analysis of Solid Rocket Propulsion (삭마 및 열분해 반응을 고려한 고체 추진기관의 열해석)

  • Kim, Yun-Chul
    • Journal of the Korean Society of Propulsion Engineers
    • /
    • v.14 no.5
    • /
    • pp.32-44
    • /
    • 2010
  • A two-dimensional thermal response and ablation analysis code for predicting charring material ablation and shape change on solid rocket nozzle is presented. The thermogravimetric analysis (TGA) techniques have been used to characterize the thermal decomposition constants for Arrhenius parameters. Two heterogeneous reactions involving carbon and the oxidizing species of $H_2O$ and $CO_2$ are considered and determined by Zvyagin's ablation model and kinetic constants. The moving boundary problem and mesh moving are solved by remeshing-rezoning method in MSC-Marc-ATAS program. The difference between the calculated and experimental value of char and ablation thickness is up to 20%. For the performance prediction of thermal protection systems, this method will be integrated with a three-dimensional finite-element thermal and structure analysis code through the real time sensing of in-depth temperature and heat flux.