Moisture Transfer Data

The Moisture transfer component provides data for either HAMT or EMPD or both. It can be selected from the Materials dialog from under the Moisture Transfer header at the bottom of the General tab.

 

DesignBuilder is provided with a database of moisture transfer properties for a small range of representative materials. The database includes properties for both HAMT and EMPD calculation methods. The HAMT database is derived from IEA Annex 24 c.1996.

 

For details on the HAMT algorithms used within EnergyPlus see the Combined Heat and Moisture Transfer (HAMT) Model section in the Engineering Reference.

General

Name

Enter a unique name for this set of moisture transfer data.

Category

The <All> category is presently the only option.

Moisture transfer simulation method

You can choose to enter data for EMPD and/or HAMT. Select from:

 

 

When either of the 1-EMPD or 3-EMPD and HAMT options are selected the EMPD tab will be shown. If either of the 2-HAMT or 3-EMPD and HAMT options are selected the following tabs will be shown:

 

EMPD

The Effective Moisture Penetration Depth (EMPD) moisture model will be used when the appropriate EMPD moisture materials are specified and the Moisture transfer simulation method is one the EMPD options. When the EMPD option is being used, data on this tab is used to describe the five moisture material properties that are used in the 5-Moisture Penetration Depth Conduction Transfer Function solution algorithm. The EMPD algorithm is a simplified, lumped moisture model that simulates moisture storage and release from interior surfaces. The model uses “actual” convective mass transfer coefficients that are determined by existing heat and mass transfer relationships, e.g. the Lewis relation. An effective moisture penetration depth may be determined from either experimental or detailed simulation data by using actual surface areas and moisture sorption isotherms.

Effective moisture depth

This field is used to enter the effective moisture penetration depth of the material layer. Units for this parameter are m or ft.

Constants to define moisture equilibrium equation

The next four fields, coefficients “a”, “b”, “c”, and “d”, help define the sorption isotherm curve used for building materials under equilibrium conditions. They are used to define the relationship between the material’s moisture content and the surface air relative humidity (ref: Effective Moisture Penetration Depth (EMPD) Model in the Engineering Reference):

 

U = aφb + cφd

 

where:

a,b,c,d = Coefficients to define the relationship between the material’s moisture content and the surface air relative humidity

U = Moisture content defined as the mass fraction of water contained in a material (kg/kg or lb/lb)

φ = Surface air relative humidity [0 to 1].

The next four fields are dimensionless coefficients:

Moisture Equation Coefficient a

Moisture Equation Coefficient b

Moisture Equation Coefficient c

Moisture Equation Coefficient d

HAMT Settings

Porosity

The porosity of a material is the maximum fraction, by volume, of a material that can be taken up with water. The units are m3/m3 or ft3/ft3.

Water content

Enter the initial water content ratio (in kg/kg or lb/lb). For the HAMT solution algorithm the initial water content is assumed to be distributed evenly through the depth of the material.

Sorption Isotherm

The Sorption Isotherm data relates the moisture, or water content of a material with the relative humidity (RH). The water content is expected to increase as relative humidity increases, starting at zero content at 0.0 RH fraction and reaching a maximum, defined by the porosity, at 1.0 RH fraction, which corresponds to 100% relative humidity. Relative humidities are entered as fraction ranging from 0.0 to 1.0. These two extremes (0.0 and 1.0) are automatically set by the HAMT solution. However, if they are entered they will be used as extra data points. Data should be provided with increasing RH and moisture content up to as high an RH as possible to provide a stable solution.

 

One possible reason for the following error message may be that a material has a very rapid increase in water content for a small change in RH, which can happen if the last entered water content point is at a low RH and the material has a very high porosity.

 

** Warning ** HeatAndMoistureTransfer: Large Latent Heat for Surface ROOF

Number of data coordinates

A maximum of 25 coordinates can be specified.

Data Coordinate n

Relative humidity fraction x

The relative humidity of the nth coordinate. The relative humidity is entered as fraction, not in percent.

Moisture content

The Moisture content of the nth coordinate. The units are kg/m3 or lb/ft3

Suction

The suction data relates the liquid transport coefficient, under suction, to the water content of a material. A data point at zero water content is required. The liquid transport coefficient at the highest entered water content value is used for all liquid transport coefficient values above this water content. These coefficients are used by HAMT when the rain flag is set in the weather file.

Number of Suction points

A maximum of 25 points can be specified.

Suction Pair n

Moisture content n

The moisture content of the xth point. The units are kg/m3 or lb/ft3.

Liquid transport coefficient n

The Liquid Transport Coefficient of the xth point. The units are m2/s or ft2/s.

Redistribution

The redistribution data relates the liquid transport coefficient to the water content of a material under normal conditions. A data point at zero water content is required. The liquid transport coefficient at the highest entered water content value is used for all liquid transport coefficient values above this water content. These coefficients are used by the Heat and Moisture Transfer algorithm when the rain flag is NOT set in the weather file.

Number of Redistribution Points

A maximum of 25 points can be specified.

Redistribution Point n

Moisture content

The moisture content of the nth point. The units are kg/m3 or lb/ft3.

Liquid transport coefficient

The Liquid transport coefficient of the nth point. The units are m2/s or ft2/s.

Diffusion

The MU data relates the vapor diffusion resistance factor (dimensionless) to the relative humidity as fraction (RH). A data point at zero RH is required. The vapor diffusion resistance factor at the highest entered relative humidity (RH) value is used for all vapor diffusion resistance factor values above this RH. The relative humidity maximum value in fraction is 1.0.

Number of data pairs

A maximum of 25 pairs can be specified.

Data Pair n

Relative humidity fraction

The moisture content of the nth pair. The relative humidity is entered as fraction, not in percent.

Vapor diffusion resistance factor

The Liquid transport coefficient of the nth pair.

Thermal Conductivity

The thermal data relates the thermal conductivity of a material to the moisture or water content. A data point at zero water content is required. The thermal conductivity at the highest entered water content value is used for all thermal conductivity values above this water content.

Number of thermal coordinates

A maximum of 25 coordinates can be specified.

Thermal Coordinate n

Moisture content

The moisture content of the nth coordinate. The units are kg/m3 or lb/ft3.

Thermal conductivity

The Thermal conductivity of the nth coordinate. The units are W/m-K or Btu-in/h-ft-°F.