🔬 COMSOL Multiphysics Projects 2026 — BE / MTech / PhD Final Year Projects · Piezoelectric · MEMS · Thermal · Magnetic · Electrical · Bangalore
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25+ COMSOL Final Year Projects 2026 · BE · MTech · PhD · Simulation · FEA

COMSOL Multiphysics Projects 2026 — simulate every physics, solve every engineering problem.

25+ IEEE-aligned COMSOL Multiphysics projects for BE, MTech and PhD students in Bangalore — covering the five most-demanded coupled-physics domains: Piezoelectricity (energy harvesting, acoustic sensors, ultrasonic transducers), MEMS (comb-drive resonators, capacitive accelerometers, RF switches), Electrical Simulation (motors, transformers, power devices), Battery Cooling & Thermal Management (Li-ion pack heat transfer, PCM cooling, heat sink optimisation) and Magnetic Field Analysis (permanent magnet assemblies, eddy current losses, electromagnetic shielding). Every COMSOL final year project includes a complete .mph simulation file, FEA mesh, parametric sweep results, university-format report (VTU / Anna University / JNTU), PPT presentation and viva support — making them the ideal choice for students searching for comsol project ideas, comsol simulation projects and comsol engineering projects in 2026.

5
COMSOL Physics Domains
Covered in 2026
25+
COMSOL Project Topics
for BE, MTech & PhD
.mph
Complete COMSOL Files
Included Every Project
25+
COMSOL Project Topics
5
Physics Domains
.mph
Full Simulation Files
97%
Viva Success Rate

COMSOL Multiphysics Final Year Projects 2026 — Simulation-Driven Engineering for BE, MTech & PhD Students

COMSOL Multiphysics is the world's leading finite element analysis (FEA) and coupled-physics simulation platform — used by ISRO, DRDO, NTPC, Bosch, STMicroelectronics, IITs and global research universities for solving real-world engineering problems that involve two or more interacting physical phenomena. Unlike single-domain simulators, COMSOL solves tightly coupled PDEs across structural, electromagnetic, thermal, fluid and chemical physics simultaneously — making it uniquely suited to modern multiphysics engineering projects where two or more effects interact: a piezoelectric energy harvester converts mechanical stress to electric current; a MEMS resonator undergoes electrostatic actuation and viscous damping; a battery pack generates Joule heat that must be removed by coolant flow; an electric motor loses energy to both Joule heating and magnetic core losses.

At ProjectsatBangalore, we deliver 25+ COMSOL final year projects across five high-demand physics domains for BE, MTech (Mechanical, EEE, ECE, Civil, Biomedical) and PhD students in Bangalore — giving every student a complete COMSOL Multiphysics simulation experience from geometry building and meshing to physics setup, solver configuration, post-processing and technical documentation. Every COMSOL simulation project includes a complete and ready-to-run .mph project file, parametric sweep plots, FEA mesh quality report, university-format project report in VTU / Anna University / JNTU chapter structure, 15-slide PPT and a viva Q&A preparation guide. Whether you are searching for comsol mini projects, comsol major projects, comsol thesis topics or comsol research topics for a PhD, we have you covered.

All COMSOL Projects For PhD/Mtech research Students

comsol projects for final year COMSOL final year projects COMSOL project ideas COMSOL project topics COMSOL mini projects COMSOL major projects COMSOL projects for students COMSOL thesis topics COMSOL research topics COMSOL simulation projects COMSOL Multiphysics projects COMSOL modeling projects COMSOL multiphysics simulation COMSOL FEA projects COMSOL MEMS projects COMSOL sensor projects COMSOL thermal projects COMSOL heat transfer projects COMSOL fluid flow projects COMSOL structural projects COMSOL electromagnetic projects COMSOL piezoelectric projects COMSOL biomedical projects COMSOL electrical projects COMSOL engineering projects

COMSOL Physics Modules Used in Our Projects

Each COMSOL Multiphysics project uses one or more licensed modules — here are the core modules across our five domains.

PZ
Piezoelectric Devices Module
Couples Structural Mechanics + Electrostatics for direct/converse piezoelectric effect in sensors, energy harvesters and actuators
ME
MEMS Module
Electromechanics, Moving Mesh (ALE), squeeze-film damping for comb drives, accelerometers, RF switches
AC
AC/DC Module
Magnetic Fields, Electric Currents, Electrostatics — motors, transformers, inductors, power devices
HT
Heat Transfer Module
Heat conduction, convection, radiation, conjugate heat transfer, bioheat — battery cooling and electronics thermal management
CF
CFD Module
Laminar and turbulent (k-ε, k-ω) fluid flow, non-isothermal flow — cooling channel and microfluidic simulation
SM
Structural Mechanics Module
Solid mechanics, beam, shell, fatigue — static, dynamic and modal FEA analysis for brackets, beams and pressure vessels
BF
Batteries & Fuel Cells Module
Electrochemical-thermal coupled simulation of Li-ion, solid-state and fuel-cell electrochemical systems
OP
Optimization Module
Topology optimisation, parametric sweep, shape optimisation — for heat sink, MEMS geometry and magnetic circuit design
COMSOL Piezoelectricity Projects
Piezoelectric Devices Module · Structural Mechanics + Electrostatics · Energy Harvesters · Acoustic Sensors · Ultrasonic Transducers

Piezoelectricity is the phenomenon where certain crystalline materials (PZT, PVDF, BaTiO₃) generate an electric charge when subjected to mechanical stress (direct effect) or undergo mechanical deformation when an electric field is applied (converse effect). COMSOL piezoelectric projects use the Piezoelectric Devices Module to couple Structural Mechanics and Electrostatics — modelling resonant frequency, open-circuit voltage, strain distribution, electric field and harvested power as functions of geometry, material and excitation frequency. These are among the most cited comsol project topics in 2026 because of the rapid growth of self-powered IoT sensor nodes, wearable devices and structural health monitoring systems.

#COMSOL Piezoelectric Project TopicCOMSOL Module(s)Level
01Cantilever Beam Piezoelectric Energy Harvester — Resonant Frequency Optimisation and Harvested Power vs. Tip Mass Parametric Study in COMSOL IEEE 2026Piezoelectric Devices, Structural Mechanics, AC/DCBTech / MTech
02PZT-Based MEMS Piezoelectric Pressure Sensor — Sensitivity, Linearity and Frequency Response Simulation in COMSOL Multiphysics IEEE 2026Piezoelectric Devices, MEMS ModuleMTech / PhD
03Broadband Piezoelectric Energy Harvester with Nonlinear Bistable Mechanism — Stochastic Resonance and Voltage Output COMSOL Simulation IEEE 2025Piezoelectric Devices, Structural MechanicsMTech / PhD
04PVDF Film Piezoelectric Acoustic Sensor — Frequency Selectivity, Bandwidth and Sensitivity COMSOL FEA Analysis for Ultrasonic NDT Application IEEE 2025Piezoelectric Devices, Pressure AcousticsBE / BTech
05Wideband Piezoelectric Microgenerator Array for Wearable IoT Power Supply — Coupled Mechanical-Electrical COMSOL Multiphysics Modelling IEEE 2026Piezoelectric Devices, AC/DC, Structural MechanicsMTech / PhD
COMSOL MEMS Projects
MEMS Module · Electromechanics · Moving Mesh · Capacitive Sensors · Comb-Drive Resonators · RF MEMS Switches

Micro-Electro-Mechanical Systems (MEMS) are miniaturised electromechanical devices fabricated using semiconductor manufacturing processes. COMSOL MEMS projects use the MEMS Module with Electromechanics multiphysics coupling to model electrostatic actuation forces, structural deflection, resonant modes, squeeze-film air damping and capacitance change — the core operating principles of MEMS accelerometers, gyroscopes, microphones, pressure sensors and RF switches. These are rapidly growing comsol project topics for final year students at the intersection of ECE (for sensing and communication) and Mechanical Engineering (for structural and dynamic analysis).

#COMSOL MEMS Project TopicCOMSOL Module(s)Level
06Electrostatically Actuated Comb-Drive MEMS Resonator — Pull-In Voltage, Resonant Frequency and Quality Factor COMSOL Simulation IEEE 2026MEMS Module, ElectromechanicsMTech / PhD
07MEMS Capacitive Accelerometer with Differential Comb Sense Structure — Sensitivity vs. Proof Mass Geometry Parametric COMSOL FEA IEEE 2026MEMS Module, Structural MechanicsBE / BTech
08Thermo-Mechanically Actuated MEMS Microvalve for Drug Delivery Microsystem — Flow Rate vs. Voltage COMSOL Multiphysics Modelling IEEE 2025MEMS, Heat Transfer, Laminar FlowMTech
09RF MEMS Switch Design — Actuation Voltage, Isolation and Insertion Loss Frequency Response COMSOL Electromagnetic Simulation IEEE 2025MEMS, AC/DC, RF ModuleMTech / PhD
10MEMS Gyroscope — Coriolis Force Coupling Between Drive and Sense Modes and Mode-Matching Optimisation in COMSOL IEEE 2026MEMS Module, Structural MechanicsMTech / PhD
COMSOL Electrical Simulation Projects
AC/DC Module · Electric Currents · Magnetic Fields · PMSM / Induction Motor · Transformer · Power MOSFET · Electric Field Distribution

COMSOL electrical projects use the AC/DC Module (Magnetic Fields and Electric Currents physics interfaces) to model electromagnetic phenomena in electrical machines, transformers, inductors and power semiconductor devices. These comsol engineering projects are particularly relevant for EEE and ECE students whose final year project domains include electric motors (PMSM, induction, BLDC), power transformers, high-voltage insulation design and wireless power transfer — all areas where coupled electromagnetic-thermal COMSOL simulation provides insights unavailable from analytical methods alone.

#COMSOL Electrical Project TopicCOMSOL Module(s)Level
11Permanent Magnet Synchronous Motor (PMSM) Multi-Physics COMSOL Simulation — Magnetic Flux Density, Torque Ripple, Iron Loss and Thermal Map IEEE 2026AC/DC (Magnetic Fields), Heat TransferMTech / PhD
12Single-Phase Distribution Transformer Core Loss and Leakage Flux COMSOL FEA — No-Load and Short-Circuit Test Simulation IEEE 2025AC/DC Module (Magnetic Fields)BE / BTech
13Power MOSFET Coupled Electrothermal COMSOL Simulation — Junction Temperature, Current Crowding and Safe Operating Area (SOA) Analysis IEEE 2026Semiconductor Module, Heat TransferMTech / PhD
14Wireless Power Transfer (WPT) Coil Optimisation for Electric Vehicle Charging — Coupling Coefficient and Power Transfer Efficiency vs. Coil Gap COMSOL IEEE 2026AC/DC Module (Magnetic Fields)MTech
15Electric Field Distribution and Partial Discharge Inception Voltage in High-Voltage Cable Insulation — COMSOL Electrostatics Simulation IEEE 2025AC/DC Module (Electrostatics)BE / MTech
Battery Cooling & Thermal Management — COMSOL Thermal Projects
Heat Transfer Module · Batteries & Fuel Cells Module · CFD (Conjugate Heat Transfer) · Li-ion Pack Cooling · PCM Thermal Energy Storage

COMSOL thermal projects for battery cooling and thermal management have become one of the highest-demand comsol project ideas for final year students in 2026, driven by the explosive growth of electric vehicles and grid energy storage. Battery thermal management system (BTMS) design is a multi-physics challenge: electrochemical heat generation (Joule heating + entropic heat) must be balanced against conductive, convective and radiative heat removal. COMSOL heat transfer projects in this domain use the Heat Transfer Module coupled with Batteries and Fuel Cells Module (for electrochemical heat source) and CFD Module (for coolant flow) to produce temperature maps, hot spot identification and safety margin analysis at cell, module and pack level.

#COMSOL Battery Cooling / Thermal Project TopicCOMSOL Module(s)Level
16Lithium-Ion Battery Pack Thermal Management — Conjugate Heat Transfer Cooling Channel CFD Simulation in COMSOL for EV Application IEEE 2026Heat Transfer, CFD, Batteries & Fuel CellsMTech / PhD
17Phase Change Material (PCM) Based Passive Battery Thermal Management COMSOL Simulation — Latent Heat Absorption and Cell Temperature Uniformity IEEE 2026Heat Transfer (Phase Change), CFDMTech
18Electronics Cooling Heat Sink Topology Optimisation COMSOL Simulation — Minimum Thermal Resistance Subject to Pressure Drop Constraint IEEE 2025Heat Transfer, CFD, OptimizationBE / MTech
19Tab-Cooled Cylindrical Lithium-Ion Cell COMSOL Thermal Simulation — 1C, 2C and 3C Discharge Rate Temperature Rise Comparison IEEE 2025Batteries & Fuel Cells, Heat TransferBE / BTech
20Solid-State Battery Electrochemical-Thermal COMSOL Multiphysics Modelling — Li-Metal Anode Dendrite Heat Hotspot Risk Analysis IEEE 2026Batteries & Fuel Cells, Heat TransferPhD
Magnetic Field Analysis — COMSOL Electromagnetic Projects
AC/DC Module (Magnetic Fields) · Eddy Current Loss · Permanent Magnet Assembly · EM Shielding · Induction Heating

COMSOL electromagnetic projects for magnetic field analysis encompass a wide range of comsol major project topics — from mapping the magnetic flux density in permanent magnet assemblies and analysing eddy current losses in silicon steel laminations to designing electromagnetic shielding enclosures and modelling induction heating coils. The AC/DC Module's Magnetic Fields physics interface (for time-harmonic and transient magnetic analysis) and its coupling to the Heat Transfer Module make COMSOL uniquely powerful for these comsol engineering projects. Students from EEE, ECE, Instrumentation and Mechanical Engineering branches all find compelling magnetic field project topics here.

#COMSOL Magnetic Field / Electromagnetic Project TopicCOMSOL Module(s)Level
21Permanent Magnet Halbach Array Magnetic Flux Density Mapping and Force on Soft Iron Target COMSOL Simulation — Magnetic Circuit Optimisation IEEE 2026AC/DC Module (Magnetic Fields)BE / MTech
22Eddy Current Loss Analysis in Silicon Steel Transformer Core Laminations at 50 Hz and 5 kHz — COMSOL FEA vs. Classical Formula Comparison IEEE 2025AC/DC (Magnetic Fields), Heat TransferBTech / MTech
23Electromagnetic Shielding Effectiveness of Conductive Enclosures at GHz Frequencies — COMSOL Multiphysics vs. FEM Analytical Benchmark IEEE 2026AC/DC Module, RF ModuleMTech / PhD
24Induction Heating Coil Design for Surface Hardening — Joule Heating vs. Frequency and Coil Geometry COMSOL Multiphysics Parametric Sweep IEEE 2025AC/DC (Magnetic Fields), Heat TransferBE / BTech
25Magnetic Resonance Imaging (MRI) Gradient Coil Lorentz Force Vibration and Acoustic Noise COMSOL Structural-Electromagnetic Coupled Analysis IEEE 2026AC/DC, Structural Mechanics, Pressure AcousticsMTech / PhD

What Every COMSOL Final Year Project Includes

A complete simulation-to-documentation package designed for BE and MTech students to present confidently in their review and viva.

Complete COMSOL .mph File

A fully annotated and ready-to-run COMSOL Multiphysics project file (.mph) with geometry, material properties, physics setup, mesh and solver configuration — all parameters labelled so you can change values and observe their effect live.

Ready to Run

Parametric Sweep Results & Plots

Exported high-resolution simulation result plots — displacement fields, stress contours, temperature maps, electric and magnetic field distributions, flow velocity profiles — plus parametric sweep graphs showing performance vs. key design variable.

Publication Ready

University-Format Report

Full project report in VTU, Anna University or JNTU chapter format — abstract, introduction, governing equations, literature survey, geometry and boundary conditions, mesh convergence study, results, discussion and conclusion — ready to submit as your final year project report.

VTU / Anna / JNTU

IEEE Base Paper Reference

Every COMSOL project is aligned to a specific IEEE Transactions or IEEE Sensors Journal paper from 2024–2026, ensuring your project matches current research trends and giving you an authoritative citation for your report introduction and literature survey.

IEEE Aligned

PPT + Viva Q&A Guide

15-slide IEEE-styled PowerPoint covering project motivation, COMSOL geometry, physics setup, results and conclusion — plus a 35-question viva preparation guide covering COMSOL Multiphysics fundamentals, governing equations, mesh independence, boundary conditions and result validation.

Viva Ready

PhD / Journal Extension Available

For MTech scholars targeting PhD admission or IEEE journal publication, we extend any COMSOL project with a novel design proposal, additional physics coupling or optimisation study, and prepare a draft IEEE journal manuscript for submission to IEEE Transactions on Industrial Electronics, IEEE Sensors Journal or equivalent.

PhD Extension

Standard COMSOL Multiphysics Simulation Workflow

The 6-step process followed in every COMSOL simulation project — from geometry to publication-ready results.

1

Geometry Design

The device or system geometry is built in COMSOL's built-in CAD environment or imported from a STEP/IGES file (SolidWorks, AutoCAD). Geometry parameters are defined as global variables so the same model can be swept over different dimensions in the parametric study.

COMSOL Geometry Editor / CAD Import
2

Material Assignment

Material properties (PZT-5A piezoelectric constants, silicon elastic constants, NdFeB remanence, lithium-ion electrolyte conductivity, copper thermal conductivity) are assigned from the COMSOL material library or entered as user-defined expressions — temperature-dependent properties are defined as function tables for coupled thermal analyses.

COMSOL Material Library
3

Physics Setup & Boundary Conditions

The relevant physics modules are added and configured with the governing PDEs — structural loads, electrostatic potentials, heat flux boundary conditions, flow inlets and outlets, magnetic field excitation — along with multiphysics coupling nodes (e.g., Electromechanics coupling for MEMS, Electromagnetic Heat Source for motor loss, Piezoelectric Effect for energy harvesters).

Physics Interfaces + Multiphysics Coupling
4

Mesh Generation & Convergence Study

An appropriate finite element mesh is generated — mapped, swept or free tetrahedral — with mesh refinement at critical regions (crack tips, electrode edges, channel walls). A mesh convergence study verifies that result quantities change less than 1% between successive mesh refinements, validating the spatial discretisation.

COMSOL Mesh + Convergence Study
5

Solver Configuration & Parametric Sweep

The appropriate solver — stationary, time-dependent, frequency-domain or eigenfrequency — is configured and run. A parametric sweep is set up over one or more design variables (geometry dimension, excitation frequency, discharge C-rate, applied voltage) to generate the performance curves that form the core results of the project.

COMSOL Parametric Sweep / Solver
6

Post-Processing & Export

Results are visualised and exported — surface plots of stress/temperature/magnetic flux density, line graphs of resonant frequency vs. geometry, arrow plots of velocity or electric field, 3D volume plots — all exported at high resolution (300 dpi PNG and PDF) in the postprocessing dataset, ready for report figures and PPT slides.

COMSOL Post-Processing & Export

Get Your COMSOL Final Year Project Started Today

Tell us your branch and domain preference — Piezoelectricity, MEMS, Electrical, Battery Cooling or Magnetic — and we'll send you 3 customised COMSOL project ideas with simulation scope and IEEE base paper reference within 24 hours. Free consultation by WhatsApp or call.

Frequently Asked Questions — COMSOL Multiphysics Projects

Common questions students ask about comsol projects for final year, comsol simulation projects and comsol thesis topics.

What are the best COMSOL Multiphysics project ideas for final year BE and MTech students in 2026?
Best COMSOL final year project ideas for 2026 span five coupled-physics domains. For BE students: single-phase transformer core loss COMSOL FEA, cantilever piezoelectric energy harvester, MEMS capacitive accelerometer, electronics heat sink conjugate heat transfer optimisation and permanent magnet flux density mapping. For MTech students: PMSM multiphysics coupled motor simulation, piezoelectric MEMS pressure sensor, comb-drive MEMS resonator with pull-in voltage analysis, lithium-ion battery pack thermal management with PCM cooling, and electromagnetic shielding effectiveness simulation. For PhD scholars: broadband nonlinear piezoelectric energy harvester, MEMS gyroscope mode-matching, solid-state battery dendrite thermal risk analysis, induction heating topology optimisation and MRI gradient coil vibro-acoustic coupled COMSOL analysis. All projects include complete .mph COMSOL Multiphysics simulation files, IEEE base paper, report, PPT and viva support.
What COMSOL physics modules are used in these simulation projects?
COMSOL piezoelectric projects use the Piezoelectric Devices Module (Structural Mechanics + Electrostatics coupling). COMSOL MEMS projects use the MEMS Module with Electromechanics and Moving Mesh (ALE). COMSOL electrical projects use the AC/DC Module (Magnetic Fields, Electric Currents, Electrostatics). COMSOL thermal projects for battery cooling use the Heat Transfer Module coupled with CFD Module (Conjugate Heat Transfer) and Batteries and Fuel Cells Module. COMSOL electromagnetic projects for magnetic field analysis use the AC/DC Module (Magnetic Fields) often coupled with Heat Transfer for eddy-current thermal analysis. The Optimization Module is used across all domains for topology optimisation and parametric design studies.
What deliverables are included with every COMSOL final year project?
Every COMSOL final year project includes: complete .mph COMSOL Multiphysics simulation file with annotated geometry, physics, boundary conditions and mesh; parametric sweep and mesh convergence study results exported as high-resolution PNG/PDF plots; IEEE 2025-2026 base paper reference with DOI; university-format project report in VTU, Anna University or JNTU chapter structure (abstract, introduction, governing equations, literature survey, methodology, simulation results, conclusion, references); 15-slide PPT in IEEE template; 35-question viva Q&A guide covering COMSOL fundamentals, governing PDEs, boundary condition rationale and result validation; and live online walkthrough of the simulation via screen share so you can understand and explain the project confidently.
What is the difference between COMSOL MEMS projects and COMSOL piezoelectric projects?
COMSOL MEMS projects focus on micro-scale electromechanical systems — electrostatically actuated resonators, capacitive sensors, microvalves and RF switches — coupling Structural Mechanics with Electrostatics (Electromechanics) and fluid squeeze-film effects using the MEMS Module. COMSOL piezoelectric projects specifically model the direct piezoelectric effect (mechanical stress → electric charge, for energy harvesters and sensors) or the converse piezoelectric effect (applied voltage → strain, for actuators and ultrasonic transducers) using the Piezoelectric Devices physics interface, coupling Structural Mechanics and Electrostatics. Many advanced projects combine both — a piezoelectric MEMS energy harvester or a PZT-based MEMS pressure sensor uses both the MEMS Module and Piezoelectric Devices Module together.
Can COMSOL Multiphysics be used for battery cooling and thermal management final year projects?
Yes — COMSOL battery cooling thermal management projects are among the most in-demand comsol project topics for final year in 2026 due to the global EV and energy storage boom. A typical COMSOL battery thermal project models a cylindrical or prismatic lithium-ion cell using the Heat Transfer Module coupled with the Batteries and Fuel Cells Module (for electrochemical heat generation — Joule heating + entropic heat) and CFD Module (for coolant flow in liquid cold-plate channels). The simulation produces temperature distribution contours across the battery pack, identifies hot spots above 40°C and compares different cooling strategies — liquid cold plates, forced air, PCM (phase change material) and tab cooling — to minimise peak temperature rise and temperature non-uniformity, which directly impacts battery cycle life and thermal runaway safety margin.
What COMSOL thesis topics and research topics are available for MTech and PhD students?
High-impact COMSOL thesis topics for MTech and PhD include: topology-optimised broadband piezoelectric energy harvester with frequency up-conversion for wearable IoT power supply; MEMS gyroscope drive-sense mode-matching optimisation under vacuum COMSOL analysis; solid-state battery multi-physics simulation with lithium dendrite thermal risk analysis; PMSM motor multi-physics coupled iron-loss thermal analysis for EV propulsion; wireless power transfer coil optimisation for EV charging with ferrite shielding; microfluidic lab-on-chip COMSOL biomedical projects with electroosmotic flow, dielectrophoresis and DNA stretching; and topology-optimised lightweight aerospace bracket COMSOL structural FEA project using SIMP method. All thesis topics can be extended to IEEE/Scopus journal paper writing with COMSOL simulation as the core computational result.