Design and Optimum of Dust Collector with Corrugated Plate for Underground Mine

A set of dust collectors was designed with corrugated plate for an underground metal mine, which has low ventilation resistance, simple maintenance, and strong environmental adaptability. A three-dimensional simulation model was built based on ANSYSFluent software, and it was used to analyze the influence law of key parameters on the comprehensive dust removal efficiency; the angle of corrugated plate to the horizontal plane, the surface characteristics of plate, pressure loss and dust removal efficiency were discussed.*e optimal design scheme of the dust collector was determined according to the simulation results.*e dust collection was carried out in the Fankou lead-zinc underground metal mine in China, and the total dust removal efficiency was more than 95%, and for respiratory dust, it was more than 85%. *is dust collector can be widely used in similar underground metal mines.


Introduction
e mining scale, mining intensity, and mining depth have increased rapidly during recent decades for metal mines in China, especially for old mines with expansion construction and reconstruction to improve its mining capacity. Consequently, it makes the ventilation network complex and the structure irrational, ventilation circuit long, ventilation resistance big, and daily management much difficult, and it brings serious contradiction between air supply and demand. At present, the existing well and roadways are used as the inlet shaft or airway, which is one of the important ways to effectively solve the poor ventilation problem for underground mines. Some metal mines allow fresh air inlet from the main shaft to partially replenish the demand of air under certain conditions. Due to the small ventilation resistance and large cross section, the volume of airflow is large, and the fresh air is polluted by dust in the skip shaft during the real application. According to the provisions from Safety Regulations of Metal and Nonmetal Mines ( GB16423-2006), " e skip shaft should not double as intake shaft. When mixture shaft is used as the intake shaft, it should take effective purification measures to ensure the quality of the air source." So these metal mines face the problem of purifying airflow which is from the main shaft or skip shaft.
Dust collectors have been widely used because of technology ripening, safety working, and economy reasonable nowadays. ere are many kinds of dedusting technologies and dust collectors [1], most of which focus on wet dedusting and filter removal technologies, especially on spraying dedusting [2][3][4] and filter-bag dedusting. Although current dedusting and dust collectors are relatively mature technology, it is not easy to apply them well into underground mines, which needs to meet the conditions of confined space, easy maintenance, efficiency, and the large volume of airflow economically [5]. It is of great practical significance and application value to investigate the purification technology and dedusting device for underground metal mine.

Design of Dust Collector
In order to meet the requirements for the purification of air in underground metal mine (e.g., low ventilation resistance, high capacity to deal with airflow, and relatively low content of respiration dust), the dedusting types of shutter, spray, and water film need to be combined in the design of the dust collector.
e corrugated plate was selected as the main material, and the idea of modular design was adopted to build the dust collector. One or more sets of independent dust removal module were used to constitute the dust collector, and these modules can be used in series, parallel, and series-parallel modes.

Preliminary Design.
Each dedusting module consists of a metal support and corrugated plate. e corrugated plate is xed on the metal support and has an angle to the horizontal plane and formed like a shutter-type dust collector [6]. When the dusty air ow passes through the corrugated plate, the air ow disturbance caused by the wave-shaped structure of the corrugated plate would enhance the inertia e ect and increase the collision probability between the dust and the surface of the corrugated plate [7]. e dust removal mechanism of the corrugated plate includes gravity sedimentation, inertia separation, surface adhesion [8,9], and so on.

Simulation and Analysis.
e technology of numerical simulation is widely used to assist experimental research and provides more and faster simulation data [10,11]. A numerical model was built to optimize the parameters of the dedusting module.
e dedusting e ciency, installation angle, ventilation resistance, pressure loss, and ow-eld distribution were simulated and discussed. e numerical model used in this study is implemented by solving the di erential equations of conservation of mass, momentum, and energy and is complemented by turbulent ow models. Calculations are performed with the commercial software package ANSYS-Fluent. e discrete phase model (DPM) is used to simulate the results of dust [12]. e trajectory of a discrete phase particle is simulated by integrating the force balance on the particle in a Lagrangian reference frame. is force balance equates the particle inertia with the forces acting on the particle [13] and can be written (for the x direction in Cartesian coordinates) as follows: where F → is an additional acceleration (force/unit particle mass) term, is the drag force per unit particle mass, u → is the uid phase velocity, u → p is the particle velocity, μ is the molecular viscosity of the uid, ρ is the uid density, ρ p is the density of the particle, d p is the particle diameter, and Re is the relative Reynolds number. e simulation geometry is shown in Figure 1(a). e computational domain was 1.1 m × 0.5 m × 0.13 m and included ve corrugated plates. ree planes (inlet, outlet, and middle) were selected to calculate the simulation results. e three angles (0°, 5°, and 10°) between the horizontal plane to the corrugated plate and the surface of the corrugated plate were set as three types, i.e., "two sides" means that the boundary condition is "trap" for both surfaces of the corrugated plate, "one side" represents that upper surface of the corrugated plate was set as "trap," and "no side" refers to that no surface was set as "trap." Typical simulation results and graphs are shown in Figures 1(b)-1(d).
ree planes were selected to evaluate the dust removal e ciency, as shown in Figure 1(a). e data were averaged value of three planes (inlet, outlet, and middle) according to the simulation results, which are shown in Figures 2 and 3.      Figures 3(a)-3(c) show that the dust removal e ciency is dependent on the plate area and the characteristics of the plate surface, and the dedusting e ciencies were as follows: two sides > one side > no side. e collection e ciency is 76.38% for two sides, 26.97% for one side, and 11.83% for no side at angle 0°; 75.55% for two sides, 34.05% for one side, and 12.79% for no side at angle 5°; 80.75% for two sides, 37.39% for one side, and 4.6% for no side at angle 10°. Figures 3(d)-3(f ) present that the dust removal eciency is a ected by the angle, but its e ect is not so signi cant, and it depends on the surface area of plate, which is associated with the "trap" type boundary condition [14].
In order to improve the dust capture capability for the surface of the corrugated plate and to increase the comprehensive e ciency of dust removal, the water supply pipe was installed on one or both sides of each dedusting module, with water sprinkled into its inside through injection hole.
Some leakage holes were arranged on each corrugated plate, and water curtain was formed between the plates through these leakage holes. Water curtain became the water mist when it was apped and impacted by air ow, and water lm was formed on the surface of the corrugated plate. e inertial e ect, wet dedusting, and water lm collecting constituted the dust collector. Because of the spoiler e ect of the corrugated plate and spray dust removal system, the dust removal rate is high for respiratory dust. e dust was taken away by sprinkle water, which prevented dust aggregation on the surface and washed the dust.

Field Application and E ect Evaluation.
e dust collector has been applied in a large nonferrous metal mine to purify air ow from the main shaft, and the device was installed in a roadway with a size of 25.0 m × 4.5 m × 4.0 m. e dust collector consists of three independent dedusting modules, and the basic structure is shown in Figure 4.
Field application results: the dust concentration is 5-10 mg/m 3 for the inlet air ow from the main shaft and 0.5-1.5 mg/m 3 for the outlet air ow from this dust collector;     Figure 5. e adoption of the modular design in this dust collector provides the capability to change the parameter according to field requirements. Field application proved that the dust collector meets the design requirements and can be used into the underground metal mine for the purification of the inlet air from the main shaft or skip shaft.
Based on the ventilation cost of this applied mine, the main economic indicator is that the operation cost of ventilation is about RMB30,000 per year for 1 m 3 fresh air from auxiliary shaft. According to these data, the throughput volume of this dust collector is 20 m 3 ; therefore, the annual economic benefit of RMB450,000 can be achieved.

Conclusions
is study was conducted to design a new dust collector to purify airflow for the main shaft in an underground metal mine. e corrugated plate was selected as the main material; ANSYS-Fluent software was used to optimize the parameter of the dust collector. e modular design was used in the dust collector, which provides the capability to change module composition according to field requirements. e dust collector integrates wet dedusting, condensation, collision, inertia, gravity, and other dedusting methods.
is device was applied in an underground metal mine, which has low ventilation resistance, simple maintenance, and strong environmental adaptability. Field application proved that the dust collector meets the design requirements and can be used into the underground metal mine for the purification of the inlet air from the main shaft or skip shaft.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that they have no conflicts of interest.