An Integrated Review of Industrial Dust Monitoring, Removal Mechanisms, Dust Collectors, and System Optimization
Abstract
1. Introduction
2. Research on Industrial Dust Monitoring Technology
2.1. Traditional Sampling Monitoring Methods
2.2. Sensor-Based Online Monitoring Methods
2.3. Intelligent Monitoring Methods
3. Research on Action Mechanisms of Industrial Dust Removal
3.1. Basic Mechanisms of Physical Dust Removal
3.2. Enhancement Mechanisms Based on Interface Modification and Agglomeration
3.3. Dust Physicochemical Reactions Under Special Conditions and Safety Prevention Mechanisms
4. Research Status of Industrial Dust Collectors
4.1. Types and Application Status of Mainstream Dust Collectors
4.2. Research Progress on Performance Optimization of Dust Collectors
4.3. Research on Safety, Energy Conservation and Standardization
5. Research Progress of Industrial Dust Removal Systems
5.1. Overall Design and Layout Planning of Dust Removal Systems
5.2. System Integration, Operation Optimization and Simulation Control
5.3. Safety Protection and Comprehensive Management of Dust Removal Systems
6. Conclusions and Prospects
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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| Type | Principle | Scenarios | Advantages | Limitations |
|---|---|---|---|---|
| Optical sensors [21,22,23,24,25,26,27] | Light scattering | Coal mines, photovoltaic stations, industrial areas | High accuracy, multi-particle detection; non-intrusive and widely used | Susceptible to temperature and humidity interference |
| Ultrasonic sensors [28] | Ultrasonic attenuation | Powder processing industry | Real-time tracking, steady operation, low cost | Narrow range; ineffective for low-concentration dust |
| Electrostatic induction sensors [29,30] | Electrostatic induction | Flammable and explosive dust areas | Good performance for dust explosion early warning | Limited to charged combustible dust |
| Directional monitoring sensors [31] | Adhesive film + image scanning | Mining and industrial sites | Traceable dust migration and source location | Relatively weak efficiency; not for continuous concentration monitoring |
| Technique | Continuity | Anti-interference | Scenarios | Limitations |
|---|---|---|---|---|
| Traditional sampling monitoring [15,16,17,18,19,20] | Intermittent | Good | Mines, tailings ponds, regular safety inspection | Poor real-time performance, heavy manual workload |
| Sensor-based online monitoring [21,22,23,24,25,26,27,28,29,30,31] | Continuous | Moderate | Mining, metallurgy, powder processing | Susceptible to temperature, humidity and dust concentration changes |
| Intelligent monitoring [32,33,34,35,36] | Continuous | Good | Open-pit mines, photovoltaic industry, large industrial parks | Relatively complex system construction |
| Equipment | Mechanism | Treatment Object | Scenarios | Advantages | Limitations |
|---|---|---|---|---|---|
| Wet chord grid dust remover [37] | Inertial & liquid bridge interception | Conventional dust | Normal flue gas | Simple structure, low cost | Relatively weak performance for ultrafine particles |
| Granular layer dust collector [38] | Inertial collision, interception | Common particulate dust | General industrial environments | Steady operation | Easy blockage |
| Cyclone separator [39,40] | Centrifugal separation | Coarse and medium particles | High-flow dry flue gas | Large throughput, no consumables | Fine particles can easily escape |
| ESP [41,42,43,44] | Electrostatic adsorption | Fine particles, oil mist | Normal-/high-temperature flue gas | High removal efficiency | Susceptible to temperature and humidity |
| Technology | Principle | Target | Scenarios | Advantages | Limitations |
|---|---|---|---|---|---|
| Functional filter material [45,46] | Integrated filtration and catalysis | Dust, nitrogen oxides | Industrial flue gas purification | Remove multiple pollutants | Catalyst deactivation risk |
| Eco-friendly dust suppressant [47] | Dust film protection | Mine & road dust | Open dust sources, roadways | Eco-friendly & recyclable | Only for surface dust suppression |
| Surfactant-assisted agglomeration [48,49,50] | Improve dust wettability | Ultrafine & hydrophobic dust | Underground mines | Good agglomeration effect | Strict on concentration control |
| Collector | Mechanism | Particle | Advantages | Limitations | Scenarios |
|---|---|---|---|---|---|
| Filtration [57,63] | Filter interception | Fine particles (PM2.5) | Ultra-high removal efficiency | High flow resistance, easy blockage | Boiler flue gas, wood processing, coal mining |
| Cyclone [64,65,66,67,68] | Centrifugal separation | Coarse & medium particles | Low cost, simple maintenance | Relatively weak performance for ultrafine particles, wall abrasion | Industrial grinding, dry flue gas treatment |
| Electrostatic [69,70] | Electrostatic adsorption | Fine particles | Excellent fine particle capture ability | Affected by temperature and flue gas properties | General industrial flue gas purification |
| Wet [71,72] | Gas–liquid contact & capture | Conventional dust | Adapt to high temperature and high humidity | Large water consumption | Underground coal mines, humid working conditions |
| Composite [73,74,75,76] | Multi-mechanism coupling | Full-size particles | Integrate advantages of multiple technologies | Complex structure and high cost | Complex industrial dust removal scenarios |
| Method | Scenarios | Advantages | Limitations | Refs |
|---|---|---|---|---|
| CFD combined with intelligent algorithms | Structural optimization of cyclone separators and electrostatic cyclone precipitators | Achieve balance between low pressure drop and high separation efficiency | Simplified models lead to relatively weak accuracy for complex multiphase flow | [65,70,93,94,95,96] |
| Experimental test & parametric analysis | Layout optimization of dust collection components and pipelines; operating parameter exploration | Reliable test results for onsite industrial application | Heavy workload, poor adaptability to changing working conditions | [98,100,103] |
| Mesoscale simulation & flow field measurement | Analysis of internal flow, droplet evolution and particle movement characteristics | Clarify internal working mechanism of dust removal equipment | Complex modeling and high requirements for computing performance | [37,104,105,106] |
| Operating parameter optimization | Performance tuning of wet dust collectors, granular bed filters and ventilation systems | Improve efficiency and realize energy-saving control | Only applicable to fixed equipment and operating conditions | [92,107,108,109,110,111] |
| Particle property & carbon emission analysis | Energy conservation, low-carbon operation and fine particle removal | Support full-cycle operation and management | Difficult to evaluate long-term operating performance quantitatively | [91,112,113] |
| Bibliometric analysis & whole-process management | Dust explosion research, combustible dust control and safety regulation | Sort out research hotspots and formulate management strategies | Cannot provide direct guidance for equipment structural improvement | [56,114,115] |
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Huang, B.; Zhang, Y.; Ji, C.; Tan, M. An Integrated Review of Industrial Dust Monitoring, Removal Mechanisms, Dust Collectors, and System Optimization. Appl. Sci. 2026, 16, 6806. https://doi.org/10.3390/app16136806
Huang B, Zhang Y, Ji C, Tan M. An Integrated Review of Industrial Dust Monitoring, Removal Mechanisms, Dust Collectors, and System Optimization. Applied Sciences. 2026; 16(13):6806. https://doi.org/10.3390/app16136806
Chicago/Turabian StyleHuang, Bin, Yichi Zhang, Chunhui Ji, and Mingyang Tan. 2026. "An Integrated Review of Industrial Dust Monitoring, Removal Mechanisms, Dust Collectors, and System Optimization" Applied Sciences 16, no. 13: 6806. https://doi.org/10.3390/app16136806
APA StyleHuang, B., Zhang, Y., Ji, C., & Tan, M. (2026). An Integrated Review of Industrial Dust Monitoring, Removal Mechanisms, Dust Collectors, and System Optimization. Applied Sciences, 16(13), 6806. https://doi.org/10.3390/app16136806

