卡车的外部气流:练习 4 - 分配边界条件
对于边界条件,流体行为和属性是在流体域的所有边界曲面上指定的。
指定入口边界条件
1. 在 
“边界条件”(Boundary Conditions) > 
“普通边界”(General Boundaries) 下,选择 outside_dir1_min。
“边界条件”(Boundary Conditions) > “普通边界”(General Boundaries) 下,选择 outside_dir1_min。2. 在“模型”(Model) 选项卡中,对于“流动”(Flow),为所列选项选择以下值:
◦ “流动”(Flow) -“指定的速度”(Specified Velocity)
◦ 在“方法”(Method) 下,将“速度”(Velocity) 设置为 20,0,0
指定出口边界条件
1. 在 “边界条件”(Boundary Conditions) > “普通边界”(General Boundaries) 下,选择 outside_dir1_max。
“边界条件”(Boundary Conditions) > “普通边界”(General Boundaries) 下,选择 outside_dir1_max。2. 在“模型”(Model) 选项卡中,对于“流动”(Flow),为所列选项选择以下值:
◦ “流动”(Flow) - “指定的压力出口”(Specified Pressure Outlet)
◦ “压力”(Pressure) - 0 Pa
指定其他边界条件
1. 在 Flow Analysis 树中,选择 “边界条件”(Boundary Conditions) > “普通边界”(General Boundaries) 下的 outside_dir2_max、outside_dir3_max 和 outside_dir3_min。
“边界条件”(Boundary Conditions) > “普通边界”(General Boundaries) 下的 outside_dir2_max、outside_dir3_max 和 outside_dir3_min。2. 在“模型”(Model) 选项卡中,对于“流动”(Flow),为所列选项选择以下值:
◦ “流动”(Flow) - “指定的压力出口”(Specified Pressure Outlet)
◦ 在 Velocity Profile 下,将 Back Flow Velocity(optional) 设置为 20,0,0
指定用于计算阻力系数的表达式
1. 在 Flow Analysis 树中,选择 
“物理”(Physics)。
“物理”(Physics)。2. 在“操作”(Operations) 组中,单击 
“表达式编辑器”(Expression Editor)。
“表达式编辑器”(Expression Editor)。3. 在“表达式编辑器”(Expression Editor) 对话框中,输入以下内容:
V_fs = 20 # flow velocity
rho = 1.176 # density
A = 9.51474 # frontal area
#Drag force
D = flow.px@CAB + flow.tx@CAB + flow.px@TIRE_1 + flow.tx@TIRE_1 + flow.px@TIRE_2 + flow.tx@TIRE_2 + flow.px@TIRE_3 + flow.tx@TIRE_3 + flow.px@TIRE_4 + flow.tx@TIRE_4 + flow.px@TIRE_5 + flow.tx@TIRE_5 + flow.px@TIRE_6 + flow.tx@TIRE_6 + flow.px@TIRE_7 + flow.tx@TIRE_7 + flow.px@TIRE_8 + flow.tx@TIRE_8 + flow.px@TIRE_L_1 + flow.px@TIRE_L_2 + flow.tx@TIRE_L_1 + flow.tx@TIRE_L_2 + flow.px@TRAILER + flow.tx@TRAILER
plot.Drag_Force_on_Truck = D
#plot.Drag_Force_on_Truck: Drag force
#Drag coefficient
C_d = D/(0.5*rho*V_fs*V_fs*A)
plot.Coefficient_of_Drag = C_d
#plot.Coefficient_of_Drag = Coefficient of Drag
rho = 1.176 # density
A = 9.51474 # frontal area
#Drag force
D = flow.px@CAB + flow.tx@CAB + flow.px@TIRE_1 + flow.tx@TIRE_1 + flow.px@TIRE_2 + flow.tx@TIRE_2 + flow.px@TIRE_3 + flow.tx@TIRE_3 + flow.px@TIRE_4 + flow.tx@TIRE_4 + flow.px@TIRE_5 + flow.tx@TIRE_5 + flow.px@TIRE_6 + flow.tx@TIRE_6 + flow.px@TIRE_7 + flow.tx@TIRE_7 + flow.px@TIRE_8 + flow.tx@TIRE_8 + flow.px@TIRE_L_1 + flow.px@TIRE_L_2 + flow.tx@TIRE_L_1 + flow.tx@TIRE_L_2 + flow.px@TRAILER + flow.tx@TRAILER
plot.Drag_Force_on_Truck = D
#plot.Drag_Force_on_Truck: Drag force
#Drag coefficient
C_d = D/(0.5*rho*V_fs*V_fs*A)
plot.Coefficient_of_Drag = C_d
#plot.Coefficient_of_Drag = Coefficient of Drag
4. 单击“确定”(OK)。