System-Level Heat Exchanger (MA-MA)

Heat exchanger based on performance data between two moist air networks

Since R2025a

Libraries:
Simscape / Fluids / Heat Exchangers / Moist Air

Description

The System-Level Heat Exchanger (MA-MA) block models a heat exchanger based on performance data between two distinct moist air networks. Each network has its own set of fluid properties.

The block uses performance data from the heat exchanger datasheet, rather than the detailed geometry of the exchanger. You can adjust the size and performance of the heat exchanger during design iterations, or model heat exchangers with uncommon geometries. You can also use this block to model heat exchangers with a certain level of performance at an early design stage, when detailed geometry data is not yet available. You parameterize the block by the nominal operating condition. The heat exchanger is sized to match the specified performance at the nominal operating condition at steady state.

Both moist air sides model water vapor condensation based on convective water vapor mass transfer with the heat transfer surface. The block removes condensed water from the moist air flow.

Heat Transfer

The block divides each moist air flow into three segments of equal size and calculates heat transfer between the fluids is in each segment. For simplicity, the equation in this section are for one segment.

If you clear the Enable wall thermal mass check box, then the heat balance in the heat exchanger is

$Q_{s e g, M A 1} + Q_{s e g, M A 2} = 0,$

where:

Q_seg,MA1 is the heat flow rate from the wall that is the heat transfer surface to the moist air side 1 in the segment.
Q_seg,MA2 is the heat flow rate from the wall to the moist air side 2 in the segment.

If you select Enable wall thermal mass, then the heat balance in the heat exchanger is

$Q_{s e g, M A 1} + Q_{s e g, M A 2} = - \frac{M_{w a l l} c_{p_{w a l l}}}{N} \frac{d T_{s e g, w a l l}}{d t},$

where:

M_wall is the mass of the wall.
c_{p_wall} is the specific heat of the wall.
N = 3 is the number of segments.
T_seg,wall is the average wall temperature in the segment.
t is time.

The heat flow rate from the wall to each segment it segment is

$Q_{s e g, M A} = \frac{U A_{s e g, M A}}{{\bar{c}}_{p_{s e g, M A}}} ({\bar{h}}_{s e g, w a l l} - {\bar{h}}_{s e g, M A}) + {\dot{m}}_{w, s e g, c o n d} h_{l, w a l l},$

where:

UA_seg,MA is the heat transfer conductance for the moist air in the segment.
${\bar{c}}_{p_{s e g, M A}}$ is the moist air mixture specific heat per unit mass of dry air and trace gas in the segment.
${\bar{h}}_{s e g, w a l l}$ is the moist air mixture enthalpy per unit mass of dry air and trace gas at the average wall segment temperature.
${\bar{h}}_{s e g, M A}$ is the moist air mixture enthalpy per unit mass of dry air and trace gas in the segment.
${\dot{m}}_{w, s e g, c o n d}$ is the rate of water vapor condensation on the wall surface.
h_l,wall is the specific enthalpy of liquid water at the average wall segment temperature.

Using mixture enthalpy in this equation accounts for both differences in temperature and differences in humidity due to condensation [3].

The fluid properties that the block uses in heat transfer calculations are the average between the value at the inlet and the value in the fluid volume.

Note

In equations, the bar above the variables indicates that they are quantities for the moist air mixture divided by the mass of dry air and trace gas only, as opposed to dividing by the mass of the whole mixture. The whole mixture includes dry air, water vapor, and trace gas.

Moist Air Heat Transfer Correlation

The heat transfer conductance on each side of the heat exchanger is

$U A_{s e g, M A} = a_{M A} {({Re}_{s e g, M A})}^{b_{M A}} {(\Pr_{s e g, M A})}^{c_{M A}} k_{s e g, M A} \frac{G_{M A}}{N},$

where:

a_MA, b_MA, and c_MA are the coefficients of the Nusselt number correlation. These coefficients are block parameters in the Correlation Coefficients section.
Re_seg,MA is the average Reynolds number for the segment.
Pr_seg,MA is the average Prandtl number for the segment.
k_seg,MA is the average thermal conductivity for the segment.
G_MA is the geometry scale factor for the moist air side of the heat exchanger. The block calculates the geometry scale factor so that the total heat transfer over all segments matches the specified performance at the nominal operating conditions.

The average Reynolds number is

${Re}_{s e g, M A} = \frac{{\dot{m}}_{s e g, M A} D_{r e f, M A}}{μ_{s e g, M A} S_{r e f, M A}},$

where:

${\dot{m}}_{s e g, M A}$ is the mass flow rate through the segment.
μ_seg,MA is the average dynamic viscosity for the segment.
D_ref,MA is an arbitrary reference diameter.
S_ref,MA is an arbitrary reference flow area.

Note

The D_ref,MA and S_ref,MA terms are included in this equation for unit calculation purposes only, to make Re_seg,MA nondimensional. The values of D_ref,MA and S_ref,MA are arbitrary because the G_MA calculation overrides these values.

Condensation

The equation that describes the heat flow rate from the wall to the moist air in the segment uses the average moist air mixture enthalpy, ${\bar{h}}_{s e g, M A}$ , and the wall segment moist air mixture enthalpy, ${\bar{h}}_{s e g, w a l l}$ .

The average moist air mixture enthalpy is based on the temperature and humidity of the moist air flow through the segment

${\bar{h}}_{s e g, M A} = h_{s e g, a g, M A} + W_{s e g, M A} h_{s e g, w, M A},$

where:

h_seg,ag,MA is the average specific enthalpy of dry air and trace gas for the segment.
h_seg,w,MA is the average specific enthalpy of water vapor for the segment.
W_seg,MA is the humidity ratio of the segment.

The wall segment moist air mixture enthalpy is based on the temperature and humidity at the wall segment

${\bar{h}}_{s e g, w a l l} = h_{s e g, a g, w a l l} + W_{s e g, w a l l} h_{s e g, w, w a l l},$

where:

h_seg,ag,wall is the specific enthalpy of dry air and trace gas at the wall segment temperature.
h_seg,w,wall is the specific enthalpy of water vapor at the wall segment temperature.
W_seg,wall is the humidity ratio at the wall segment:
$W_{s e g, w a l l} = \min (W_{s e g, M A}, W_{s e g, s, w a l l}),$
where W_seg,s,wall is the saturated humidity ratio at the wall segment temperature. In other words, the humidity ratio at the wall is the same as the humidity ratio of the moist air flow but not more than the maximum that can be supported at the wall segment temperature.

When W_seg,s,wall < W_seg,MA, water vapor condensation occurs on the wall surface. The rate of water vapor condensation is

${\dot{m}}_{w, s e g, c o n d} = \frac{U A_{s e g, M A}}{{\bar{c}}_{p_{s e g, M A}}} (W_{s e g, M A} - W_{s e g, w a l l}) .$

The block assumes that the condensed water is drained from the wall surface and is thus removed from the moist air flow downstream.

Pressure Loss

The pressure losses on each side of the heat exchanger are

$\begin{array}{l} p_{A, M A} - p_{M A} = \frac{K_{M A}}{2} \frac{{\dot{m}}_{A, M A} \sqrt{{\dot{m}}^{2}_{A, M A} + {\dot{m}}^{2}_{t h r e s, M A}}}{2 ρ_{a v g, 2 P}} \\ p_{B, M A} - p_{M A} = \frac{K_{M A}}{2} \frac{{\dot{m}}_{B, M A} \sqrt{{\dot{m}}^{2}_{B, M A} + {\dot{m}}^{2}_{t h r e s, M A}}}{2 ρ_{a v g, M A}} \end{array}$

where:

p_A,MA and p_B,MA are the pressures at ports A1 and B1 or A2 and B2.
p_MA is internal moist air pressure at which the heat transfer is calculated.
${\dot{m}}_{A, M A}$ and ${\dot{m}}_{B, M A}$ are the mass flow rates into ports A1 and B1 or A2 and B2.
ρ_avg,MA is the average moist air density over all segments.
${\dot{m}}_{t h r e s, M A}$ is the laminar threshold for pressure loss, approximated as 1e-4 of the nominal mass flow rate. The block calculates the pressure loss coefficient, K_MA, so that p_A,MA – p_B,MA matches the nominal pressure loss at the nominal mass flow rate.

Moist Air Mass and Energy Conservation

The mass conservation on each side of the heat exchanger for the overall moist air mixture flow is

$\begin{array}{l} (\frac{d p_{M A}}{d t} \sum_{s e g m e n t s} (\frac{\partial ρ_{s e g, M A}}{\partial p}) + \sum_{s e g m e n t s} (\frac{d T_{s e g, M A}}{d t} \frac{\partial ρ_{s e g, M A}}{\partial T} + \frac{d x_{w, s e g, M A}}{d t} \frac{\partial ρ_{s e g, M A}}{\partial x_{w}} + \frac{d x_{g, s e g, M A}}{d t} \frac{\partial ρ_{s e g, M A}}{\partial x_{g}})) \frac{V_{M A}}{N} \\ = {\dot{m}}_{A, M A} + {\dot{m}}_{B, M A} - \sum_{s e g m e n t s} ({\dot{m}}_{w, s e g, c o n d} + {\dot{m}}_{w, s e g, c o n v}) + \sum_{s e g m e n t s} {\dot{m}}_{d, s e g, e v a p}, \end{array}$

where:

$\frac{\partial ρ_{s e g, M A}}{\partial p}$ is the partial derivative of density with respect to pressure for the segment.
$\frac{\partial ρ_{s e g, M A}}{\partial T}$ is the partial derivative of density with respect to temperature for the segment.
$\frac{\partial ρ_{s e g, M A}}{\partial x_{w}}$ is the partial derivative of density with respect to specific humidity for the segment.
$\frac{\partial ρ_{s e g, M A}}{\partial x_{g}}$ is the partial derivative of density with respect to trace gas mass fraction for the segment.
x_w,seg,MA is the specific humidity, also referred to as the water vapor mass fraction, for the segment.
x_g,seg,MA is the trace gas mass fraction for the segment.
V_MA is the total moist air volume.
$\dot{m}$ _w,seg,conv is the rate of condensation on the wall surface for the segment.
$\dot{m}$ _d,seg,evap is the rate of water droplet evaporation for the segment.

The summation is over all segments.

Note

Although the block divides each moist air flow into N=3 segments for heat transfer calculations, it assumes all segments on one side are at the same internal pressure, p_MA. Consequentially, p_MA is outside of the summation.

The energy conservation equation for each segment is

$\begin{array}{l} \frac{d T_{s e g, M A}}{d t} ({\bar{c}}_{s e g, M A} - R_{s e g}) \frac{M_{M A}}{N} + u_{a, s e g, M A} ({\dot{m}}_{s e g, i n, M A} - {\dot{m}}_{s e g, o u t, M A}) + (u_{w, s e g, M A} - u_{a, s e g, M A}) ({\dot{m}}_{w, s e g, i n, M A} - {\dot{m}}_{w, s e g, o u t, M A}) + \\ (u_{g, s e g, M A} - u_{a, s e g, M A}) ({\dot{m}}_{g, s e g, i n, M A} - {\dot{m}}_{g, s e g, o u t, M A}) + h_{d} ({\dot{m}}_{d, s e g, i n, M A} - {\dot{m}}_{d, s e g, o u t, M A}) \\ = Φ_{s e g, i n, M A} - Φ_{s e g, o u t, M A} + Q_{s e g, M A} - (1 - λ_{d}) ({\dot{m}}_{w, s e g, c o n d} h_{d} + {\dot{m}}_{w, s e g, c o n v} h_{l, w a l l}), \end{array}$

where:

u_a,seg,MA is the dry air specific internal energy for the segment.
u_g,seg,MA is the trace gas specific internal energy for the segment.
u_w,seg,MA is the water vapor specific internal energy for the segment.
M_MA is the total moist air mass.
${\dot{m}}_{s e g, i n, M A}$ and ${\dot{m}}_{s e g, o u t, M A}$ are the moist air mass flow rates into and out of the segment.
${\dot{m}}_{w, s e g, i n, M A}$ and ${\dot{m}}_{w, s e g, o u t, M A}$ are the water vapor mass flow rates into and out of the segment.
${\dot{m}}_{g, s e g, i n, M A}$ and ${\dot{m}}_{g, s e g, o u t, M A}$ are the trace gas mass flow rates into and out of the segment.
${\dot{m}}_{d, s e g, i n, M A}$ and ${\dot{m}}_{d, s e g, o u t, M A}$ are the water droplets mass flow rate into and out of the segment.
R_seg is the segment volume specific gas constant.
Φ_seg,in,MA and Φ_seg,out,MA are the energy flow rates into and out of the segment.
h_d is the water droplet specific enthalpy in the segment.
λ_d is the value of the Fraction of condensate entrained as water droplets parameter.

The block assumes the mass flow rates between segments are linearly distributed between the values of ${\dot{m}}_{A, M A}$ and ${\dot{m}}_{B, M A}$ .

The water vapor mass conservation equation for each segment is

$\begin{array}{l} \frac{d x_{w, s e g, M A}}{d t} \frac{M_{M A}}{N} + x_{w, s e g, M A} ({\dot{m}}_{s e g, i n, M A} - {\dot{m}}_{s e g, o u t, M A}) = \\ {\dot{m}}_{w, s e g, i n, M A} - {\dot{m}}_{w, s e g, o u t, M A} - {\dot{m}}_{w, s e g, c o n d} - {\dot{m}}_{w, s e g, c o n v} + {\dot{m}}_{d, s e g, e v a p} . \end{array}$

The trace gas mass conservation equation for each segment is

$\begin{array}{l} \frac{d x_{g, s e g, M A}}{d t} \frac{M_{M A}}{N} + x_{g, s e g, M A} ({\dot{m}}_{s e g, i n, M A} - {\dot{m}}_{s e g, o u t, M A}) = \\ {\dot{m}}_{g, s e g, i n, M A} - {\dot{m}}_{g, s e g, o u t, M A} . \end{array}$

The water droplet mass balance conservation equation for each segment is

$\begin{array}{l} \frac{d r_{d, s e g}}{d t} \frac{M_{M A}}{N} + r_{d, s e g} ({\dot{m}}_{s e g, i n, M A} - {\dot{m}}_{s e g, o u t, M A}) = \\ {\dot{m}}_{d, s e g, i n} - {\dot{m}}_{d, s e g, o u t} + λ_{d} ({\dot{m}}_{w, s e g, c o n d} + {\dot{m}}_{w, s e g, c o n v}) - {\dot{m}}_{d, s e g, e v a p}, \end{array}$

where r_d,seg is the mass ratio of the water droplets to the moist air in the fluid volume in the segment.

Note

If the Trace gas model parameter is None in the Moist Air Properties (MA) block, the moist air network does not model trace gas. In this case, in the System-Level Heat Exchanger (MA-MA) block on the corresponding side of the heat exchanger, the conservation equation for trace gas is set to 0.

If you clear the Enable entrained water droplets in the Moist Air Properties (MA) block, the moist air network does not model entrained water droplets. In this case, in the System-Level Heat Exchanger (MA-MA) block on the corresponding side of the heat exchanger, the conservation equation for water droplets is set to 0.

Assumptions and Limitations

When determining the heat exchanger size, the block ignores the value of the Fraction of condensate entrained as water droplets parameters and assumes that the condensate is not entrained as droplets.

Ports

Output

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Q1 — Rate of heat transfer to moist air 1, W
physical signal

Rate of heat transfer to moist air 1, returned as a physical signal, in W. The physical signals at ports Q1 and Q2 are usually equal in value with opposite sign. However, if you select Enable wall thermal mass, then these two signals may have different values because the wall may absorb and release some of the heat being transferred.

Q2 — Rate of heat transfer to moist air 2, W
physical signal

Rate of heat transfer to moist air 2, returned as a physical signal, in W. The physical signals at ports Q1 and Q2 are usually equal in value with opposite sign. However, if you select Enable wall thermal mass, then these two signals may have different values because the wall may absorb and release some of the heat being transferred.

W1 — Moist air 1 condensation rate, kg/s
physical signal

Water condensation rate that leaves the moist air 1 flow, returned as a physical signal. The value of this port does not include the portion of condensation that is entrained as water droplets. The condensate does not accumulate on the heat transfer surface.

W2 — Moist air 2 condensation rate, kg/s
physical signal

Water condensation rate that leaves the moist air 2 flow, returned as a physical signal. The value of this port does not include the portion of condensation that is entrained as water droplets. The condensate does not accumulate on the heat transfer surface.

Conserving

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A1 — Moist air port on side 1
moist air

Inlet or outlet port associated with the moist air on side 1.

B1 — Moist air port on side 1
moist air

Inlet or outlet port associated with the moist air on side 1.

A2 — Moist air port on side 2
moist air

Inlet or outlet port associated with the moist air on side 2.

B2 — Moist air port on side 2
moist air

Inlet or outlet port associated with the moist air on side 2.

Parameters

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Configuration

Flow arrangement at nominal operating conditions — Flow path alignment
`Parallel flow - Both fluids flow from A to B` (default) | `Counter flow - Moist Air 1 flows from A to B, Moist Air 2 flows from B to A` | `Cross flow - Both fluids flow from A to B`

Flow path alignment between the heat exchanger sides at nominal operating condition. The available flow arrangements are:

Parallel flow - Both fluids flow from A to B — The flows run parallel to each other, in the opposite directions.
Parallel flow - Both fluids flow from A to B — The flows run in the same direction.
Cross flow - Both fluids flow from A to B — The flows run perpendicular to each other.

The choice between parallel flow and counter flow affects how the block determines the size of the heat exchanger. The counter flow setting is the most effective, and needs the smallest size to meet the specified performance. Conversely, parallel flow is the least effective, and needs the biggest size to meet the specified performance.

Flow direction at the nominal condition (from A to B, or from B to A) only affects the model initialization, when you select Initialize moist air 1 to nominal operating conditions or Initialize moist air 2 to nominal operating conditions. If you set different initial operating conditions, the flow directions can be different.

After the block determines the size of the heat exchanger, this setting does not play a role in how the block calculates the heat transfer during simulation. Instead, the heat transfer depends on the flow directions during simulation. For example, if you set the parameter to parallel flow but set up the model to run in counter flow, then the rate of heat transfer during simulation will not match the specified performance, even if the rest of the boundary conditions are the same.

If you set the parameter to cross flow, then the block models the flow paths as perpendicular inside the heat exchanger, so the flow directions during simulation do not matter.

Enable wall thermal mass — Whether to enable effect of thermal mass on heat transfer surface
`off` (default) | `on`

Whether to enable the effect of thermal mass on the heat transfer surface. When you select this parameter, the block introduces additional dynamics to the simulation and takes longer to reach steady state, but this parameter does not affect the results at steady-state simulation.

Wall mass — Mass of heat transfer surface
`1 kg` (default) | positive scalar

Mass of the heat transfer surface.

Dependencies

To enable this parameter, select Enable wall thermal mass.

Wall specific heat — Specific heat of heat transfer surface
`490 J/(K*kg)` (default) | positive scalar

Specific heat of the heat transfer surface.

Dependencies

To enable this parameter, select Enable wall thermal mass.

Initialize wall temperature to nominal operating conditions — Option for initializing wall temperature
`on` (default) | `off`

Option to initialize the wall temperature to nominal operating conditions or specified values. If you select this parameter, the block calculates the initial wall temperature from the nominal operating conditions specified for both fluid sides. If you clear this parameter, you can specify the initial wall temperature directly with the Initial wall temperature parameter.

Dependencies

To enable this parameter, select Enable wall thermal mass.

Initial wall temperature — Initial temperature of wall
`293.15 K` (default) | positive scalar or two-element vector

Initial temperature of the wall. If you specify a scalar, the block assumes that the initial wall temperature is uniform. If you specify a two-element vector, then the block assumes that the initial wall temperature varies linearly between ports A1 and A2 and ports B1 and B2. The first element corresponds to the temperature at ports A1 and A2 and the second element corresponds to the temperature at ports B1 and B2.

Dependencies

To enable this parameter, select Enable wall thermal mass and clear the Initialize wall temperature to nominal operating conditions check box.

Cross-sectional area at port A1 — Flow area at port A1
`0.01 m^2` (default) | positive scalar

Flow area at the moist air port A1.

Cross-sectional area at port B1 — Flow area at port B1
`0.01 m^2` (default) | positive scalar

Flow area at the moist air port B1.

Cross-sectional area at port A2 — Flow area at port A2
`0.01 m^2` (default) | positive scalar

Flow area at the moist air port A2.

Cross-sectional area at port B2 — Area normal to flow at port B2
`0.01 m^2` (default) | positive scalar

Flow area at the moist air port B2.

Moist Air 1

Nominal operating condition — Nominal operating condition
`Heat transfer from Moist Air 1 to Moist Air 2` (default) | `Heat transfer from Moist Air 2 to Moist Air 1`

Nominal operating condition:

Heat transfer from Moist Air 1 to Moist Air 2 — The moist air 1 is cooled and the moist air 2 is heated.
Heat transfer from Moist Air 2 to Moist Air 1 — The moist air 2 is cooled and the moist air 1 is heated.

This setting relates only to the nominal operating condition parameters. It does not mean that heat transfer can only happen in the specified direction during simulation.

Nominal mass flow rate — Mass flow rate between moist air 1 ports during nominal operating condition
`0.1 kg/s` (default) | positive scalar

Mass flow rate from port A1 to port B1 during the nominal operating condition.

Nominal pressure drop — Pressure drop between moist air 1 ports during nominal operating condition
`0.01 MPa` (default) | positive scalar

Pressure drop from port A1 to port B1 during the nominal operating condition.

Nominal inlet pressure — Pressure at the moist air 1 inlet
`0.101325 MPa` (default) | positive scalar

Pressure at the moist air 1 inlet of the heat exchanger during nominal operating condition.

Nominal inlet temperature — Temperature at the moist air 1 inlet
`333.15 K` (default) | positive scalar

Temperature at the moist air 1 inlet of the heat exchanger during the nominal operating condition.

Inlet humidity specification — Quantity used to describe the humidity level at the moist air 1 side inlet
`Relative humidity` (default) | `Specific humidity` | `Mole fraction` | `Humidity ratio` | `Wet-bulb temperature`

Select quantity used to describe the humidity level at the inlet during the nominal operating condition.

Nominal inlet relative humidity — Relative humidity at the inlet
`0.5` (default) | scalar in the range [0,1]

Relative humidity at the moist air 1 inlet of the heat exchanger during the nominal operating conditions.

Dependencies

To enable this parameter, set Inlet humidity specification to Relative humidity.

Nominal inlet specific humidity — Specific humidity at the inlet
`0.01` (default) | scalar in the range [0,1]

Specific humidity, defined as the mass fraction of water vapor in a moist air 1 mixture, at the moist air inlet of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Inlet humidity specification to Specific humidity.

Nominal inlet water vapor mole fraction — Mole fraction of water vapor at the inlet
`0.01` (default) | scalar in the range [0,1]

Mole fraction of water vapor in a moist air 1 mixture at the moist air inlet of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Inlet humidity specification to Mole fraction.

Nominal inlet humidity ratio — Humidity ratio at the inlet
`0.01` (default) | positive scalar in the range [0,1]

Humidity ratio, defined as the mass ratio of water vapor to dry air and trace gas, at the moist air 1 inlet of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Inlet humidity specification to Humidity ratio.

Nominal inlet wet-bulb temperature — Wet-bulb temperature at the start of simulation
`287 K` (default) | positive scalar in the range [0,1]

Wet-bulb temperature at the moist air 1 inlet of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Inlet humidity specification to Wet-bulb temperature.

Inlet trace gas specification — Quantity used to describe trace gas level at the inlet
`Mass fraction` (default) | `Mole fraction`

Select quantity used to describe the trace gas level at the inlet during the nominal operating condition: mass fraction or mole fraction.

Nominal inlet trace gas mass fraction — Mass fraction of trace gas at the inlet
`0.001` (default) | scalar in the range [0,1]

Mass fraction of trace gas in a moist air 1 mixture at the moist air inlet of the heat exchanger during the nominal operating condition.

This parameter is ignored if the Trace gas model parameter in the Moist Air Properties (MA) block is set to None.

Dependencies

To enable this parameter, set Inlet trace gas specification to Mass fraction.

Nominal inlet trace gas mole fraction — Mole fraction of trace gas at the inlet
`0.001` (default) | scalar in the range [0,1]

Mole fraction of trace gas in a moist air 1 mixture at the moist air inlet of the heat exchanger during the nominal operating condition.

This parameter is ignored if the Trace gas model parameter in the Moist Air Properties (MA) block is set to None.

Dependencies

To enable this parameter, set Inlet trace gas specification to Mole fraction.

Heat transfer capacity specification — How to specify heat transfer capacity of moist air 1
`Rate of heat transfer` (default) | `Outlet condition`

Whether to specify the performance of the heat exchanger for the moist air 1 at the nominal operating condition directly, by the rate of heat transfer, or indirectly, by the outlet condition.

Dependencies

To enable this parameter, set Nominal operating condition to Heat transfer from Moist Air 2 to Moist Air 1.

Nominal rate of heat transfer — Rate of heat transfer
`1 kW` (default) | positive scalar

Rate of heat transfer. The Nominal Operating condition parameter determines the network that the heat transfers from and to:

If Nominal operating condition is Heat transfer from Moist Air 1 to Moist Air 2, this parameter is the rate of the heat transfer from the moist air 1 to the moist air 2 during the nominal operating condition.
If Nominal operating condition is Heat transfer from Moist Air 2 to Moist Air 1, this parameter is the rate of the heat transfer from the moist air 1 to the moist air 2 during the nominal operating condition.

Dependencies

To enable this parameter, set either:

Nominal operating condition to Heat transfer from Moist Air 1 to Moist Air 2.
Nominal operating condition to Heat transfer from Moist Air 2 to Moist Air 1 and Heat transfer capacity specification to Rate of heat transfer.

Nominal outlet temperature — Outlet temperature
`323.15 K` (default) | positive scalar

Temperature at the outlet of the moist air 1 side of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Nominal operating condition to Heat transfer from Moist Air 2 to Moist Air 1 and Heat transfer capacity specification to Outlet condition.

Moist air 1 volume — Total volume of moist air on side 1 of the heat exchanger
`0.1 m^3` (default) | positive scalar

Total volume of moist air on side 1 of the heat exchanger.

Initialize moist air 1 to nominal operating conditions — Option for initializing moist air 1
`on` (default) | `off`

Option to initialize the moist air 1 to nominal operating conditions or specified values. If you select this parameter, the block initializes the moist air 1 to the nominal operating conditions. If you clear this check box, you can specify the initial conditions directly with additional parameters.

Initial moist air 1 pressure — Moist air 1 pressure at start of simulation
`0.101325 MPa` (default) | positive scalar

Moist air 1 pressure at the start of the simulation.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box.

Initial moist air 1 temperature — Moist air temperature at start of simulation
`293.15 K` (default) | positive scalar | two-element vector

Moist air 1 temperature at the start of simulation. If the value is a scalar, then the initial temperature is assumed uniform. If the value is a two-element vector, then the initial temperature is assumed to vary linearly between ports A2 and B2, with the first element corresponding to port A2 and the second element corresponding to port B2.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box.

Initial humidity specification — Quantity used to describe the initial humidity level
`Relative humidity` (default) | `Specific humidity` | `Mole fraction` | `Humidity ratio` | `Wet-bulb temperature`

Select quantity used to describe the initial humidity level: relative humidity, specific humidity, water vapor mole fraction, or humidity ratio.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box.

Initial moist air 1 relative humidity — Relative humidity at start of simulation
`0.5` (default) | scalar in the range [0,1] | two-element vector

Moist air 1 relative humidity at the start of simulation. If the value is a scalar, then the initial relative humidity is assumed uniform. If the value is a two-element vector, then the initial relative humidity is assumed to vary linearly between ports A1 and B1, with the first element corresponding to port A1 and the second element corresponding to port B1.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box and set Initial humidity specification to Relative humidity.

Initial moist air 1 specific humidity — Specific humidity at start of simulation
`0.01` (default) | scalar in the range [0,1] | two-element vector

Moist air 1 specific humidity, defined as the mass fraction of water vapor in a moist air mixture, at the start of simulation. If the value is a scalar, then the initial specific humidity is assumed uniform. If the value is a two-element vector, then the initial specific humidity is assumed to vary linearly between ports A1 and B1, with the first element corresponding to port A1 and the second element corresponding to port B1.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box and set Initial humidity specification to Specific humidity.

Initial moist air 1 water vapor mole fraction — Mole fraction of water vapor at start of simulation
`0.01` (default) | scalar in the range [0,1] | two-element vector

Mole fraction of water vapor in a moist air 1 mixture at the start of simulation. If the value is a scalar, then the initial mole fraction is assumed uniform. If the value is a two-element vector, then the initial mole fraction is assumed to vary linearly between ports A1 and B1, with the first element corresponding to port A1 and the second element corresponding to port B1.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box and set Initial humidity specification to Mole fraction.

Initial moist air 1 humidity ratio — Humidity ratio at start of simulation
`0.01` (default) | positive scalar in the range [0,1] | two-element vector

Moist air 1 humidity ratio, defined as the mass ratio of water vapor to dry air and trace gas, at the start of simulation. If the value is a scalar, then the initial humidity ratio is assumed uniform. If the value is a two-element vector, then the initial humidity ratio is assumed to vary linearly between ports A1 and B1, with the first element corresponding to port A1 and the second element corresponding to port B1.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box and set Initial humidity specification to Humidity ratio.

Initial moist air 1 wet-bulb temperature — Wet-bulb temperature at the start of simulation
`287 K` (default) | positive scalar in the range [0,1]

Wet-bulb temperature at the start of the simulation. The block uses this value to calculate humidity.

This parameter can be a scalar or a two-element vector. A scalar value represents the mean initial wet-bulb temperature in the channel. A vector value represents the initial wet-bulb temperature at the inlet and outlet in the form [inlet, outlet]. The block calculates a linear gradient between the two ports. The inlet and the outlet ports are identified according to the initial flow direction.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box and set Initial humidity specification to Wet-bulb temperature.

Initial trace gas specification — Quantity used to describe initial trace gas level
`Mass fraction` (default) | `Mole fraction`

Select the quantity used to describe the trace gas level at the start of simulation: mass fraction or mole fraction.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box.

Initial moist air 1 trace gas mass fraction — Mass fraction of trace gas at start of simulation
`0.001` (default) | scalar in the range [0,1] | two-element vector

Mass fraction of trace gas in a moist air 1 mixture at the start of simulation. If the value is a scalar, then the initial mass fraction is assumed uniform. If the value is a two-element vector, then the initial mass fraction is assumed to vary linearly between ports A1 and B1, with the first element corresponding to port A1 and the second element corresponding to port B1.

This parameter is ignored if the Trace gas model parameter in the Moist Air Properties (MA) block is set to None.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box and set Initial trace gas specification to Mass fraction.

Initial moist air 1 trace gas mole fraction — Mole fraction of trace gas at start of simulation
`0.001` (default) | scalar in the range [0,1] | two-element vector

Mole fraction of trace gas in a moist air 1 mixture at the start of simulation. If the value is a scalar, then the initial mole fraction is assumed uniform. If the value is a two-element vector, then the initial mole fraction is assumed to vary linearly between ports A1 and B1, with the first element corresponding to port A1 and the second element corresponding to port B1.

This parameter is ignored if the Trace gas model parameter in the Moist Air Properties (MA) block is set to None.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box and set Initial trace gas specification to Mole fraction.

Initial mass ratio of water droplets to moist air — Ratio of water droplets to moist air
`0` (default) | positive scalar

Initial mass ratio of water droplets to moist air.

Dependencies

To enable this parameter, clear the Initialize moist air 1 to nominal operating conditions check box.

Relative humidity at saturation — Relative humidity point of condensation
`1` (default) | nonnegative scalar

Relative humidity point of condensation. Condensation occurs above this value. In most cases, this value is 1, that is, 100%. A value greater than 1 indicates a supersaturated vapor.

Water vapor condensation time constant — Time scale for condensation
`1e-3 s` (default) | positive scalar

Characteristic time scale at which an oversaturated moist air volume returns to saturation by condensing out excess humidity.

Water droplets evaporation time constant — Time scale for evaporation
`1e-3 s` (default) | positive scalar

Characteristic time scale at which water droplets evaporate to vapor.

Fraction of condensate entrained as water droplets — Fraction of condensate in water droplets
`1` (default) | scalar in the range [0,1]

Fraction of the condensate in the moist air that is entrained as water droplets.

Moist Air 2

Nominal mass flow rate — Mass flow rate between moist air 2 ports during nominal operating condition
`0.1 kg/s` (default) | positive scalar

Mass flow rate from port A2 to port B2 during the nominal operating condition.

Nominal pressure drop — Pressure drop between moist air 2 ports during nominal operating condition
`0.001 MPa` (default) | positive scalar

Pressure drop from port A2 to port B2 during the nominal operating condition.

Nominal inlet pressure — Pressure at the moist air 2 side inlet
`0.101325 MPa` (default) | positive scalar

Pressure at the moist air 2 inlet of the heat exchanger during nominal operating condition.

Nominal inlet temperature — Temperature at the moist air 2 side inlet
`293.15 K` (default) | positive scalar

Temperature at the moist air 2 inlet of the heat exchanger during the nominal operating condition.

Inlet humidity specification — Quantity used to describe the humidity level at the moist air side inlet
`Relative humidity` (default) | `Specific humidity` | `Mole fraction` | `Humidity ratio` | `Wet-bulb temperature`

Select quantity used to describe the humidity level at the inlet during the nominal operating condition.

Nominal inlet relative humidity — Relative humidity at the inlet
`0.5` (default) | scalar in the range [0,1]

Relative humidity at the moist air 2 inlet of the heat exchanger during the nominal operating conditions.

Dependencies

To enable this parameter, set Inlet humidity specification to Relative humidity.

Nominal inlet specific humidity — Specific humidity at the inlet
`0.01` (default) | scalar in the range [0,1]

Specific humidity, defined as the mass fraction of water vapor in a moist air mixture, at the moist air 2 inlet of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Inlet humidity specification to Specific humidity.

Nominal inlet water vapor mole fraction — Mole fraction of water vapor at the inlet
`0.01` (default) | scalar in the range [0,1]

Mole fraction of water vapor in a moist air mixture at the moist air 2 inlet of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Inlet humidity specification to Mole fraction.

Nominal inlet humidity ratio — Humidity ratio at the inlet
`0.01` (default) | positive scalar in the range [0,1]

Humidity ratio, defined as the mass ratio of water vapor to dry air and trace gas, at the moist air 2 inlet of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Inlet humidity specification to Humidity ratio.

Nominal inlet wet-bulb temperature — Wet-bulb temperature at the start of simulation
`287 K` (default) | positive scalar in the range [0,1]

Wet-bulb temperature at the moist air 2 inlet of the heat exchanger during the nominal operating condition.

Dependencies

To enable this parameter, set Inlet humidity specification to Wet-bulb temperature.

Inlet trace gas specification — Quantity used to describe trace gas level at the inlet
`Mass fraction` (default) | `Mole fraction`

Select quantity used to describe the trace gas level at the inlet during the nominal operating condition: mass fraction or mole fraction.

Nominal inlet trace gas mass fraction — Mass fraction of trace gas at the inlet
`0.001` (default) | scalar in the range [0,1]

Mass fraction of trace gas in a moist air mixture at the moist air 2 inlet of the heat exchanger during the nominal operating condition.

This parameter is ignored if the Trace gas model parameter in the Moist Air Properties (MA) block is set to None.

Dependencies

To enable this parameter, set Inlet trace gas specification to Mass fraction.

Nominal inlet trace gas mole fraction — Mole fraction of trace gas at the inlet
`0.001` (default) | scalar in the range [0,1]

Mole fraction of trace gas in a moist air mixture at the moist air 2 inlet of the heat exchanger during the nominal operating condition.

This parameter is ignored if the Trace gas model parameter in the Moist Air Properties (MA) block is set to None.

Dependencies

To enable this parameter, set Inlet trace gas specification to Mole fraction.

Moist air 2 volume — Total volume of moist air on side 2 of the heat exchanger
`0.1 m^3` (default) | positive scalar

Total volume of moist air on side 2 of the heat exchanger.

Initialize moist air 2 to nominal operating conditions — Option for initializing moist air
`on` (default) | `off`

Option to initialize the moist air 2 to nominal operating conditions or specified values. If you select this parameter, the block initializes the moist air to the nominal operating conditions. If you clear this check box, you can specify the initial conditions directly with additional parameters.

Initial moist air 2 pressure — Moist air pressure at start of simulation
`0.101325 MPa` (default) | positive scalar

Moist air 2 pressure at the start of the simulation.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box.

Initial moist air 2 temperature — Moist air temperature at start of simulation
`293.15 K` (default) | positive scalar | two-element vector

Moist air 2 temperature at the start of simulation. If the value is a scalar, then the initial temperature is assumed uniform. If the value is a two-element vector, then the initial temperature is assumed to vary linearly between ports A2 and B2, with the first element corresponding to port A2 and the second element corresponding to port B2.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box.

Initial humidity specification — Quantity used to describe the initial humidity level
`Relative humidity` (default) | `Specific humidity` | `Mole fraction` | `Humidity ratio` | `Wet-bulb temperature`

Select quantity used to describe the initial humidity level: relative humidity, specific humidity, water vapor mole fraction, or humidity ratio.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box.

Initial moist air 2 relative humidity — Relative humidity at start of simulation
`0.5` (default) | scalar in the range [0,1] | two-element vector

Moist air 2 relative humidity at the start of simulation. If the value is a scalar, then the initial relative humidity is assumed uniform. If the value is a two-element vector, then the initial relative humidity is assumed to vary linearly between ports A2 and B2, with the first element corresponding to port A2 and the second element corresponding to port B2.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box and set Initial humidity specification to Relative humidity.

Initial moist air 2 specific humidity — Specific humidity at start of simulation
`0.01` (default) | scalar in the range [0,1] | two-element vector

Moist air 2 specific humidity, defined as the mass fraction of water vapor in a moist air mixture, at the start of simulation. If the value is a scalar, then the initial specific humidity is assumed uniform. If the value is a two-element vector, then the initial specific humidity is assumed to vary linearly between ports A2 and B2, with the first element corresponding to port A2 and the second element corresponding to port B2.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box and set Initial humidity specification to Specific humidity.

Initial moist air 2 water vapor mole fraction — Mole fraction of water vapor at start of simulation
`0.01` (default) | scalar in the range [0,1] | two-element vector

Mole fraction of water vapor in a moist air 2 mixture at the start of simulation. If the value is a scalar, then the initial mole fraction is assumed uniform. If the value is a two-element vector, then the initial mole fraction is assumed to vary linearly between ports A2 and B2, with the first element corresponding to port A2 and the second element corresponding to port B2.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box and set Initial humidity specification to Mole fraction.

Initial moist air 2 humidity ratio — Humidity ratio at start of simulation
`0.01` (default) | positive scalar in the range [0,1] | two-element vector

Moist air 2 humidity ratio, defined as the mass ratio of water vapor to dry air and trace gas, at the start of simulation. If the value is a scalar, then the initial humidity ratio is assumed uniform. If the value is a two-element vector, then the initial humidity ratio is assumed to vary linearly between ports A2 and B2, with the first element corresponding to port A2 and the second element corresponding to port B2.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box and set Initial humidity specification to Humidity ratio.

Initial moist air 2 wet-bulb temperature — Wet-bulb temperature at the start of simulation
`287 K` (default) | positive scalar in the range [0,1]

Wet-bulb temperature at the start of the simulation. The block uses this value to calculate humidity.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box and set Initial humidity specification to Wet-bulb temperature.

Initial trace gas specification — Quantity used to describe initial trace gas level
`Mass fraction` (default) | `Mole fraction`

Select the quantity used to describe the trace gas level at the start of simulation: mass fraction or mole fraction.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box.

Initial moist air 2 trace gas mass fraction — Mass fraction of trace gas at start of simulation
`0.001` (default) | scalar in the range [0,1] | two-element vector

Mass fraction of trace gas in a moist air mixture at the start of simulation. If the value is a scalar, then the initial mass fraction is assumed uniform. If the value is a two-element vector, then the initial mass fraction is assumed to vary linearly between ports A2 and B2, with the first element corresponding to port A2 and the second element corresponding to port B2.

This parameter is ignored if the Trace gas model parameter in the Moist Air Properties (MA) block is set to None.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box and set Initial trace gas specification to Mass fraction.

Initial moist air 2 trace gas mole fraction — Mole fraction of trace gas at start of simulation
`0.001` (default) | scalar in the range [0,1] | two-element vector

Mole fraction of trace gas in a moist air 2 mixture at the start of simulation. If the value is a scalar, then the initial mole fraction is assumed uniform. If the value is a two-element vector, then the initial mole fraction is assumed to vary linearly between ports A2 and B2, with the first element corresponding to port A2 and the second element corresponding to port B2.

This parameter is ignored if the Trace gas model parameter in the Moist Air Properties (MA) block is set to None.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box and set Initial trace gas specification to Mole fraction.

Initial mass ratio of water droplets to moist air — Ratio of water droplets to moist air
`0` (default) | positive scalar

Initial mass ratio of water droplets to moist air.

Dependencies

To enable this parameter, clear the Initialize moist air 2 to nominal operating conditions check box.

Relative humidity at saturation — Relative humidity point of condensation
`1` (default) | nonnegative scalar

Relative humidity point of condensation. Condensation occurs above this value. In most cases, this value is 1, that is, 100%. A value greater than 1 indicates a supersaturated vapor.

Water vapor condensation time constant — Time scale for condensation
`1e-3 s` (default) | positive scalar

Characteristic time scale at which an oversaturated moist air volume returns to saturation by condensing out excess humidity.

Water droplets evaporation time constant — Time scale for evaporation
`1e-3 s` (default) | positive scalar

Characteristic time scale at which water droplets evaporate to vapor.

Fraction of condensate entrained as water droplets — Fraction of condensate in water droplets
`1` (default) | scalar in the range [0,1]

Fraction of the condensate in the moist air that is entrained as water droplets.

Correlation Coefficients

**a in Nu = aRe^bPr^c for moist air 1** — Correlation coefficient for moist air 1
`0.023` (default) | positive scalar

Proportionality constant in the correlation of the Nusselt number as a function of the Reynolds number and Prandtl number for moist air 1. The default value is based on the Colburn equation.

**b in Nu = aRe^bPr^c for moist air 1** — Reynolds number exponent in correlation for moist air 1
`0.8` (default) | positive scalar

Reynolds number exponent in the correlation of the Nusselt number as a function of the Reynolds number and Prandtl number for moist air 1. The default value is based on the Colburn equation.

**c in Nu = aRe^bPr^c for moist air 1** — Prandtl number exponent in correlation for moist air 1
`0.33` (default) | positive scalar

Prandtl number exponent in the correlation of the Nusselt number as a function of the Reynolds number and Prandtl number for moist air 1. The default value is based on the Colburn equation.

**a in Nu = aRe^bPr^c for moist air 2** — Correlation coefficient for moist air 2
`0.023` (default) | positive scalar

Proportionality constant in the correlation of the Nusselt number as a function of the Reynolds number and Prandtl number for moist air 2. The default value is based on the Colburn equation.

**b in Nu = aRe^bPr^c for moist air 2** — Reynolds number exponent in correlation for moist air 2
`0.8` (default) | positive scalar

Reynolds number exponent in the correlation of the Nusselt number as a function of the Reynolds number and Prandtl number for moist air 2. The default value is based on the Colburn equation.

**c in Nu = aRe^bPr^c for moist air 2** — Prandtl number exponent in correlation for moist air 2
`0.33` (default) | positive scalar

Prandtl number exponent in the correlation of the Nusselt number as a function of the Reynolds number and Prandtl number for moist air 2. The default value is based on the Colburn equation.

References

[1] Ashrae Handbook: Fundamentals. Atlanta: Ashrae, 2013.

[2] Çengel, Yunus A. Heat and Mass Transfer: A Practical Approach. 3rd ed. McGraw-Hill Series in Mechanical Engineering. Boston: McGraw-Hill, 2007.

[3] Mitchell, John W., and James E. Braun. Principles of Heating, Ventilation, and Air Conditioning in Buildings. Hoboken, NJ: Wiley, 2013.

[4] Shah, R. K., and Dušan P. Sekulić. Fundamentals of Heat Exchanger Design. Hoboken, NJ: John Wiley & Sons, 2003.

System-Level Heat Exchanger (MA-MA)

Description

Heat Transfer

Moist Air Heat Transfer Correlation

Condensation

Pressure Loss

Moist Air Mass and Energy Conservation

Assumptions and Limitations

Ports

Output

Q1 — Rate of heat transfer to moist air 1, W physical signal

Q2 — Rate of heat transfer to moist air 2, W physical signal

W1 — Moist air 1 condensation rate, kg/s physical signal

W2 — Moist air 2 condensation rate, kg/s physical signal

Conserving

A1 — Moist air port on side 1 moist air

B1 — Moist air port on side 1 moist air

A2 — Moist air port on side 2 moist air

B2 — Moist air port on side 2 moist air

Parameters

Configuration

Flow arrangement at nominal operating conditions — Flow path alignment Parallel flow - Both fluids flow from A to B (default) | Counter flow - Moist Air 1 flows from A to B, Moist Air 2 flows from B to A | Cross flow - Both fluids flow from A to B

Enable wall thermal mass — Whether to enable effect of thermal mass on heat transfer surface off (default) | on

Wall mass — Mass of heat transfer surface 1 kg (default) | positive scalar

Dependencies

Wall specific heat — Specific heat of heat transfer surface 490 J/(K*kg) (default) | positive scalar

Dependencies

Initialize wall temperature to nominal operating conditions — Option for initializing wall temperature on (default) | off

Dependencies

Initial wall temperature — Initial temperature of wall 293.15 K (default) | positive scalar or two-element vector

Dependencies

Cross-sectional area at port A1 — Flow area at port A1 0.01 m^2 (default) | positive scalar

Cross-sectional area at port B1 — Flow area at port B1 0.01 m^2 (default) | positive scalar

Cross-sectional area at port A2 — Flow area at port A2 0.01 m^2 (default) | positive scalar

Cross-sectional area at port B2 — Area normal to flow at port B2 0.01 m^2 (default) | positive scalar

Moist Air 1

Nominal operating condition — Nominal operating condition Heat transfer from Moist Air 1 to Moist Air 2 (default) | Heat transfer from Moist Air 2 to Moist Air 1

Nominal mass flow rate — Mass flow rate between moist air 1 ports during nominal operating condition 0.1 kg/s (default) | positive scalar

Nominal pressure drop — Pressure drop between moist air 1 ports during nominal operating condition 0.01 MPa (default) | positive scalar

Nominal inlet pressure — Pressure at the moist air 1 inlet 0.101325 MPa (default) | positive scalar

Nominal inlet temperature — Temperature at the moist air 1 inlet 333.15 K (default) | positive scalar

Inlet humidity specification — Quantity used to describe the humidity level at the moist air 1 side inlet Relative humidity (default) | Specific humidity | Mole fraction | Humidity ratio | Wet-bulb temperature

Nominal inlet relative humidity — Relative humidity at the inlet 0.5 (default) | scalar in the range [0,1]

Dependencies

Nominal inlet specific humidity — Specific humidity at the inlet 0.01 (default) | scalar in the range [0,1]

Dependencies

Nominal inlet water vapor mole fraction — Mole fraction of water vapor at the inlet 0.01 (default) | scalar in the range [0,1]

Dependencies

Nominal inlet humidity ratio — Humidity ratio at the inlet 0.01 (default) | positive scalar in the range [0,1]

Dependencies

Nominal inlet wet-bulb temperature — Wet-bulb temperature at the start of simulation 287 K (default) | positive scalar in the range [0,1]

Dependencies

Inlet trace gas specification — Quantity used to describe trace gas level at the inlet Mass fraction (default) | Mole fraction

Nominal inlet trace gas mass fraction — Mass fraction of trace gas at the inlet 0.001 (default) | scalar in the range [0,1]

Dependencies

Nominal inlet trace gas mole fraction — Mole fraction of trace gas at the inlet 0.001 (default) | scalar in the range [0,1]

Dependencies

Heat transfer capacity specification — How to specify heat transfer capacity of moist air 1 Rate of heat transfer (default) | Outlet condition

Dependencies

Nominal rate of heat transfer — Rate of heat transfer 1 kW (default) | positive scalar

Dependencies

Nominal outlet temperature — Outlet temperature 323.15 K (default) | positive scalar

Dependencies

Moist air 1 volume — Total volume of moist air on side 1 of the heat exchanger 0.1 m^3 (default) | positive scalar

Initialize moist air 1 to nominal operating conditions — Option for initializing moist air 1 on (default) | off

Initial moist air 1 pressure — Moist air 1 pressure at start of simulation 0.101325 MPa (default) | positive scalar

Dependencies

Initial moist air 1 temperature — Moist air temperature at start of simulation 293.15 K (default) | positive scalar | two-element vector

Dependencies

Initial humidity specification — Quantity used to describe the initial humidity level Relative humidity (default) | Specific humidity | Mole fraction | Humidity ratio | Wet-bulb temperature

Dependencies

Initial moist air 1 relative humidity — Relative humidity at start of simulation 0.5 (default) | scalar in the range [0,1] | two-element vector

Dependencies

Initial moist air 1 specific humidity — Specific humidity at start of simulation 0.01 (default) | scalar in the range [0,1] | two-element vector

Dependencies

Initial moist air 1 water vapor mole fraction — Mole fraction of water vapor at start of simulation 0.01 (default) | scalar in the range [0,1] | two-element vector

Dependencies

Initial moist air 1 humidity ratio — Humidity ratio at start of simulation 0.01 (default) | positive scalar in the range [0,1] | two-element vector

Dependencies

Initial moist air 1 wet-bulb temperature — Wet-bulb temperature at the start of simulation 287 K (default) | positive scalar in the range [0,1]

Q1 — Rate of heat transfer to moist air 1, W
physical signal

Q2 — Rate of heat transfer to moist air 2, W
physical signal

W1 — Moist air 1 condensation rate, kg/s
physical signal

W2 — Moist air 2 condensation rate, kg/s
physical signal

A1 — Moist air port on side 1
moist air

B1 — Moist air port on side 1
moist air

A2 — Moist air port on side 2
moist air

B2 — Moist air port on side 2
moist air

Flow arrangement at nominal operating conditions — Flow path alignment
`Parallel flow - Both fluids flow from A to B` (default) | `Counter flow - Moist Air 1 flows from A to B, Moist Air 2 flows from B to A` | `Cross flow - Both fluids flow from A to B`

Enable wall thermal mass — Whether to enable effect of thermal mass on heat transfer surface
`off` (default) | `on`

Wall mass — Mass of heat transfer surface
`1 kg` (default) | positive scalar

Wall specific heat — Specific heat of heat transfer surface
`490 J/(K*kg)` (default) | positive scalar

Initialize wall temperature to nominal operating conditions — Option for initializing wall temperature
`on` (default) | `off`

Initial wall temperature — Initial temperature of wall
`293.15 K` (default) | positive scalar or two-element vector

Cross-sectional area at port A1 — Flow area at port A1
`0.01 m^2` (default) | positive scalar

Cross-sectional area at port B1 — Flow area at port B1
`0.01 m^2` (default) | positive scalar

Cross-sectional area at port A2 — Flow area at port A2
`0.01 m^2` (default) | positive scalar

Cross-sectional area at port B2 — Area normal to flow at port B2
`0.01 m^2` (default) | positive scalar

Nominal operating condition — Nominal operating condition
`Heat transfer from Moist Air 1 to Moist Air 2` (default) | `Heat transfer from Moist Air 2 to Moist Air 1`

Nominal mass flow rate — Mass flow rate between moist air 1 ports during nominal operating condition
`0.1 kg/s` (default) | positive scalar

Nominal pressure drop — Pressure drop between moist air 1 ports during nominal operating condition
`0.01 MPa` (default) | positive scalar

Nominal inlet pressure — Pressure at the moist air 1 inlet
`0.101325 MPa` (default) | positive scalar

Nominal inlet temperature — Temperature at the moist air 1 inlet
`333.15 K` (default) | positive scalar

Inlet humidity specification — Quantity used to describe the humidity level at the moist air 1 side inlet
`Relative humidity` (default) | `Specific humidity` | `Mole fraction` | `Humidity ratio` | `Wet-bulb temperature`

Nominal inlet relative humidity — Relative humidity at the inlet
`0.5` (default) | scalar in the range [0,1]

Nominal inlet specific humidity — Specific humidity at the inlet
`0.01` (default) | scalar in the range [0,1]

Nominal inlet water vapor mole fraction — Mole fraction of water vapor at the inlet
`0.01` (default) | scalar in the range [0,1]

Nominal inlet humidity ratio — Humidity ratio at the inlet
`0.01` (default) | positive scalar in the range [0,1]

Nominal inlet wet-bulb temperature — Wet-bulb temperature at the start of simulation
`287 K` (default) | positive scalar in the range [0,1]

Inlet trace gas specification — Quantity used to describe trace gas level at the inlet
`Mass fraction` (default) | `Mole fraction`

Nominal inlet trace gas mass fraction — Mass fraction of trace gas at the inlet
`0.001` (default) | scalar in the range [0,1]

Nominal inlet trace gas mole fraction — Mole fraction of trace gas at the inlet
`0.001` (default) | scalar in the range [0,1]

Heat transfer capacity specification — How to specify heat transfer capacity of moist air 1
`Rate of heat transfer` (default) | `Outlet condition`

Nominal rate of heat transfer — Rate of heat transfer
`1 kW` (default) | positive scalar

Nominal outlet temperature — Outlet temperature
`323.15 K` (default) | positive scalar

Moist air 1 volume — Total volume of moist air on side 1 of the heat exchanger
`0.1 m^3` (default) | positive scalar

Initialize moist air 1 to nominal operating conditions — Option for initializing moist air 1
`on` (default) | `off`

Initial moist air 1 pressure — Moist air 1 pressure at start of simulation
`0.101325 MPa` (default) | positive scalar

Initial moist air 1 temperature — Moist air temperature at start of simulation
`293.15 K` (default) | positive scalar | two-element vector

Initial humidity specification — Quantity used to describe the initial humidity level
`Relative humidity` (default) | `Specific humidity` | `Mole fraction` | `Humidity ratio` | `Wet-bulb temperature`

Initial moist air 1 relative humidity — Relative humidity at start of simulation
`0.5` (default) | scalar in the range [0,1] | two-element vector

Initial moist air 1 specific humidity — Specific humidity at start of simulation
`0.01` (default) | scalar in the range [0,1] | two-element vector

Initial moist air 1 water vapor mole fraction — Mole fraction of water vapor at start of simulation
`0.01` (default) | scalar in the range [0,1] | two-element vector

Initial moist air 1 humidity ratio — Humidity ratio at start of simulation
`0.01` (default) | positive scalar in the range [0,1] | two-element vector

Initial moist air 1 wet-bulb temperature — Wet-bulb temperature at the start of simulation
`287 K` (default) | positive scalar in the range [0,1]

Initial trace gas specification — Quantity used to describe initial trace gas level
`Mass fraction` (default) | `Mole fraction`

Initial moist air 1 trace gas mass fraction — Mass fraction of trace gas at start of simulation
`0.001` (default) | scalar in the range [0,1] | two-element vector

Initial moist air 1 trace gas mole fraction — Mole fraction of trace gas at start of simulation
`0.001` (default) | scalar in the range [0,1] | two-element vector

Initial mass ratio of water droplets to moist air — Ratio of water droplets to moist air
`0` (default) | positive scalar

Relative humidity at saturation — Relative humidity point of condensation
`1` (default) | nonnegative scalar

Water vapor condensation time constant — Time scale for condensation
`1e-3 s` (default) | positive scalar

Water droplets evaporation time constant — Time scale for evaporation
`1e-3 s` (default) | positive scalar

Fraction of condensate entrained as water droplets — Fraction of condensate in water droplets
`1` (default) | scalar in the range [0,1]

Nominal mass flow rate — Mass flow rate between moist air 2 ports during nominal operating condition
`0.1 kg/s` (default) | positive scalar

Nominal pressure drop — Pressure drop between moist air 2 ports during nominal operating condition
`0.001 MPa` (default) | positive scalar

Nominal inlet pressure — Pressure at the moist air 2 side inlet
`0.101325 MPa` (default) | positive scalar

Nominal inlet temperature — Temperature at the moist air 2 side inlet
`293.15 K` (default) | positive scalar

Inlet humidity specification — Quantity used to describe the humidity level at the moist air side inlet
`Relative humidity` (default) | `Specific humidity` | `Mole fraction` | `Humidity ratio` | `Wet-bulb temperature`

Nominal inlet relative humidity — Relative humidity at the inlet
`0.5` (default) | scalar in the range [0,1]

Nominal inlet specific humidity — Specific humidity at the inlet
`0.01` (default) | scalar in the range [0,1]

Nominal inlet water vapor mole fraction — Mole fraction of water vapor at the inlet
`0.01` (default) | scalar in the range [0,1]

Nominal inlet humidity ratio — Humidity ratio at the inlet
`0.01` (default) | positive scalar in the range [0,1]

Nominal inlet wet-bulb temperature — Wet-bulb temperature at the start of simulation
`287 K` (default) | positive scalar in the range [0,1]

Inlet trace gas specification — Quantity used to describe trace gas level at the inlet
`Mass fraction` (default) | `Mole fraction`

Nominal inlet trace gas mass fraction — Mass fraction of trace gas at the inlet
`0.001` (default) | scalar in the range [0,1]

Nominal inlet trace gas mole fraction — Mole fraction of trace gas at the inlet
`0.001` (default) | scalar in the range [0,1]

Moist air 2 volume — Total volume of moist air on side 2 of the heat exchanger
`0.1 m^3` (default) | positive scalar

Initialize moist air 2 to nominal operating conditions — Option for initializing moist air
`on` (default) | `off`

Initial moist air 2 pressure — Moist air pressure at start of simulation
`0.101325 MPa` (default) | positive scalar

Initial moist air 2 temperature — Moist air temperature at start of simulation
`293.15 K` (default) | positive scalar | two-element vector

Initial humidity specification — Quantity used to describe the initial humidity level
`Relative humidity` (default) | `Specific humidity` | `Mole fraction` | `Humidity ratio` | `Wet-bulb temperature`

Initial moist air 2 relative humidity — Relative humidity at start of simulation
`0.5` (default) | scalar in the range [0,1] | two-element vector

Initial moist air 2 specific humidity — Specific humidity at start of simulation
`0.01` (default) | scalar in the range [0,1] | two-element vector

Initial moist air 2 water vapor mole fraction — Mole fraction of water vapor at start of simulation
`0.01` (default) | scalar in the range [0,1] | two-element vector

Initial moist air 2 humidity ratio — Humidity ratio at start of simulation
`0.01` (default) | positive scalar in the range [0,1] | two-element vector

Initial moist air 2 wet-bulb temperature — Wet-bulb temperature at the start of simulation
`287 K` (default) | positive scalar in the range [0,1]

Initial trace gas specification — Quantity used to describe initial trace gas level
`Mass fraction` (default) | `Mole fraction`

Initial moist air 2 trace gas mass fraction — Mass fraction of trace gas at start of simulation
`0.001` (default) | scalar in the range [0,1] | two-element vector

Initial moist air 2 trace gas mole fraction — Mole fraction of trace gas at start of simulation
`0.001` (default) | scalar in the range [0,1] | two-element vector

Initial mass ratio of water droplets to moist air — Ratio of water droplets to moist air
`0` (default) | positive scalar