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地道风与空气源热泵 英文版 李永安 著;邢德安 译 2015年版
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地道风与空气源热泵 英文版
作者: 李永安 著;邢德安 译
出版时间: 2015年版
内容简介
《地道风与空气源热泵》是住房和城乡建设部科研课题,对冬夏季地道风的特性及基于地道风的空气源热泵进行了较为深入的研究,主要内容包括地层温度的变化特点与计算、地道中空气与土壤之间的换热、空气流经地道的加热过程、空气流经地道的冷却过程、基于地道风的空气源热泵等,取得了一批具有实用价值的成果。
目录
Chapter 1 Introduction
1.1 Current situation of energy source in China
1.2 Utilization of renewable energy resource
1.3 Traditional utility pattern of air through tunnel(hereafter referred to as"ATT")
Chapter 2 Characteristic of Formation Temperature Change
2.1 Source of formation energy
2.1.1 Solar radiation energy
2.1.2 Biological heat
2.1.3 Geothermal resources
2.2 Thermo—physical property of formation soil
2.2.1 Heat conductivity coefficient λ
2.2.2 Specific heat cP
2.2.3 Thermal diffusivity α
2.3 Change rules of soil temperature inside formation
2.4 Numerical mathematical model for original soil temperature field
2.4.1 Dynamic model of shallow underground soil temperature distribution
2.4.2 Solve the shallow formation soil temperature distribution in application of Fourier Law
2.5 Characteristic analysis of formation temperature wave
2.5.1 Formation soil temperature attenuating property
2.5.2 Temperature wave delay
2.5.3 Calculation of original formation soil temperature at the same time
Chapter 3 Heat Transfer between Soil and Air in Tunnel
3.1 Analysis of tunnel wall heat conduction process
3.2 Introduction of coupling problem
3.3 Selection of turbulence model
3.4 Processing of near—wall region
3.5 Mathematical description of the model
3.6 Mesh generation of mathematical model
3.7 Definition of boundary conditions in GAMBIT and FLUENT
3.7.1 Settings for boundary conditions
3.7.2 Preliminary defining of the types of boundary conditions in the GAMBIT
3.7.3 Further defining the conditions of the mathematical model in FLUENT
Chapter 4 Process Analysis of Air through Tunnel in Summer
4.1 Determination of different parameters in simulation computation
4.1.1 Air outdoor meteorological parameters
4.1.2 Formation temperature
4.1.3 Tunnel masonry material
4.1.4 Convection heat transfer coefficient
4.2 Analog computation and analysis of all factors for air cooling through tunnel
4.2.1 Simulation computation and analysis for air cooling factors through tunnel under
4.2.2 Dynamic simulation computation and analysis of air temperature drop through tunnel
4.3 Tunnel cooling efficiency
4.3.1 Effect of tunnel length on tunnel cooling efficiency
4.3.2 Effect of tunnel buried depth on tunnel cooling efficiency
4.3.3 Effect of tunnel wind speed on tunnel cooling efficiency
4.3.4 Effect of tunnel structure size on tunnel cooling efficiency
4.3.5 Effect of different ventilation time on tunnel cooling efficiency
Chapter 5 State Change of Air through Tunnel in Winter
5.1 Introduction of mathematical model
5.1.1 Model zone setting
5.1.2 Air outdoor meteorological parameters
5.1.3 Formation temperature
5.1.4 Soil physical property parameters
5.1.5 Determination of convection heat transfer coefficient
5.2 Simulation results
5.3 Analog computation and analysis of all factors for air heating through tunnel
5.3.1 Simulation computation and analysis for air heating factors through tunnel under steady state
5.3.2 Dynamic simulation computation and analysis of air temperature drop through tunnel
5.4 Tunnel heating efficiency
5.4.1 Effect of tunnel length on tunnel heating efficiency
5.4.2 Effect of tunnel buried depth on tunnel heating efficiency
5.4.3 Effect of tunnel wind speed on tunnel heating efficiency
5.4.4 Effect of tunnel structure size on heating efficiency
Chapter 6 Air through Tunnel Experimental Study
6.1 Experimental object description
6.2 Experimental methods and apparatus
6.2.1 Conditions preparation before the experiment
6.2.2 Experimental methods and procedures
6.2.3 Experimental apparatus
6.3 Experimental error analysis
6.3.1 Experimental apparatus error analysis
6.3.2 Error analysis of experimental measurement
6.4 Experimental procedures and data processing
6.4.1 The experimental procedures and results of tunnel parameters measurement under original state
6.4.2 Experimental procedures and results of each measured parameters inside the tunnel under ventilation state
6.5 Comparative analysis of experimental results and theoretical calculation
Chapter 7 ASHP
7.1 Heat pump and its type
7.2 Air source heat pump(ASHP)
7.3 The characteristics of ASHP
7.4 The applicability of ASHP
Chapter 8 Air Source Heat Pump Based on Air through Tunnel
8.1 Air source heat pump based on air through tunnel
8.2 Introduction of ASHP experimental system based on air through tunnel
8.2.1 Work principle of ASHP system based on ATT
8.2.2 Experiment facility and test method
8.3 Experiment data and analysis of ASHP based on ATT
8.4 Frostless ASHP based on ATT
8.5 Application analysis of ASHP based on ATT
8.6 Innovation analysis of ASHP based on ATT
Annex
Annex 1 Surface Temperature,Temperature Wave Amplitude,and Maximum Depth of Frozen Ground of Main Cities in China
Annex 2 Calculating Parameter for Building Material Thermo Physical Characteristic
作者: 李永安 著;邢德安 译
出版时间: 2015年版
内容简介
《地道风与空气源热泵》是住房和城乡建设部科研课题,对冬夏季地道风的特性及基于地道风的空气源热泵进行了较为深入的研究,主要内容包括地层温度的变化特点与计算、地道中空气与土壤之间的换热、空气流经地道的加热过程、空气流经地道的冷却过程、基于地道风的空气源热泵等,取得了一批具有实用价值的成果。
目录
Chapter 1 Introduction
1.1 Current situation of energy source in China
1.2 Utilization of renewable energy resource
1.3 Traditional utility pattern of air through tunnel(hereafter referred to as"ATT")
Chapter 2 Characteristic of Formation Temperature Change
2.1 Source of formation energy
2.1.1 Solar radiation energy
2.1.2 Biological heat
2.1.3 Geothermal resources
2.2 Thermo—physical property of formation soil
2.2.1 Heat conductivity coefficient λ
2.2.2 Specific heat cP
2.2.3 Thermal diffusivity α
2.3 Change rules of soil temperature inside formation
2.4 Numerical mathematical model for original soil temperature field
2.4.1 Dynamic model of shallow underground soil temperature distribution
2.4.2 Solve the shallow formation soil temperature distribution in application of Fourier Law
2.5 Characteristic analysis of formation temperature wave
2.5.1 Formation soil temperature attenuating property
2.5.2 Temperature wave delay
2.5.3 Calculation of original formation soil temperature at the same time
Chapter 3 Heat Transfer between Soil and Air in Tunnel
3.1 Analysis of tunnel wall heat conduction process
3.2 Introduction of coupling problem
3.3 Selection of turbulence model
3.4 Processing of near—wall region
3.5 Mathematical description of the model
3.6 Mesh generation of mathematical model
3.7 Definition of boundary conditions in GAMBIT and FLUENT
3.7.1 Settings for boundary conditions
3.7.2 Preliminary defining of the types of boundary conditions in the GAMBIT
3.7.3 Further defining the conditions of the mathematical model in FLUENT
Chapter 4 Process Analysis of Air through Tunnel in Summer
4.1 Determination of different parameters in simulation computation
4.1.1 Air outdoor meteorological parameters
4.1.2 Formation temperature
4.1.3 Tunnel masonry material
4.1.4 Convection heat transfer coefficient
4.2 Analog computation and analysis of all factors for air cooling through tunnel
4.2.1 Simulation computation and analysis for air cooling factors through tunnel under
4.2.2 Dynamic simulation computation and analysis of air temperature drop through tunnel
4.3 Tunnel cooling efficiency
4.3.1 Effect of tunnel length on tunnel cooling efficiency
4.3.2 Effect of tunnel buried depth on tunnel cooling efficiency
4.3.3 Effect of tunnel wind speed on tunnel cooling efficiency
4.3.4 Effect of tunnel structure size on tunnel cooling efficiency
4.3.5 Effect of different ventilation time on tunnel cooling efficiency
Chapter 5 State Change of Air through Tunnel in Winter
5.1 Introduction of mathematical model
5.1.1 Model zone setting
5.1.2 Air outdoor meteorological parameters
5.1.3 Formation temperature
5.1.4 Soil physical property parameters
5.1.5 Determination of convection heat transfer coefficient
5.2 Simulation results
5.3 Analog computation and analysis of all factors for air heating through tunnel
5.3.1 Simulation computation and analysis for air heating factors through tunnel under steady state
5.3.2 Dynamic simulation computation and analysis of air temperature drop through tunnel
5.4 Tunnel heating efficiency
5.4.1 Effect of tunnel length on tunnel heating efficiency
5.4.2 Effect of tunnel buried depth on tunnel heating efficiency
5.4.3 Effect of tunnel wind speed on tunnel heating efficiency
5.4.4 Effect of tunnel structure size on heating efficiency
Chapter 6 Air through Tunnel Experimental Study
6.1 Experimental object description
6.2 Experimental methods and apparatus
6.2.1 Conditions preparation before the experiment
6.2.2 Experimental methods and procedures
6.2.3 Experimental apparatus
6.3 Experimental error analysis
6.3.1 Experimental apparatus error analysis
6.3.2 Error analysis of experimental measurement
6.4 Experimental procedures and data processing
6.4.1 The experimental procedures and results of tunnel parameters measurement under original state
6.4.2 Experimental procedures and results of each measured parameters inside the tunnel under ventilation state
6.5 Comparative analysis of experimental results and theoretical calculation
Chapter 7 ASHP
7.1 Heat pump and its type
7.2 Air source heat pump(ASHP)
7.3 The characteristics of ASHP
7.4 The applicability of ASHP
Chapter 8 Air Source Heat Pump Based on Air through Tunnel
8.1 Air source heat pump based on air through tunnel
8.2 Introduction of ASHP experimental system based on air through tunnel
8.2.1 Work principle of ASHP system based on ATT
8.2.2 Experiment facility and test method
8.3 Experiment data and analysis of ASHP based on ATT
8.4 Frostless ASHP based on ATT
8.5 Application analysis of ASHP based on ATT
8.6 Innovation analysis of ASHP based on ATT
Annex
Annex 1 Surface Temperature,Temperature Wave Amplitude,and Maximum Depth of Frozen Ground of Main Cities in China
Annex 2 Calculating Parameter for Building Material Thermo Physical Characteristic