BoundaryGas Txim flow

Created Thursday 13 June 2013

This model provides a mass flow source emitting a gas composition at a specified temperature. It

1. Purpose of Model

This model can be used to set up constant or variable boundary conditions for a gas medium for example inside the flue gas path. It serves as an idealised flow source which emitts a specified mass flow. It should be used together with BoundaryGas pTxi serving as a second boundary condition giving a specified pressure.

2. Level of Detail, Physical Effects Considered and Physical Insight

2.1 Level of Detail

Referring to Brunnemann et al. [1], this model refers to the level of detail L1 because the system is modeled without the use of balance equations.

2.2 Physical Effects Considered

idealised mass flow at fixed rate and temperature

2.3 Level of Insight

No different levels of detail are available.

3. Limits of Validity

Real sources with complex pressure dependence of mass flow cannot be covered by this model.

4. Interfaces

4.1 Physical Connectors

Basics:Interfaces:GasPortOut gas_a

4.2 Summaries

4.3 Inputs

Real Input value for:
- Mass flow rate being emitted [kg/s].
- Temperature close to the connection port [K].
- Gas composition close to the connection port [kg_x/kg_tot].
Medium properties at the port.

4.2 Medium Models.

Fluid Medium Model at the inlet port

5. Nomenclature

6. Governing Equations

This model simply converts the real input values mass flow, temperature and medium composition into a ClaRa gas stream connector. The pressure inside the connector results from the second (fixed pressure) boundary condition Documentation:Components:BoundaryConditions:GasSink pT and the pressure losses of the gas path.

6.1 System Description and General model approach

6.2 General Model Equations

Since this model is an idealised boundary, no balance equations are used.

7. Remarks for Usage

If operated as an ideal boundary source, the model emits the set up mass flow, no matter what the physical conditions in the adjacent components are. There might be situations (e.g. a closing valve) where this leads to termination of the simulation due to the occurrence of unphysical pressures.

8. Validation

9. References

[1] Johannes Brunnemann and Friedrich Gottelt, Kai Wellner, Ala Renz, André Thüring, Volker Röder, Christoph Hasenbein, Christian Schulze, Gerhard Schmitz, Jörg Eiden: "Status of ClaRaCCS: Modelling and Simulation of Coal-Fired Power Plants with CO2 capture", 9th Modelica Conference, Munich, Germany, 2012

10. Authorship and Copyright Statement for original (initial) Contribution

Author:
DYNCAP/DYNSTART development team, Copyright 2011 - 2022.
Remarks:
This component was developed during DYNCAP/DYNSTART projects.
Acknowledgements:
ClaRa originated from the collaborative research projects DYNCAP and DYNSTART. Both research projects were supported by the German Federal Ministry for Economic Affairs and Energy (FKZ 03ET2009 and FKZ 03ET7060).
CLA:
The author(s) have agreed to ClaRa CLA, version 1.0. See https://claralib.com/pdf/CLA.pdf
By agreeing to ClaRa CLA, version 1.0 the author has granted the ClaRa development team a permanent right to use and modify his initial contribution as well as to publish it or its modified versions under the 3-clause BSD License.

11. Version History

25.06.2013 - v0.1 - initial implementation of the model - André Thüring, TLK-Thermo GmbH
03.04.2019 - added eye connector

Backlinks: ClaRa:A User Guide:Revisions:v1.4.1 ClaRa:Components:BoundaryConditions:BoundaryGas pTxi