E-Filter L2 empirical
Created Wednesday 15 October 2014
Empirical model for an e-filter with dynamic energy and mass balances, taking convective heat transfer and pressure losses into account.
1. Purpose of Model
This model is used for the simulation of an empirical electrostatic dust filter for flue gas cleaning purposes with calculated separation rate.
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 L2.
2.2 Physical Effects Considered
- Conservation of Mass
- Conservation of Energy
- Back flow
- Heat Transport due to convection
- Pressure loss due to friction
2.3 Level of Insight
Heat Transfer
- Basics:ControlVolumes:Fundamentals:HeatTransport:Generic HT:Adiabat L2 : No heat transfer
- Basics:ControlVolumes:Fundamentals:HeatTransport:Generic HT:CharLine L2 : All Geo || HTC || Characteristic Line
- Basics:ControlVolumes:Fundamentals:HeatTransport:Generic HT:Constant L2 : All Geo || HTC || Constant
- Basics:ControlVolumes:Fundamentals:HeatTransport:Generic HT:IdealHeatTransfer L2 : All Geo || Ideal Heat Transfer
Pressure Loss
- Basics:ControlVolumes:Fundamentals:PressureLoss:Generic PL:NoFriction L2: Friction free flow between inlet and outlet
- Basics:ControlVolumes:Fundamentals:PressureLoss:Generic PL:LinearPressureLoss L2 : Linear pressure loss based on nominal values
- Basics:ControlVolumes:Fundamentals:PressureLoss:Generic PL:QuadraticNominalPoint L2 Quadratic pressure loss, density independent
Geometry
- Generic_Geometry : Generic geometry
3. Limits of Validity
- Steady flow.
- Fixed control volume.
- Averaging assumption violated.
- The equations imply that the outlet states equal the states in the balance equations - Not true for large volumes and high gradients.
4. Interfaces
4.1 Physical Connectors
Basics:Interfaces:GasPortIn inlet
Basics:Interfaces:GasPortOut outlet
Basics:Interfaces:HeatPort a heat
5. Governing Equations
5.1 System Description and General model approach
The model is build up from a FlueGasCell and a e filter model. Please have a look into these models for further details
Summary
A summary record is available which bundles important component values.
7. Remarks for Usage
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
Date - Version - Description of changes - author/revisor
25.06.2013 - v0.1 - initial implementation of the model - André Thüring, TLK-Thermo GmbH
03.04.2019 - added eye connector