Pipe (TL)

Rigid conduit for fluid flow in thermal liquid systems

Libraries:
Simscape / Foundation Library / Thermal Liquid / Elements

Description

The Pipe (TL) block represents a pipeline segment with a fixed volume of liquid. The liquid experiences pressure losses due to viscous friction and heat transfer due to convection between the fluid and the pipe wall. Viscous friction follows from the Darcy-Weisbach equation, while the heat exchange coefficient follows from Nusselt number correlations.

Pipe Effects

The block lets you include dynamic compressibility and fluid inertia effects. Turning on each of these effects can improve model fidelity at the cost of increased equation complexity and potentially increased simulation cost:

When dynamic compressibility is off, the liquid is assumed to spend negligible time in the pipe volume. Therefore, there is no accumulation of mass in the pipe, and mass inflow equals mass outflow. This is the simplest option. It is appropriate when the liquid mass in the pipe is a negligible fraction of the total liquid mass in the system.
When dynamic compressibility is on, an imbalance of mass inflow and mass outflow can cause liquid to accumulate or diminish in the pipe. As a result, pressure in the pipe volume can rise and fall dynamically, which provides some compliance to the system and modulates rapid pressure changes. This is the default option.
If dynamic compressibility is on, you can also turn on fluid inertia. This effect results in additional flow resistance, besides the resistance due to friction. This additional resistance is proportional to the rate of change of mass flow rate. Accounting for fluid inertia slows down rapid changes in flow rate but can also cause the flow rate to overshoot and oscillate. This option is appropriate in a very long pipe. Turn on fluid inertia and connect multiple pipe segments in series to model the propagation of pressure waves along the pipe, such as in the water hammer phenomenon.

Mass Balance

The mass conservation equation for the pipe is

${\dot{m}}_{A} + {\dot{m}}_{B} = {\begin{matrix} 0, & if fluid dynamic compressibility is'off' \\ V ρ (\frac{1}{β} \frac{d p}{d t} - α \frac{d T}{d t}), & if fluid dynamic compressibility is'on' \end{matrix}$

where:

${\dot{m}}_{A}$ and ${\dot{m}}_{B}$ are the mass flow rates through ports A and B.
V is the pipe fluid volume.
ρ is the thermal liquid density in the pipe.
β is the isothermal bulk modulus in the pipe.
α is the isobaric thermal expansion coefficient in the pipe.
p is the thermal liquid pressure in the pipe.
T is the thermal liquid temperature in the pipe.

Momentum Balance

The table shows the momentum conservation equations for each half pipe.

For half pipe adjacent to port A	$p_{A} - p = {\begin{matrix} Δ p_{v,A}, & if fluid inertia is off \\ Δ p_{v,A} + \frac{L}{2 S} {\ddot{m}}_{A}, & if fluid inertia is on \end{matrix}$
For half pipe adjacent to port B	$p_{B} - p = {\begin{matrix} Δ p_{v,B}, & if fluid inertia is off \\ Δ p_{v,B} + \frac{L}{2 S} {\ddot{m}}_{B}, & if fluid inertia is on \end{matrix}$

In the equations:

S is the pipe cross-sectional area.
p, p_A, and p_B are the liquid pressures in the pipe, at port A and port B.
Δp_v,A and Δp_v,B are the viscous friction pressure losses between the pipe volume center and ports A and B.

Viscous Friction Pressure Losses

The table shows the viscous friction pressure loss equations for each half pipe.

For half pipe adjacent to port A	$Δ p_{v,A} = {\begin{matrix} λ ν (\frac{L + L_{eq}}{2}) \frac{{\dot{m}}_{A}}{2 D^{2} S}, & if {Re}_{A} < {Re}_{l} \\ f_{A} (\frac{L + L_{eq}}{2}) \frac{{\dot{m}}_{A} \| {\dot{m}}_{A} \|}{2 ρ D S^{2}}, & {if Re}_{A} \geq {Re}_{t} \end{matrix}$
For half pipe adjacent to port B	$Δ p_{v,B} = {\begin{matrix} λ ν (\frac{L + L_{eq}}{2}) \frac{{\dot{m}}_{B}}{2 D^{2} S}, & if {Re}_{B} < {Re}_{l} \\ f_{B} (\frac{L + L_{eq}}{2}) \frac{{\dot{m}}_{B} \| {\dot{m}}_{B} \|}{2 ρ D S^{2}}, & {if Re}_{B} \geq {Re}_{t} \end{matrix}$

In the equations:

λ is the pipe shape factor.
ν is the kinematic viscosity of the thermal liquid in the pipe.
L_eq is the aggregate equivalent length of the local pipe resistances.
D is the hydraulic diameter of the pipe.
f_A and f_B are the Darcy friction factors in the pipe halves adjacent to ports A and B.
Re_A and Re_B are the Reynolds numbers at ports A and B.
Re_l is the Reynolds number above which the flow transitions to turbulent.
Re_t is the Reynolds number below which the flow transitions to laminar.

The Darcy friction factors follow from the Haaland approximation for the turbulent regime:

$f = \frac{1}{{[- 1.8 \log_{10} (\frac{6.9}{Re} + {(\frac{1}{3.7} \frac{r}{D})}^{1.11})]}^{2}},$

where:

f is the Darcy friction factor.
r is the pipe surface roughness.

Energy Balance

The energy conservation equation for the pipe is

$V \frac{d (ρ u)}{d t} = ϕ_{A} + ϕ_{B} + Q_{H},$

where:

Φ_A and Φ_B are the total energy flow rates into the pipe through ports A and B.
Q_H is the heat flow rate into the pipe through the pipe wall.

Wall Heat Flow Rate

The heat flow rate between the thermal liquid and the pipe wall is:

$Q_{H} = Q_{c o n v} + \frac{k S_{H}}{D} (T_{H} - T),$

where:

Q_H is the net heat flow rate.
Q_conv is the portion of the heat flow rate attributed to convection at nonzero flow rates.
k is the thermal conductivity of the thermal liquid in the pipe.
S_H is the surface area of the pipe wall, the product of the pipe perimeter and length.
T_H is the temperature at the pipe wall.

Assuming an exponential temperature distribution along the pipe, the convective heat transfer is

$Q_{c o n v} = | {\dot{m}}_{a v g} | c_{p, a v g} (T_{H} - T_{i n}) (1 - exp (- \frac{h_{c o e f f} S_{H}}{| {\dot{m}}_{a v g} | c_{p, a v g}})),$

where:

${\dot{m}}_{a v g} = ({\dot{m}}_{A} - {\dot{m}}_{B}) / 2$ is the average mass flow rate from port A to port B.
$c_{p_{a v g}}$ is the specific heat evaluated at the average temperature.
T_in is the inlet temperature depending on flow direction.

The heat transfer coefficient, h_coeff, depends on the Nusselt number:

$h_{c o e f f} = N u \frac{k_{a v g}}{D},$

where k_avg, is the thermal conductivity evaluated at the average temperature. The Nusselt number depends on the flow regime. The Nusselt number in the laminar flow regime is constant and equal to the Nusselt number for laminar flow heat transfer parameter value. The Nusselt number in the turbulent flow regime is computed from the Gnielinski correlation:

$N u_{t u r} = \frac{\frac{f_{a v g}}{8} ({Re}_{a v g} - 1000) \Pr_{a v g}}{1 + 12.7 \sqrt{\frac{f_{a v g}}{8}} (\Pr_{a v g}^{2 / 3} - 1)},$

where f_avg is the Darcy friction factor at the average Reynolds number, Re_avg, and Pr_avg is the Prandtl number evaluated at the average temperature. The average Reynolds number is computed as:

${Re}_{a v g} = \frac{| {\dot{m}}_{a v g} | D}{S μ_{a v g}},$

where μ_avg is the dynamic viscosity evaluated at the average temperature. When the average Reynolds number is between the Laminar flow upper Reynolds number limit and the Turbulent flow lower Reynolds number limit parameter values, the Nusselt number follows a smooth transition between the laminar and turbulent Nusselt number values.

Assumptions and Limitations

The pipe wall is rigid.
The flow is fully developed.
The effect of gravity is negligible.

Examples

Optimal Pipeline Geometry for Heated Oil Transportation

Model shows the opposing effects of viscous warming and conductive cooling on the temperature of a buried pipeline segment for heated oil transportation. A requirement for these systems is for the crude oil to stay well above the pour point to provide a continuous steady flow. The system is modeled using the Thermal Liquid Foundation Library. Crude oil thermodynamic properties are stored in workspace matrices and are used to populate the Thermal Liquid Settings block mask parameters.

Open Model

Engine Cooling System

Model a basic engine cooling system using custom thermal liquid blocks. A fixed-displacement pump drives water through the cooling circuit. Heat from the engine is absorbed by the water coolant and dissipated through the radiator. The system temperature is regulated by the thermostat, which diverts flow to the radiator only when the temperature is above a threshold.

Open Model

Hydraulic Fluid Warming Due to Losses

Model shows how Foundation Library thermal liquid components can be used to estimate the impact of viscous losses on an actuating system's temperature over a long time scale. A pump supplies energy to the system to actuate a double-acting cylinder periodically. The pressure losses within directional valve converts the energy into heat. Heat transfer through the cylinder casing to the environment provides a heat sink.

Open Model

Water Hammer Effect

Model shows how the Thermal Liquid foundation library can be used to model water hammer in a long pipe. After slowly establishing a steady flow within the pipe by opening a valve accordingly, the same valve is shut within a few milliseconds. This triggers a water hammer effect. The valve is modeled using a Variable Local Restriction (TL) block and the pipe is divided into four segments using the Pipe (TL) block. Breaking the pipe into more segments increases fidelity at the expense of simulation performance.

Open Model

Ports

Conserving

expand all

A — Inlet or outlet
thermal liquid

Thermal liquid conserving port associated with the inlet or outlet of the pipe. This block has no intrinsic directionality.

B — Inlet or outlet
thermal liquid

Thermal liquid conserving port associated with the inlet or outlet of the pipe. This block has no intrinsic directionality.

H — Temperature of pipe wall
thermal

Thermal conserving port associated with the temperature of the pipe wall. This temperature may differ from the temperature of the thermal liquid inside the pipe.

Parameters

expand all

Geometry

Pipe length — The length of the pipe
`5 m` (default)

The length of the pipe along the direction of flow.

Cross-sectional area — The internal area of the pipe
`0.01 m^2` (default)

The internal area of the pipe normal to the direction of the flow.

Hydraulic diameter — Diameter of an equivalent cylindrical pipe with the same cross-sectional area
`0.1128 m` (default)

Diameter of an equivalent cylindrical pipe with the same cross-sectional area.

Friction and Heat Transfer

Aggregate equivalent length of local resistances — The combined length of all local resistances present in the pipe
`1 m` (default)

The combined length of all local resistances present in the pipe. Local resistances include bends, fittings, armatures, and pipe inlets and outlets. The effect of the local resistances is to increase the effective length of the pipe segment. This length is added to the geometrical pipe length only for friction calculations. The liquid volume inside the pipe depends only on the pipe geometrical length, defined by the Pipe length parameter.

Internal surface absolute roughness — Average depth of all surface defects on the internal surface of the pipe
`15e-6 m` (default)

Average depth of all surface defects on the internal surface of the pipe, which affects the pressure loss in the turbulent flow regime.

Laminar flow upper Reynolds number limit — The Reynolds number above which flow begins to transition from laminar to turbulent
`2000` (default)

The Reynolds number above which flow begins to transition from laminar to turbulent. This number equals the maximum Reynolds number corresponding to fully developed laminar flow.

Turbulent flow lower Reynolds number limit — The Reynolds number below which flow begins to transition from turbulent to laminar
`4000` (default)

The Reynolds number below which flow begins to transition from turbulent to laminar. This number equals to the minimum Reynolds number corresponding to fully developed turbulent flow.

Shape factor for laminar flow viscous friction — Effect of pipe geometry on the viscous friction losses
`64` (default)

Dimensionless factor that encodes the effect of pipe cross-sectional geometry on the viscous friction losses in the laminar flow regime. Typical values are 64 for a circular cross section, 57 for a square cross section, 62 for a rectangular cross section with an aspect ratio of 2, and 96 for a thin annular cross section [1].

Nusselt number for laminar flow heat transfer — Ratio of convective to conductive heat transfer
`3.66` (default)

Ratio of convective to conductive heat transfer in the laminar flow regime. Its value depends on the pipe cross-sectional geometry and pipe wall thermal boundary conditions, such as constant temperature or constant heat flux. Typical value is 3.66, for a circular cross section with constant wall temperature [2].

Effects and Initial Conditions

Fluid dynamic compressibility — Select whether to model fluid dynamic compressibility
`On` (default) | `Off`

Select whether to account for the dynamic compressibility of the liquid. Dynamic compressibility gives the liquid density a dependence on pressure and temperature, impacting the transient response of the system at small time scales.

Fluid inertia — Select whether to model fluid inertia
`Off` (default) | `On`

Select whether to account for the flow inertia of the liquid. Flow inertia gives the liquid a resistance to changes in mass flow rate.

Dependencies

To enable this check box, select the Fluid dynamic compressibility check box.

Initial liquid pressure — Liquid pressure at time zero
`0.101325 MPa` (default)

Liquid pressure in the pipe at the start of simulation.

Dependencies

Enabled when the Fluid dynamic compressibility parameter is set to On.

Initial liquid temperature — Liquid temperature at time zero
`293.15 K` (default)

Liquid temperature in the pipe at the start of simulation.

Initial mass flow rate from port A to port B — Mass flow rate at time zero
`0 kg/s` (default)

Mass flow rate from port A to port B at time zero.

Dependencies

Enabled when the Fluid inertia parameter is set to On.

References

[1] White, F. M., Fluid Mechanics. 7th Ed, Section 6.8. McGraw-Hill, 2011.

[2] Cengel, Y. A., Heat and Mass Transfer – A Practical Approach. 3rd Ed, Section 8.5. McGraw-Hill, 2007.

Extended Capabilities

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.

Version History

Introduced in R2013b

Pipe (TL)

Description

Pipe Effects

Mass Balance

Momentum Balance

Viscous Friction Pressure Losses

Energy Balance

Wall Heat Flow Rate

Assumptions and Limitations

Examples

Optimal Pipeline Geometry for Heated Oil Transportation

Engine Cooling System

Hydraulic Fluid Warming Due to Losses

Water Hammer Effect

Ports

Conserving

A — Inlet or outlet thermal liquid

B — Inlet or outlet thermal liquid

H — Temperature of pipe wall thermal

Parameters

Geometry

Pipe length — The length of the pipe 5 m (default)

Cross-sectional area — The internal area of the pipe 0.01 m^2 (default)

Hydraulic diameter — Diameter of an equivalent cylindrical pipe with the same cross-sectional area 0.1128 m (default)

Friction and Heat Transfer

Aggregate equivalent length of local resistances — The combined length of all local resistances present in the pipe 1 m (default)

Internal surface absolute roughness — Average depth of all surface defects on the internal surface of the pipe 15e-6 m (default)

Laminar flow upper Reynolds number limit — The Reynolds number above which flow begins to transition from laminar to turbulent 2000 (default)

Turbulent flow lower Reynolds number limit — The Reynolds number below which flow begins to transition from turbulent to laminar 4000 (default)

Shape factor for laminar flow viscous friction — Effect of pipe geometry on the viscous friction losses 64 (default)

Nusselt number for laminar flow heat transfer — Ratio of convective to conductive heat transfer 3.66 (default)

Effects and Initial Conditions

Fluid dynamic compressibility — Select whether to model fluid dynamic compressibility On (default) | Off

Fluid inertia — Select whether to model fluid inertia Off (default) | On

Dependencies

Initial liquid pressure — Liquid pressure at time zero 0.101325 MPa (default)

Dependencies

Initial liquid temperature — Liquid temperature at time zero 293.15 K (default)

Initial mass flow rate from port A to port B — Mass flow rate at time zero 0 kg/s (default)

Dependencies

References

Extended Capabilities

C/C++ Code Generation Generate C and C++ code using Simulink® Coder™.

Version History

See Also

Topics

A — Inlet or outlet
thermal liquid

B — Inlet or outlet
thermal liquid

H — Temperature of pipe wall
thermal

Pipe length — The length of the pipe
`5 m` (default)

Cross-sectional area — The internal area of the pipe
`0.01 m^2` (default)

Hydraulic diameter — Diameter of an equivalent cylindrical pipe with the same cross-sectional area
`0.1128 m` (default)

Aggregate equivalent length of local resistances — The combined length of all local resistances present in the pipe
`1 m` (default)

Internal surface absolute roughness — Average depth of all surface defects on the internal surface of the pipe
`15e-6 m` (default)

Laminar flow upper Reynolds number limit — The Reynolds number above which flow begins to transition from laminar to turbulent
`2000` (default)

Turbulent flow lower Reynolds number limit — The Reynolds number below which flow begins to transition from turbulent to laminar
`4000` (default)

Shape factor for laminar flow viscous friction — Effect of pipe geometry on the viscous friction losses
`64` (default)

Nusselt number for laminar flow heat transfer — Ratio of convective to conductive heat transfer
`3.66` (default)

Fluid dynamic compressibility — Select whether to model fluid dynamic compressibility
`On` (default) | `Off`

Fluid inertia — Select whether to model fluid inertia
`Off` (default) | `On`

Initial liquid pressure — Liquid pressure at time zero
`0.101325 MPa` (default)

Initial liquid temperature — Liquid temperature at time zero
`293.15 K` (default)

Initial mass flow rate from port A to port B — Mass flow rate at time zero
`0 kg/s` (default)

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.