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# | Type | Title | Author | Publisher | Pub. Year | Subjects | Call Number |
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61 | مقاله | A novel hydro magnetic micro-pump and flow controller | Alavi Dehkordi, E. | 2008 |
10 micron.
Carrier liquid. Characteristic curve. Constant pressures. External magnetic field. Flow controllers. Magnetic particle. Magnetic system. Micro pump. Micro valves. Microtube. Nickel particles. Optimum switching. Pressure-driven. Pumping performance. Specific sites. Switching modes. Switching time. Working fluid. Engines. Ethanol. Fluids. Magnetic fields. Magnetic materials. Microchannels. Pumps. Solenoids. Switching. |
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62 | مقاله | Experimental investigation of on-demand ferrofluid droplet generation in microfluidics using a Pulse-Width Modulation magnetic field with proposed correlation | Bijarchi, M. A. | Elsevier B.V, | 2021 |
Drop formation.
Pulse width modulation. Voltage control. Average relative error. Capillary numbers. DC magnetic field. Droplet generation. Experimental investigations. Formation process. Generation frequency. Nondimensionalized parameter. Magnetic fields. |
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63 | مقاله | A review on application of nanofluid in various types of heat pipes | Nazari, M. A. | Central South University of Technology, | 2019 |
Heat pipe.
Nanofluid. Thermal resistance. Heat pipes. Heat resistance. Heat transfer performance. Nanoparticles. Thermal conductivity. Dynamic viscosities. Heat transfer capability. Heat transfer device. Literature reviews. Nanofluids. Pulsating heat pipe. Thermal Performance. Types of heat pipes. Nanofluidics. |
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64 | مقاله | Overall thermal performance of ferrofluidic open loop pulsating heat pipes: An experimental approach | Taslimifar, M. | 2013 |
Non-condensable gases (NCGs)
Open loop pulsating heat pipes (OLPHPs) Heating power. Loop pulsating heat pipes. Non-condensable gas. Steady. Fluids. Heat transfer. Magnetic fields. Reactor startup. Mixed convection. |
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65 | مقاله | Two-dimensional numerical investigation of a micro combustor | Irani Rahaghi, A. | 2010 |
Advection-diffusion-reaction.
Computational domains. Conservation equations. Convective heat transfer Coefficient. Cross-section profile. External convection. Flow characteristic. Gasphase. Heat transfer rate. Mass flow rate. Mass fraction. Micro combustion. Micro-scales. Mixture velocity. Multi-step. Numerical. Numerical approaches. Numerical investigations. Numerical results. Premixed. Slip flow. Stiff systems. Strang splitting. Thermal creep. Velocity equation. Boundary conditions. Combustion. Computational fluid dynamics. Creep. Heat convection. Heat transfer coefficients. Two dimensional. Combustors. Convection. Heat transfer. Numerical model. Two-dimensional modeling. |
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66 | مقاله | Visualization and comparative investigations of pulsating ferro-fluid heat pipe | Gandomkar, A. | Elsevier Ltd, | 2017 |
Ferrofluid.
Flow regime. PHP. Thermal resistance. Visualization. Copper. Electronic cooling. Flow visualization. Glass. Heat resistance. Heat transfer. Magnetic fields. Magnetic fluids. Magnetism. Electronics cooling. Filling ratio. Flow regimes. Heat transfer performance. Low costs. Nanofluids. Pulsating heat pipe. Heat pipes. |
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67 | مقاله | Investigation and visualization of surfactant effect on flow pattern and performance of pulsating heat pipe | Gandomkar, A. | Springer Netherlands, | 2020 |
Flow regime.
PHP. Surface tension. Surfactant. Thermal resistance. Visualization. Cooling systems. Electronic cooling. Energy conversion. Flow patterns. Heat flux. Heat pipes. Heat resistance. Surface active agents. Surface tension. Aerospace systems. Distribution of temperature. Flow regimes. Maximum heat flux. Pulsating heat pipe. Surfactant concentrations. Surfactant effects. Visualization results. Flow visualization. |
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68 | مقاله | Experimental evaluation of forced convective heat transfer of Fe3O4 ferrofluid in a horizontal u-shaped tube under variable magnetic field effect based on Taguchi approach | Eslahchi, A. | Springer Science and Business Media Deutschland GmbH, | 2021 |
Analysis of variance (ANOVA)
Heat flux. Heat transfer coefficients. Iron oxides. Magnetic fields. Magnetite. Nanomagnetics. Nanoparticles. Reynolds number. Taguchi methods. Tubes (components) Effect of parameters. Experiment design. Experimental evaluation. Forced convective heat transfer. Frequency parameters. Horizontal surfaces. Magnetic field frequency. Thermal boundary conditions. Heat convection. |
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69 | مقاله | Thermal conductivity of mixed nanofluids under controlled pH conditions | Iranidokht, V. | 2013 |
Brownian motion.
EDL. Mixed nanofluid. Surfactant. Thermal conductivity. Electrical double layers. High thermal conductivity. Low thermal conductivity. Metallic nanoparticles. Nanofluids. Reduction of thermal conductivity. Theoretical modeling. Electric properties. Surface active agents. Brownian movement. Metallic compounds. Nanofluidics. Nanoparticles. Thermal conductivity of liquids. |
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70 | مقاله | Thermal characteristics of closed loop pulsating heat pipe with nanofluids | Jamshidi, H. | 2011 |
Closed loop pulsating heat pipe (CLPHP)
Two-phase flow. Closed loop pulsating heat pipes. Copper tubes. Dry-out. Evaporator temperature. Filling ratio. Inclination angles. Mass concentration. Nanofluid. Nanofluids. Optimal conditions. Optimum performance. Oxide systems. Pure water. Thermal characteristics. Thermal operations. Thermal resistance. Working fluid. Evaporators. Filling. Heat flux. Heat pipes. Multiphase flow. Nanoparticles. Titanium. Titanium oxides. Nanofluidics. |
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71 | مقاله | Numerical investigation of the performance of a U-shaped pulsating heat pipe | Arabnejad, S. | 2010 |
Analytical results.
Boiling heat transfer. Energy equation. Evaporator temperature. Governing equations. Numerical investigations. Pulsating heat pipe. Pulse amplitude. Rate of heat transfer. Two section. U-shaped. Evaporators. Heat pipes. Numerical methods. Pulse amplitude modulation. Heat transfer. |
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72 | مقاله | Numerical simulation of a concentrating photovoltaic-thermal solar system combined with thermoelectric modules by coupling Finite Volume and Monte Carlo Ray-Tracing methods | Shadmehri, M. | Elsevier Ltd, | 2018 |
Concentrating Photovoltaic-Thermal (CPTV)
Finite Volume Method (FVM) Geometric parameters. Monte Carlo Ray-Tracing (MCRT) Parabolic trough solar collector. Thermoelectric (TE) Absorption cooling. Environmental regulations. Finite volume method. Hybrid systems. Monte Carlo methods. Numerical methods. Numerical models. Photovoltaic cells. Photovoltaic effects. Reflection. Solar absorbers. Solar energy. Solar power generation. Solar system. Thermoelectricity. Concentrating photovoltaic. Monte-Carlo ray tracing. Parabolic trough solar collectors. Thermoelectric. Ray tracing. |
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73 | مقاله | Bi-level energy-efficient occupancy profile optimization integrated with demand-driven control strategy: University building energy saving | Jafarinejad, T. | Elsevier Ltd, | 2019 |
Artificial neural networks (ANN)
Bi-level timetable optimization. Building energy saving. Demand-driven control. Dynamic set-point temperature. Intelligent systems (IS) Occupancy profile. College buildings. Data acquisition. Energy efficiency. Energy utilization. Intelligent systems. Neural networks. Office buildings. Optimization. Scheduling. Thermostats. Data acquisition system. Demand-driven. Energy-saving strategies. Meta heuristic algorithm. Profile optimization methods. Set-point temperatures. Energy conservation. |
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74 | مقاله | Distilled water production with combination of solar still and thermosyphon heat pipe heat exchanger coupled with indirect water bath heater – Experimental study and thermoeconomic analysis | Rastegar, S. | Elsevier Ltd, | 2020 |
Environmental analysis.
Exergoeconomic analysis. Heat pipe heat exchanger. Indirect water bath heater. Pressure Reduction Station. Solar still. Distillation. Energy efficiency. Gas industry. Heat exchangers. Heat pipes. Solar heating. Solar water heaters. Climatic conditions. Daily production. Distilled water. Exergy efficiencies. Heat pipe heat exchangers. Pressure reduction. Recovering heat. Thermoeconomic analysis. Economic analysis. |
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75 | مقاله | The impingement of liquid boiling droplet onto a molten phase change material as a direct-contact solidification method | Faghiri, S. | Elsevier Ltd, | 2021 |
Acetone.
Atmospheric temperature. Drops. High speed cameras. Molten materials. Paraffins. Solidification. Surface properties. Direct contact. Free surfaces. Heat extraction process. Liquid paraffins. Molten surfaces. Paraffin surfaces. Surface temperatures. Weber numbers. Phase change materials. |
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76 | مقاله | A comprehensive study on the complete charging-discharging cycle of a phase change material using intermediate boiling fluid to control energy flow | Hosseininaveh, H. | Elsevier Ltd, | 2021 |
Acetone.
Energy storage. Metal melting. Paraffins. Solidification. Conventional methods. Low thermal conductivity. Melting and solidification. Optimum conditions. Solidification process. Solidification rate. Solidification time. Transfer process. Phase change materials. |
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77 | مقاله | Experimental evaluation of a solar-driven adsorption desalination system using solid adsorbent of silica gel and hydrogel | Zarei Saleh Abad, M. | Springer Science and Business Media Deutschland GmbH, | 2022 |
Adsorption desalination.
Evacuated tube collector. Hydrogel. Silica gel. Solar energy. Adsorption. Desalination. Experimental study. Gel. Silica. Solar power. Solid. Silica gel. Water. Adsorption. Hydrogel. Water management. Adsorption. Hydrogels. Silica Gel. Water. Water Purification. |
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78 | مقاله | Hydrothermal analysis of non-Newtonian fluid flow (blood) through the circular tube under prescribed non-uniform wall heat flux | Faghiri, S. | Elsevier Ltd, | 2022 |
Analytical solution.
Non-newtonian fluid. Non-uniform heat flux. Power-law model. |
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79 | مقاله | Experimental investigation of the effect of using closed-loop pulsating heat pipe on the performance of a flat plate solar collector | Kargarsharifabad, H. | 2013 |
Closed-loop.
Experimental investigations. Filling ratio. Flat-plate collector. Flat-plate solar collectors. Inclination angles. Optimum value. Pulsating heat pipe. Evaporators. Heat pipes. Sun. Collector efficiency. |
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80 | مقاله | Experimental investigation on laminar forced convection heat transfer of ferrofluids under an alternating magnetic field | Ghofrani, A. | 2013 |
Alternating magnetic field.
Convective heat transfer. Enhancement. Ferrofluid. Convective heat transfer Coefficient. Convective heat transfer rates. Experimental investigations. Heat Transfer enhancement. Laminar forced convections. Forced convection. Heat flux. Heat transfer coefficients. Image enhancement. Magnetic fluids. Nanoparticles. Reynolds number. Tubes (components) Magnetic fields. |
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