• 제목/요약/키워드: 맥동 유동

검색결과 148건 처리시간 0.024초

1/4 음향공에 의한 연소실 음향거동 해석 (Analysis of Acoustic Behavior of Combustion Chambers with Quarter Wave Cavity)

  • 조용호;윤웅섭
    • 한국추진공학회:학술대회논문집
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    • 한국추진공학회 1998년도 제10회 학술강연회논문집
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    • pp.28-28
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    • 1998
  • 고주파 연소불안정은 거의 모든 로켓엔진의 개발 프로그램에서 보고되고 있으며, 이 문제의 해결을 위한 많은 연구들이 진행되어 왔다. 고주파 연소불안정은 로켓엔진 연소실 내에서의 연소와 유동변수들이 커플링되어 발생한다. 연소가스의 음향파동은 연소의 외란을 야기하며 외란된 연소는 유동변수들에 맥동에너지를 공급하는 되먹임 과정을 반복하게 된다. 결과적으로 음향파에 의한 외란의 크기, 위상 및 되먹임 과정에서의 파동에너지 감쇠량에 따라 불안정한 파동은 증폭, 유지되거나 소멸된다.

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관성관 맥동관 극저온 냉동기의 유동 특성 모델링 (MODELING ON FLOW CHARACTERISTICS OF INERTANCE PULSE TUBE CRYOCOOLER)

  • 한성현;이경환;최종욱;김재수
    • 한국전산유체공학회지
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    • 제19권3호
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    • pp.14-19
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    • 2014
  • The flow characteristics of inertance pulse tube cryocooler(IPTC) was investigated with a computational thermal fluid dynamics for the reciprocating flow in IPTC including the piston movement of linear compressor. Two dimensional axisymmetric modeling was applied for the flow in an IPTC with a clearance between the piston and cylinder wall of linear compressor. The pressure, velocity, and temperature distribution were examined for the steady state. These were compared with previous results to confirm the validity in the modeling and computational results. The leakage between piston and cylinder wall affect the cooling capacity seriously. The dependence on mesh numbers were also examined to obtain a proper mesh numbers to improve the accuracy of calculation, which showed significant effect on the results. The user-defined function was used for the process of compression and expansion of piston.

판형 열교환기에서 맥동유동이 냉매의 증발에 미치는 영향 (Effects of Pulsating Flow on Evaporation of Refrigerant in a Plate Heat Exchanger)

  • 강병하;정일권;김석현
    • 설비공학논문집
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    • 제18권8호
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    • pp.627-634
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    • 2006
  • Evaporation heat transfer characteristics by pulsating flow in a plate heat exchanger have been investigated experimentally in this study. R-l34a is evaporated by receiving heat from the hot water in the plate heat exchanger. The pulsating frequency in refrigerant side of the plate heat exchanger is varied in the range of 5-25 Hz. The operating pressure of R-l34a and mass flux of hot water are also varied 0.6-0.9 MPa and $45-105 kg/m^2s$, respectively. The experimental results indicate that evaporation heat transfer coefficient of pulsating flow is improved up to 6.3% compared with that of the steady flow at 10 Hz and $G_w=45 kg/m^2s$. It is also found that the evaporation heat transfer enhancement ratio is decreased with an increase in mass flux of hot water, and the evaporation heat transfer enhancement is little influenced by operating pressure of R-l34a.

곡관덕트에서 난류맥동유동의 축방향 속도분포와 2차유동분포에 관한연구 (A Study on the Axial Velocity and Secondary Flow Distributions of Turbulent Pulsating Flow in a Curved Duct)

  • 손현철
    • 한국마린엔지니어링학회:학술대회논문집
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    • 한국마린엔지니어링학회 2000년도 춘계학술대회 논문집(Proceeding of the KOSME 2000 Spring Annual Meeting)
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    • pp.127-133
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    • 2000
  • In the present study flow characteristics of turbulent pulsating flow in a square-sectional 180。 curved duct are investigated experimentally. in order to measure axial velocity and secondary flow distributions experimental studies for air flow are conducted in a square-sectional $180^{\circ}$ curved duct by using the LDV system with the data acquisition and the processing system of the Rotating Machinery Resolver (RMR) and the PHASE software. The experiment is conducted on seven sections form the inlet(${\phi}=180^{\circ}$) at $30^{\circ}$ intervals of the duct. The results obtained from the experimentation are summarized as follows : In the axial velocity distributions of turbulent pulsating flow when the ratio of velocity amplitude(A1) is less than one there is hardly any velocity change in the section except near the wall and any change in axial velocity distribution along the phase. The secondary flow of turbulent pulsating flow has a positive value at the vend angle of $150^{\circ}$ without regard to the ratio of velocity amplitude. The dimensionless value of secondary flow becomes gradually weak and approaches zero in the region of bend angle $180^{\circ}$ without regard to the ratio of velocity amplitude.

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원관내 뉴턴유체와 비뉴턴유체의 맥동유동특성 (Pulsatile Flow Analyses of Newtonian Fluid and Non-Newtonian Pluid in Circular Tube)

  • 조민태;노형운;서상소;김재수
    • 대한기계학회논문집B
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    • 제26권11호
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    • pp.1585-1596
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    • 2002
  • The objectives of the present study are to numerically and experimentally investigate the steady and pulsatile flow phenomena in the circular tubes, to quantitatively compare the flow characteristics of Newtonian and non-Newtonian fluids, and to find meaningful hemodynamic information through the flow analysis in the human blood vessels. The particle image velocimetry is adopted to visualize the flow fields in the circular tube. and the results from the particle image velocimetry are used to validate the results of the numerical analysis. In order to investigate the blood flow phenomena in the circular tube. constitutive equations, which are suitable to describe the rheological properties of the non-Newtonian fluids. are determined, and the steady and pulsatile momentum equations are solved by the finite volume prediction. The velocity vectors of the steady and pulsatile flow in the circular tube obtained by the particle image velocimetry arc in good agreement with those by the numerical analysis. For the given mass flow rate. the axial velocity profiles of the Newtonian and the non-Newtonian fluids appear differently. The pulsatile flow phenomena of the Newtonian and the non-Newtonian fluids are quite different from those of the steady flow.

CFD에 의한 용적형수차의 압력맥동 및 내부유동 해석 (CFD Analysis of Pressure Pulsation and Internal Flow for a Positive Displacement Hydraulic Turbine)

  • 최영도;김유택;이영호
    • Journal of Advanced Marine Engineering and Technology
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    • 제31권6호
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    • pp.687-693
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    • 2007
  • It has been known that one of the main obstacles of improving the performance of positive displacement hydraulic turbine is pressure pulsation which occurs at the regions upstream and downstream of the turbine. In order to suppress the pressure pulsation. occurrence reason of the pressure pulsation should be understood in detail Therefore. this study aims to establish a CFD analysis method by which the phenomena of unsteady pressure pulsation can be examined with high accuracy. Internal flow field of the turbine is modeled simply to generalize the relation between the pressure pulsation and internal flow. The results show that the Present CFD method adopting unsteady calculation can be applied successfully to the analysis of the Phenomena of Pressure Pulsation. Occurrence of the Pressure pulsation is due to the difference of the rotational speed of turbine rotors When driving rotor rotates by uniform speed and fellowing rotor rotates by variable speed, very large Pressure pulsation occurs within the turbine periodically.

맥동유동이 판형 열교환기 성능에 미치는 영향 (Effects of Pulsating Flow on the Performance of a Plate Heat Exchanger)

  • 강병하;김도균;박경근
    • 대한기계학회:학술대회논문집
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    • 대한기계학회 2003년도 춘계학술대회
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    • pp.1479-1484
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    • 2003
  • The heat transfer enhancement by pulsating flow in a plate heat exchanger has been experimentally investigated in this study. The effect of the pulsating flow, such as pulsating frequency and flow rate, on the heat transfer as well as pressure drop in a plate heat exchanger has been studied in detail. Reynolds number in cold side of a plate heat exchanger is varied $100{\sim}530$ while that of hot side is fixed at 620. The pulsating frequency is considered in the range of $5{\sim}30$ Hz. The results of the pulsating flow are also compared with those of steady flow. It is found that the average heat transfer rate as well as pressure drop is increased as flow rate is increased for both steady flow and pulsating flow cases. When pulsating flow is applied to the plate heat exchanger, heat transfer could be substantially increased in particular ranges of pulsating frequency or Strouhal number; $St=0.36{\sim}0.60$ and pressure drop is also increased, compared with those of steady flow.

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뉴턴유체와 혈액의 맥동유동시 탄성혈관의 운동이 벽면전단응력분포에 미치는 영향 (Effects of Elastic Blood Vessel Motions on the Wall Shear Stresses for Pulsatile Flow of a Newtonian Fluid and Blood)

  • 노형운;김재수;박길문;서상호
    • 대한기계학회:학술대회논문집
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    • 대한기계학회 2001년도 추계학술대회논문집B
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    • pp.318-323
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    • 2001
  • Characteristics of the pulsatile flow in a 3-dimensional elastic blood vessel are investigated to understand the blood flow phenomena in the human body arteries. In this study, a model for the elastic blood vessel is proposed. The finite volume prediction is used to analyse the pulsatile flow in the elastic blood vessel. Variations of the pressure, velocity and wall shear stress of the pulsatile flow in the elastic blood vessel are obtained. The magnitudes of the velocity waveforms in the elastic blood vessel model are larger than those in the rigid blood vessel model. The wall shear stresses on the elastic vessel vary with the blood vessel motions. Amplitude indices of the wall shear stress for blood in the elastic blood vessel are $4\sim5$ times larger than those of the Newtonian fluid. As the phase angle increased, point of the phase angle is are moved forward and the wall shear stresses are increased for blood and the Newtonian fluid.

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판형 열교환기에서 맥동유동에 의한 열전달 촉진에 관한 실험적 연구 (Heat Transfer Enhancement by Pulsating Flow in a Plate Heat Exchanger)

  • 김도규;강병하;김석현
    • 대한기계학회논문집B
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    • 제28권2호
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    • pp.199-206
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    • 2004
  • The heat transfer enhancement by pulsating flow in a plate heat exchanger has been experimentally investigated in this study. The effect of the pulsating flow, such as pulsating frequency and flow rate on the heat transfer as well as pressure drop in a plate heat exchanger has been studied in detail. Reynolds number in cold side of a plate heat exchanger is varied 100∼530 while that of hot side is fixed at 620. The pulsating frequency is considered in the range of 5∼30 Hz. The results of the pulsating flow are also compared with those of steady flow. It is found that the average heat transfer rate as well as pressure drop is increased as flow rate is increased for both steady flow and pulsating flow cases. When pulsating flow is applied to the plate heat exchanger, heat transfer could be substantially increased in particular ranges of pulsating frequency or Strouhal number; St=0.36∼0.60 and pressure drop is also increased, compared with those of steady flow. However, in the region of low pulsating frequency or high pulsating frequency, heat transfer enhancement is in meager. Heat transfer enhancement map is suggested based on Strouhal number and Reynolds number of pulsating flow.