tunnel_open_open 25 microns

Tunnel Open Open 25 Microns - 0.1mm Thickness

Author	COMSOL
Date	11:06:54 06/08/2014

Summary

This model describes the pressure wave propagation in a muffler for an internal combustion engine. The purpose of the model is to show how to analyze both inductive and resistive damping in pressure acoustics.

Contents

1.	Global Definitions
1.1.		Parameters 1
2.	Model 1 (mod1)
2.1.		Definitions
2.2.		Geometry 1
2.3.		Materials
2.4.		Pressure Acoustics, Frequency Domain (acpr)
2.5.		Mesh 1
3.	Study 1
3.1.		Frequency Domain
3.2.		Solver Configurations
4.	Results
4.1.		Data Sets
4.2.		Tables
4.3.		Plot Groups

1. Global Definitions

1.1. Parameters 1

Parameters
Name	Expression	Description
p0	1[Pa]	Amplitude of incoming pressure wave

2. Model 1 (Mod1)

2.1. Definitions

2.1.1. Variables

Variables 1

Selection
Geometric entity level	Entire model

Name	Expression	Description
w_in	intop1(p0^2/(2acpr.rhoacpr.c))	Power of the incoming wave
w_out	intop2(abs(p)^2/(2acpr.rhoacpr.c))	Power of the outgoing wave

2.1.2. Model Couplings

Integration 1

Coupling type	Integration
Operator name	intop1

Source selection
Geometric entity level	Boundary
Selection	Boundary 1

Integration 2

Coupling type	Integration
Operator name	intop2

Source selection
Geometric entity level	Boundary
Selection	Boundary 26

2.1.3. Selections

Inlet

Selection
Boundary 1

Inlet

Outlet

Selection
Boundary 26

Outlet

Explicit 3

Selection
Boundaries 6, 16

Explicit 3

2.1.4. Coordinate Systems

Boundary System 1

Coordinate system type	Boundary system
Identifier	sys1

Settings
Name	Value
Coordinate names	{t1, t2, n}
Create first tangent direction from	Global Cartesian

2.2. Geometry 1

Geometry 1

units
Length unit	mm
Angular unit	deg

Geometry statistics
Property	Value
Space dimension	3
Number of domains	5
Number of boundaries	26
Number of edges	44
Number of vertices	24

2.2.1. Import 1 (Imp1)

Selections of resulting entities
Name	Value
Geometry import	3D CAD file
Filename	C:\Users\judah\Desktop\Junk\Comsol\Assem1.SLDASM

2.3. Materials

2.3.1. Air

Air

Selection
Geometric entity level	Domain
Selection	Domains 1–5

Material parameters
Name	Value	Unit
Density	rho(pA[1/Pa], T[1/K])[kg/m^3]	kg/m^3
Speed of sound	cs(T[1/K])[m/s]	m/s

Basic Settings
Description	Value
Relative permeability	{{1, 0, 0}, {0, 1, 0}, {0, 0, 1}}
Relative permittivity	{{1, 0, 0}, {0, 1, 0}, {0, 0, 1}}
Dynamic viscosity	eta(T[1/K])[Pa*s]
Ratio of specific heats	1.4
Electrical conductivity	{{0[S/m], 0, 0}, {0, 0[S/m], 0}, {0, 0, 0[S/m]}}
Heat capacity at constant pressure	Cp(T[1/K])[J/(kg*K)]
Density	rho(pA[1/Pa], T[1/K])[kg/m^3]
Thermal conductivity	{{k(T[1/K])[W/(mK)], 0, 0}, {0, k(T[1/K])[W/(mK)], 0}, {0, 0, k(T[1/K])[W/(m*K)]}}
Speed of sound	cs(T[1/K])[m/s]

Functions
Function name	Type
eta	Piecewise
Cp	Piecewise
rho	Analytic
k	Piecewise
cs	Analytic

eta

2.4. Pressure Acoustics, Frequency Domain (Acpr)

Pressure Acoustics, Frequency Domain

Selection
Geometric entity level	Domain
Selection	Domains 1–5

Settings
Description	Value
Show equation assuming	std1/freq

Used products
COMSOL Multiphysics
Acoustics Module

2.4.1. Pressure Acoustics Model 1

Pressure Acoustics Model 1

Selection
Geometric entity level	Domain
Selection	Domains 1–5

Equations

Used Products

COMSOL Multiphysics

Properties from material
Property	Material	Property group
Density	Air	Basic
Speed of sound	Air	Basic

Variables

Name	Expression	Unit	Description	Selection
acpr.Q	0	1/s^2	Monopole source	Domains 1–5
acpr.qx	0	N/m^3	Dipole source, x component	Domains 1–5
acpr.qy	0	N/m^3	Dipole source, y component	Domains 1–5
acpr.qz	0	N/m^3	Dipole source, z component	Domains 1–5
acpr.p_b	0	Pa	Background pressure field	Domains 1–5
acpr.nacc	0	m/s^2	Inward acceleration	Boundaries 1–26
acpr.FAcoPerAreax	acpr.p_t*acpr.nx	N/m^2	Acoustic load per unit area, x component	Boundaries 1–26
acpr.FAcoPerAreay	acpr.p_t*acpr.ny	N/m^2	Acoustic load per unit area, y component	Boundaries 1–26
acpr.FAcoPerAreaz	acpr.p_t*acpr.nz	N/m^2	Acoustic load per unit area, z component	Boundaries 1–26
acpr.p_t	p + acpr.p_b	Pa	Total acoustic pressure field	Domains 1–5
acpr.p_s	acpr.p_t - acpr.p_b	Pa	Scattered pressure field	Domains 1–5
acpr.delta	1/acpr.omega^2	s^2	Scaling factor	Global
acpr.c	model.input.c	m/s	Speed of sound	Domains 1–5
acpr.pam1.minput_temperature	model.input.minput_temperature	K	Temperature	Domains 1–5
acpr.pam1.minput_pressure	1[atm]	Pa	Absolute pressure	Domains 1–5
acpr.rho	model.input.rho	kg/m^3	Density	Domains 1–5
acpr.c_c	acpr.c	m/s	Complex speed of sound	Domains 1–5
acpr.rho_c	acpr.rho	kg/m^3	Complex density	Domains 1–5
acpr.k	acpr.omega/acpr.c_c	rad/m	Wave number	Domains 1–5
acpr.Z	acpr.rho_c*acpr.c_c	Pa*s/m	Characteristic acoustic impedance	Domains 1–5
acpr.ik	acpr.iomega/acpr.c_c	rad/m	Phase-shifted wave number	Domains 1–5
acpr.keq_sq	-acpr.ik^2	rad/m	Squared wave number for equations	Domains 1–5
acpr.keq	(acpr.ik^2)^0.5	rad/m	Wave number for equations	Domains 1–5
acpr.ax	-(d(acpr.p_t, x) - acpr.qx)/acpr.rho_c	m/s^2	Local acceleration, x component	Domains 1–5
acpr.ay	-(d(acpr.p_t, y) - acpr.qy)/acpr.rho_c	m/s^2	Local acceleration, y component	Domains 1–5
acpr.az	-(d(acpr.p_t, z) - acpr.qz)/acpr.rho_c	m/s^2	Local acceleration, z component	Domains 1–5
acpr.a_inst	sqrt(real((d(acpr.p_t, x) - acpr.qx)/acpr.rho_c)^2 + real((d(acpr.p_t, y) - acpr.qy)/acpr.rho_c)^2 + real((d(acpr.p_t, z) - acpr.qz)/acpr.rho_c)^2)	m/s^2	Instantaneous local acceleration	Domains 1–5
acpr.a_rms	sqrt(0.5*(realdot((d(acpr.p_t, x) - acpr.qx)/acpr.rho_c, (d(acpr.p_t, x) - acpr.qx)/acpr.rho_c) + realdot((d(acpr.p_t, y) - acpr.qy)/acpr.rho_c, (d(acpr.p_t, y) - acpr.qy)/acpr.rho_c) + realdot((d(acpr.p_t, z) - acpr.qz)/acpr.rho_c, (d(acpr.p_t, z) - acpr.qz)/acpr.rho_c)))	m/s^2	Local acceleration, (RMS)	Domains 1–5
acpr.vx	-(d(acpr.p_t, x) - acpr.qx)/(acpr.rho_c*acpr.iomega)	m/s	Local velocity, x component	Domains 1–5
acpr.vy	-(d(acpr.p_t, y) - acpr.qy)/(acpr.rho_c*acpr.iomega)	m/s	Local velocity, y component	Domains 1–5
acpr.vz	-(d(acpr.p_t, z) - acpr.qz)/(acpr.rho_c*acpr.iomega)	m/s	Local velocity, z component	Domains 1–5
acpr.v_inst	sqrt(real(acpr.vx)^2 + real(acpr.vy)^2 + real(acpr.vz)^2)	m/s	Instantaneous local velocity	Domains 1–5
acpr.v_rms	sqrt(0.5*(realdot(acpr.vx, acpr.vx) + realdot(acpr.vy, acpr.vy) + realdot(acpr.vz, acpr.vz)))	m/s	Local velocity, (RMS)	Domains 1–5
acpr.Ix	0.5*realdot(acpr.p_t, acpr.vx)	W/m^2	Intensity (RMS), x component	Domains 1–5
acpr.Iy	0.5*realdot(acpr.p_t, acpr.vy)	W/m^2	Intensity (RMS), y component	Domains 1–5
acpr.Iz	0.5*realdot(acpr.p_t, acpr.vz)	W/m^2	Intensity (RMS), z component	Domains 1–5
acpr.I_rms	sqrt(0.25*(realdot(acpr.p_t, acpr.vx)^2 + realdot(acpr.p_t, acpr.vy)^2 + realdot(acpr.p_t, acpr.vz)^2))	W/m^2	Intensity magnitude (RMS)	Domains 1–5
acpr.Iix	real(acpr.vx)*real(acpr.p_t)	W/m^2	Instantaneous intensity, x component	Domains 1–5
acpr.Iiy	real(acpr.vy)*real(acpr.p_t)	W/m^2	Instantaneous intensity, y component	Domains 1–5
acpr.Iiz	real(acpr.vz)*real(acpr.p_t)	W/m^2	Instantaneous intensity, z component	Domains 1–5
acpr.I_inst	sqrt((real(acpr.vx)real(acpr.p_t))^2 + (real(acpr.vy)real(acpr.p_t))^2 + (real(acpr.vz)*real(acpr.p_t))^2)	W/m^2	Instantaneous intensity magnitude	Domains 1–5
acpr.Lp	10log10(0.5acpr.p_t*conj(acpr.p_t)/acpr.pref_SPL^2)	dB	Sound pressure level	Domains 1–5
acpr.Lp_s	10log10(0.5acpr.p_s*conj(acpr.p_s)/acpr.pref_SPL^2)	dB	Scattered sound pressure level	Domains 1–5
acpr.absp	sqrt(realdot(acpr.p_t, acpr.p_t))	Pa	Absolute pressure	Domains 1–5

Shape Functions

Name	Shape function	Unit	Description	Shape frame	Selection
p	Lagrange (Quadratic)	Pa	Pressure	Material	Domains 1–5

Weak Expressions

Weak expression	Integration frame	Selection
(d(acpr.p_t, x)test(px) - d(acpr.p_t, y)test(py) - d(acpr.p_t, z)test(pz) + acpr.p_ttest(p)acpr.keq_sq)acpr.delta/acpr.rho_c	Material	Domains 1–5
acpr.deltaacpr.Qtest(p)	Material	Domains 1–5
acpr.delta(acpr.qxtest(px) + acpr.qytest(py) + acpr.qztest(pz))/acpr.rho_c	Material	Domains 1–5
acpr.nacctest(p)acpr.delta	Material	Boundaries 1–5, 7–10, 12–15, 17–20, 22–26

2.4.2. Sound Hard Boundary (Wall) 1

Sound Hard Boundary (Wall) 1

Selection
Geometric entity level	Boundary
Selection	Boundaries 2–5, 7–10, 12–15, 17–20, 22–25

Equations

Used Products

COMSOL Multiphysics

2.4.3. Initial Values 1

Initial Values 1

Selection
Geometric entity level	Domain
Selection	Domains 1–5

Used Products

COMSOL Multiphysics

2.4.4. Plane Wave Radiation 1

Plane Wave Radiation 1

Selection
Geometric entity level	Boundary
Selection	Boundaries 1, 26

Equations

Used Products

COMSOL Multiphysics

Variables

Name	Expression	Unit	Description	Selection
acpr.ik	acpr.iomega/acpr.c_c	rad/m	Phase-shifted wave number	Boundaries 1, 26
acpr.p_i	0	Pa	Incident pressure field	Boundaries 1, 26

Weak Expressions

Weak expression	Integration frame	Selection
((acpr.ik^2)^0.5iptest(p) + ((acpr.ik^2)^0.5iacpr.p_i + acpr.nxd(acpr.p_i, x) + acpr.nyd(acpr.p_i, y) + acpr.nzd(acpr.p_i, z))test(p) + (acpr.nxmean(d(acpr.p_b, x)) + acpr.nymean(d(acpr.p_b, y)) + acpr.nzmean(d(acpr.p_b, z)))test(p) + 0.5(pTxtest(pTx) + pTytest(pTy) + pTztest(pTz))i/(acpr.ik^2)^0.5 + 0.5(test(pTx)(acpr.nx(acpr.nxd(acpr.p_i, x) + acpr.nyd(acpr.p_i, y) + acpr.nzd(acpr.p_i, z)) - d(acpr.p_i, x)) + test(pTy)(acpr.ny(acpr.nxd(acpr.p_i, x) + acpr.nyd(acpr.p_i, y) + acpr.nzd(acpr.p_i, z)) - d(acpr.p_i, y)) + test(pTz)(acpr.nz(acpr.nxd(acpr.p_i, x) + acpr.nyd(acpr.p_i, y) + acpr.nzd(acpr.p_i, z)) - d(acpr.p_i, z)))i/(acpr.ik^2)^0.5)acpr.delta/acpr.rho_c	Material	Boundaries 1, 26

Incident Pressure Field 1

Selection
Geometric entity level	Boundary
Selection	Boundary 1

Equations

Settings

Settings
Description	Value
Pressure amplitude	p0

Used Products

COMSOL Multiphysics

Variables

Name	Expression	Unit	Description	Selection
acpr.p_i	p0exp(acpr.keqi(acpr.nxx - acpr.nyy - acpr.nzz)/sqrt(acpr.nx^2 + acpr.ny^2 + acpr.nz^2))	Pa	Incident pressure field	Boundary 1

2.4.5. Interior Perforated Plate 1

Interior Perforated Plate 1

Selection
Geometric entity level	Boundary
Selection	Boundaries 6, 16

Equations

Settings

Settings
Description	Value
Area porosity	0.4
Plate thickness	0.0001
Hole diameter	25e6 [m]

Variables

Name	Expression	Unit	Description	Selection
acpr.dh	2.5E5[m]	m	Hole diameter	Boundaries 6, 16
acpr.Zi	2.5((81.8E5[Pas]acpr.k/(acpr.rho_cacpr.c_c))^0.5(1 + 1.0E4/acpr.dh) + acpr.ki(1.0E4 + 0.25acpr.dh))acpr.rho_c*acpr.c_c	Pa*s/m	Impedance	Boundaries 6, 16

Shape Functions

Name	Shape function	Unit	Description	Shape frame	Selection
p	Lagrange (Quadratic)	Pa	Pressure	Material	Boundaries 6, 16

Weak Expressions

Weak expression	Integration frame	Selection
acpr.iomega(down(acpr.p_t) - up(acpr.p_t))acpr.delta*(down(test(p)) + up(test(p)))/acpr.Zi	Material	Boundaries 6, 16

2.5. Mesh 1

Mesh statistics
Property	Value
Minimum element quality	2.598E6
Average element quality	0.591
Tetrahedral elements	9676
Triangular elements	3564
Edge elements	496
Vertex elements	24

Mesh 1

2.5.1. Size (Size)

Settings
Name	Value
Maximum element size	367
Minimum element size	45.9
Resolution of curvature	0.5
Resolution of narrow regions	0.6
Maximum element growth rate	1.45
Predefined size	Fine

3. Study 1

3.1. Frequency Domain

Frequencies: range(10,2,300)

Mesh selection
Geometry	Mesh
Geometry 1 (geom1)	mesh1

Physics selection
Physics	Discretization
Pressure Acoustics, Frequency Domain (acpr)	physics

3.2. Solver Configurations

3.2.1. Solver 1

Compile Equations: Frequency Domain (St1)

Study and step
Name	Value
Use study	Study 1
Use study step	Frequency Domain

Dependent Variables 1 (V1)

General
Name	Value
Defined by study step	Frequency Domain

Initial values of variables solved for
Name	Value
Solution	Zero

Values of variables not solved for
Name	Value
Solution	Zero

Mod1.p (Mod1_p)

General
Name	Value
Field components	mod1.p

Stationary Solver 1 (S1)

General
Name	Value
Defined by study step	Frequency Domain

Log

Stationary Solver 1 in Solver 1 started at 6-אוג-2014 10:41:18.

Parametric solver

Linear solver

Number of degrees of freedom solved for: 16770.

Parameter freq = 10.

Symmetric matrices found.

Scales for dependent variables:

mod1.p: 1