5 results on '"Zhang, Zelin"'
Search Results
2. Effect of characteristic structure of nested composite hybrid rocket fuel grain on combustion properties.
- Author
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Wang, Ruoyan, Lin, Xin, Wang, Zezhong, Wu, Kun, Pan, Junjie, Zhang, Zelin, Luo, Jiaxiao, Li, Fei, and Yu, Xilong
- Subjects
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ROCKET fuel , *COMBUSTION , *COMBUSTION efficiency , *COMPOSITE structures , *SWIRLING flow , *HELICAL structure - Abstract
This work numerically and experimentally investigated the effect of the characteristic structure of nested composite fuel grains on their combustion properties. The characteristic structure comprised multiple helical grooves inside the fuel grain port, which formed during the combustion process. Three-dimensional steady-state simulations were employed to analyze the burning behavior of composite fuel grains with different scales of the characteristic structure (i.e., groove depth) of 0, 1, and 2 mm. An obvious swirl-gas flow field and large tangential velocity appeared for fuel grains with the characteristic structure, which was conductive to enhancing the propellant mixing. A larger flame region and more intense burning were correspondingly achieved, during which greater amounts of H 2 O and CO 2 were generated than by fuel grain without the characteristic structure. Numerical results verified that the characteristic structure was theoretically beneficial to improving the combustion properties of the grains. Firing experiments were conducted using a laboratory-scale hybrid rocket engine with oxygen as the oxidizer. The flame structure and pulsation features were synchronously analyzed using a radiation imaging technique. Pure paraffin-based fuel grains with a circular port were tested for comparison. Both regression rates and combustion efficiencies of the composite fuel grains with characteristic structure scales of 1 mm and 2 mm showed significant improvement. The flame images exhibited an obvious helical shape and large area, which was consistent with the numerical analysis. Both the numerical and experimental results confirmed that the helical characteristic structure in the composite fuel grain played a key role in enhancing the combustion properties and demonstrate potential for further development. • The characteristic structure improved the combustion properties of composite grain. • Combustion properties improving mechanisms were studied numerically and experimentally. • Radiation imaging was employed to assess the flame pulsation features. • Experimental results were consistent well with the numerical results. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
3. Study of the effect of DC high-voltage electric fields on the regression rate of PMMA.
- Author
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Yang, Xiaolong, Wei, Zhijun, Zhang, Zelin, and Zhang, Jingjia
- Subjects
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ELECTRIC fields , *ELECTRIC field effects , *ROCKET engines , *HIGH voltages , *ELECTRIC potential - Abstract
Due to great demands on solid rocket motors and solid ramjets for thrust control, a study of the effect of high-voltage electric fields on the regression rate of polymethyl methacrylate (PMMA) has been undertaken. The flame shape was recorded by a CMOS camera. The regression rate of PMMA was measured. A numerical model of fluid-solid coupling, which is based on experiment and considers physico-chemical phenomena associated with the flame-field interaction process, has been developed to explain experimental observations. In order to reduce the computational workload, the radiation loss, including the soot radiation is not considered in the numerical simulation. The mechanism of the effect of electric fields on the regression rate of PMMA is analysed. The numerical simulation shows that the change of the regression rate of a PMMA tip under the action of electric fields is consistent with experimental results. Studies show that electric fields can change the regression rate of PMMA, increasing it by about 38%. The regression rate on the burning surface is increased when subjected to positive electric fields. Under a negative electric field, part of the burning surface is subjected to an increased regression rate, and some thereof is subjected to a decreased regression rate. The effect of electric fields on the regression rate of PMMA is mainly due to the interaction of buoyancy and the electric field induced volumetric body forces. • Electric fields can change the regression rate of PMMA. • The change of the regression rate was closely related to applied voltage. • The change of the regression rate was due to the action of buoyancy and"ionic wind". [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
4. Determining the time-resolved mass flow rates of hybrid rocket fuels using laser absorption spectroscopy.
- Author
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Wang, Zezhong, Lin, Xin, Li, Fei, Peng, Jinlong, Liu, Yan, Zhang, Zelin, Fang, Sihan, and Yu, Xilong
- Subjects
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LASER spectroscopy , *TIME-resolved spectroscopy , *ROCKET fuel , *COMBUSTION efficiency , *TUNABLE lasers , *EQUATIONS of state , *SEMICONDUCTOR lasers - Abstract
A non-intrusive method for determining the time-resolved fuel mass flow rate in a hybrid rocket engine is proposed based on tunable diode laser absorption spectroscopy (TDLAS). The present work performed experimental tests using oxygen/paraffin as the propellant in a laboratory-scale hybrid rocket engine, applying oxidizer-to-fuel ratios in the range of 2.5–2.9 corresponding to combustion chamber pressures of 1.68–2.46 MPa. Variations in temperature and H 2 O partial pressure at the nozzle outlet were determined adopting TDLAS based on H 2 O absorption near 2.5 μm. Three H 2 O absorption lines at 4029.5, 4030.6 and 4030.7 cm−1 were simultaneously measured using only one diode laser at 2.0 kHz repetition rate and adopting a scanned-wavelength direct absorption strategy. The airflow velocity at the nozzle outlet was ascertained in two-dimensional numerical simulations. In this manner, the time-resolved fuel mass flow rate participating in combustion can be derived from the ideal state equation. A detailed discussion of the measurement uncertainty was provided herein considering the influence from determination of temperature, H 2 O partial pressure and velocity. The effectiveness of the novel method was validated by comparing its results with that acquired with the traditional weight-loss technique. Finally, it is initially analyzed that the combustion efficiency of pure paraffin fuel gradually increases during the combustion process according to the measurement results. • An optical fuel mass flow measurement method for hybrid rocket engines is proposed. • The quantitative fuel mass flow rate participating in combustion is obtained. • A compact tunable diode laser absorption spectroscopy system was designed. • Variations of temperature and H 2 O partial pressure at the nozzle exit were diagnosed. • Combustion characteristics of the oxygen/paraffin hybrid rocket were discussed. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
5. Numerical study of the effect of electric fields on the combustion characteristics of PMMA under lateral inflow.
- Author
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Yang, Xiaolong, Wei, Zhijun, Zhang, Jingjia, Zhang, Zelin, and Wang, Ningfei
- Subjects
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ELECTRIC field effects , *HEAT of reaction , *ELECTRIC fields , *COMBUSTION , *FLAME temperature - Abstract
To satisfy the demand for thrust control on solid rocket motors and solid ramjet engines, numerical simulation of the effect of high-voltage electric fields on the combustion characteristics of polymethyl methacrylate (PMMA) under lateral inflow was undertaken. The mechanism of the effect of electric fields on the regression rate and mass flow rate of PMMA was analyzed. The results show that PMMA mass flow rate can increase by about 54% when subjected to positive voltages. The PMMA mass flow rate can not only increase by about 5.5% but also decrease by about 14% under the action of negative voltages. When the oxygen mass fraction is 54.5% at 0.101 MPa, the effect of electric fields on PMMA mass flow is weakened as the lateral velocity increases. When the inflow velocity is 1.95 m s−1 and oxygen mass fraction is 23.2%, the effect of electric fields on PMMA mass flow is decreased as the pressure rises. The effect of electric fields on PMMA regression rate is mainly due to the electric-field-induced volumetric body force. It will result in large-scale bulk flow movement, known as ionic wind, which changes the distribution of species and affects the heat of reaction, thus causing the changes in flame temperature, finally altering the thermal feedback to the solid phase. • Electric fields can change PMMA regression rate and mass flow rate. • The change of PMMA mass flow rate was closely related to applied voltages. • The change of the regression rate was due to electric body force. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
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