Engineering, Technology & Applied Science Research Vol. 8, No. 2, 2018, 2799-2804 2799  
 

www.etasr.com Carosso et al.: A New Modular Control Board for Pulse-Jet Cleaning of Dust Collector Filter Bags 
 

A New Modular Control Board for Pulse-Jet Cleaning 
of Dust Collector Filter Bags 

 

Lorenzo Carosso 
Department of Electronics 

and Telecommunications, 
Politecnico di Torino, Italy 

lorenzo.carosso@polito.it 

Daniel Gaiki 
Department of Electronics 

and Telecommunications, 
Politecnico di Torino, Italy 

daniel.gki@gmail.com 

Silvano Bertoldo 
Department of Electronics 

and Telecommunications, 
Politecnico di Torino, Italy 

silvano.bertoldo@polito.it 

Marco Allegretti 
Department of Electronics 

and Telecommunications, 
Politecnico di Torino, Italy 

marco.allegretti@polito.it 
 

 
Abstract–This work presents a timing system modular control 
board to be used for pulse-jet cleaning of dust collector filter bags 
or pneumatic conveying systems. Many systems of this kind are 
already available on the market but only some of them have the 
ability to operate in full range alternating current power supplies. 
The presented versatile and innovative control board can control 
the electro valves, either the ones operating with alternating 
current and those in direct current (since they are both used in 
the industrial plants). For the same reason, the designed 
prototype system can be powered with different voltages, 
widening the number of potential industrial applications. The 
electronic board has as main advantage the ability to fully 
automate the cleaning cycle. It can drive many electro valves 
simultaneously since it is possible to connect more control boards 
together if needed. It also allows the user to separate the control 
section of the system from the section dedicated to the actuation 
of the electro valves. The electro valves can be controlled from a 
PC terminal via ethernet. The work describes the adopted 
solutions and the steps made for the design of the entire 
prototypal modular board, with particular focus on the 
innovative timing system. 

Keywords-pulse jet baghouse; pulse jet electro valve; pulse jet 
cleaning; electro valve actuator; remote monitoring bag house; AC 
electro valves control; DC electro valves control; prototypal timing 
system 

I. INTRODUCTION 
Surface filter systems are heavily applied in air filtration 

processes for industrial applications and the use of a bag (filter 
media) cleaning subsystem by using compressed air jets is 
widespread as well. The pulse-jet type of dust filter was 
invented and developed and introduced on the market in the 
late 1950´s [1]. The basic device patent has expired and there 
are now many manufacturers of pulse-jet collector type [2]. 
Core business of industries using Pulse-Jet Fabric Filtration 
(PJFF) regard power generation, incineration, chemical, steel, 
cement, food, pharmaceuticals, metal working, aggregates and 
carbon black [3]. The research group of remote sensing and 
innovative sensors development of The Department of 
Electronics and Telecommunications (DET) of Politecnico di 
Torino, has a great interest in designing new prototypes and 
new solutions for both academic research purposes and 
industrial innovative applications. Adopted solutions were 

always realized considering keeping the cost as low as possible 
for industrial applications. They cover a large range of 
applications highlighting the multidisciplinary attitude and 
interests of the research group. During the year some 
environmental monitoring sensors have been developed such as 
a microwave radar for rain monitoring [4], sensors and 
techniques for forest fire monitoring [5, 6] etc. Starting from 
the first multipurpose board realized in 2012 [7], a large 
number of industrial projects have also been realized. They 
include a new anti-theft alarm systems for photovoltaic panels 
[8], a wireless sensor network (WSN) for smart gas metering 
(which was also documented by the Italian patent for utility 
model No. 0000279556) and more recently RFID tags and 
readers to be installed on unmanned aerial vehicles (UAVs) [9] 
and sensors for health structure monitoring [10]. Exploiting the 
high expertise of the research group in of sensor board 
realization, this work presents the realization of a new low cost 
and versatile solution for modular control board for pulse-jet 
cleaning of dust collector filter bags.  

Considering the energy costs involved in pressurizing air to 
clean the filter media, the proper design of an innovative ad-
hoc cleaning system is of high interest. A widely used system 
for implementing an automatic cleaning of an air-jet dust 
collector consists of a differential pressure gauge and a 
programmable controller. The differential pressure gauge 
measures the pressure difference between the dirty air side and 
the clean air side of the bag filters in the baghouse: our system 
is based on this consideration. Clean filter systems are called 
“reverse pulse jet”. In the filter media cleaning subsystem, high 
pressure gas injections and short duration are used in the 
reverse direction of the pressure gradient and cause a loosening 
of the dust layer from the surface of the bag: the dust layer is 
then collected in the dust tank located at the bottom of the filter 
housing (see Figure 1). Such systems work in countercurrent 
by compressed air jets controlled by solenoid valves, which in 
turn are activated according to a predefined program [11]. The 
impulse type and the pause time between two consecutive 
pulses are programmed with the sequencer, according to a pre-
defined and not modifiable structure. This procedure causes an 
excessive wear of the sleeve of the filter. The operating 
principle of the sequencers available on the market is the 
following: first, the cleaning cycle is activated. The sequencer 



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www.etasr.com Carosso et al.: A New Modular Control Board for Pulse-Jet Cleaning of Dust Collector Filter Bags 
 

detects the first available electro valve and, on the basis of the 
pre-set working time, the electro valve is opened to recall a 
specific amount of compressed air required to clean the filter 
until the completion of a cleaning cycle. Then, after a pause 
interval, the sequencer automatically recalls and opens the 
following available electro valve to start a new cleaning cycle. 

 

 
Fig. 1.  Lateral view of bag house chamber. 

Therefore, it is not possible to directly check the correct 
working of the cleaning system or the degree of cleanliness 
achieved by the filter when a single cleaning cycle is completed 
(i.e. when a single electrovalve has been activated). Since it is 
not possible to interact directly with the sequencer, the control 
procedure is performed usually from time to time by means of 
external instrumentation. Based on the obtained results, it is 
then possible to re-calibrate the time necessary for carrying out 
a whole cleaning cycle. Evidently, the described technique has 
a set of undesired effects, the most important of them being: 

 The lack of a real time control of the degree of cleanliness 
achieved by the air/gas/steam that passes through the single 
filter. This limitation could be dangerous in the case of 
treatment of dangerous substances. 

 The need of a qualified operator to work on the sequencer 
(even remotely) to adapt the system to the new conditions 
found during the subsequent checks performed with 
external instrumentation. 

 The impossibility to obtain real time reports during the 
filters’ working operations. 

 The impossibility to understand in real time the potential 
causes of malfunctioning. Therefore, it is not possible to 
intervene promptly to avoid more filter damage and even to 
the complete industrial process. 

The innovation implemented here concerns a new modular 
control unit to optimize the cleaning process. Specifically, such 
unit performs multiple tasks: 

 Managing the plurality of voltages input (including AC or 
DC) from the solenoid valves, thus allowing system 
adaptation to different industrial processes. 

 Performing the automation of the cleaning cycle. The 
automatic re-definition of the pulse and pause interval can 
be obtained according to the cleaning results achieved and 
measured inside the filters. 

 The possibility of operation with either fixed or variable 
cleaning cycle. It is possible to set the “cleaning cycle” 

operational mode according to the pressure difference 
between filter input and output (see section II). 

 The possibility to correlate the generated pulse and the 
pause interval to the residual capacity in compressors that 
are supplying air jets. Air shots too long and close to each 
other air shots can drastically decrease the pressure in input. 

II. FUNCTIONAL LOGIC DESCRIPTION OF THE SYSTEM 
The operations performed by the prototypal system 

presented in this work can be better illustrated using the 
scheme represented in Figure 2. The baghouse is divided 
horizontally in four sectors and each one contains four electro 
valves, represented by the EV# codes, and vertically in two 
sections: the clean chamber, where the cleaned air comes out of 
the filters, and the dirty chamber, where the air is introduced to 
be cleaned. The electro valves are responsible to control a 
specific air pulse jet for a group of bags that clean the dirty air 
through the bag cages. 

 

 
Fig. 2.  Baghouse division on 4 sectors. Each sector contains 4 
electrovalves. 

Depending on the size of the filter, the number of sections 
and valves may vary. Only one electro valve at a time is 
excited, the wash cycle is completed when all the valves are 
energized progressively. With this prototypal system, a large 
set of programmed sequences of electro valve activations is 
also possible. However, a good rule is to avoid to fire 
electrovalves placed consecutively. Since each cleaning cycle 
causes a reduction of the filter lifetime, to avoid excessive wear 
on the filter elements, the washing system must be optimized to 
act only when necessary. In that case, the electro valve 
shooting time and the interval between a shot and the next may 
vary depending on the values measured by the pressure sensor 
inside the filter chamber. Usually, for a single electro valve the 
time to shoot can vary from 80ms to 140ms. The time interval 
between two consecutive shots of the same valve may be 
defined in two ways and depends on whether it chooses a 
“fixed cycle” or “variable cycle” operational mode, described 
below. Both cycle types can be programmed with the boards 
realized in this project. Evidently, both the shot duration and 
the interval period must be proportional to the capacity of 
compressors that provide compressed air: shots too long and 
close can drastically decrease the air pressure in input, reducing 
the quality of filtering operation.  

A. Fixed Cycle Operational Mode 
The “fixed cycle” operational mode sets the number of 

cycles to be run during a specific time interval. Let us assume, 



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for instance, that a number of 3 washing cycles is needed 
during one hour. It means that all 16 valves (if the bag filter is 
made by a set of 16 electro valves) must shoot 3 times in one 
hour. As a result, the system will calculate the time interval 
between 2 consecutive shoots as reported in (1): =  ∙ ∙ /∙ /  (1) 

where: tinterval [s] is the time interval between two 
consecutive wash cycles, tshot [s] the time interval between 
electro valve drives, nvalve the total number of valves and 
ncycle/hour [cycle/hour] the total number of cycles in one hour. 

B. Variable Cycle Operational Mode 
With the “variable cycle” operational mode, the shooting 

range time depends on the difference in pressure (DP) between 
the “clean chamber” and the “dirty chamber” of the filter, 
measured through a differential pressure sensor. At first it is 
necessary to determine the desired DP to be maintained and 
this value is used as a set-point to trigger a new cleaning cycle. 
With this information, the system automatically evaluates the 
time interval between two consecutive shots. Of course, if DP 
is greater than the set-point, the system increases the washing 
frequency, thus decreasing the time between two consecutive 
shots. Otherwise, if the DP is lower than the set-point, the time 
between two shots needs to be increased. At specific intervals 
(usually 30-100 seconds) the system controls the DP and 
compares it to the set-point; if it is greater than a preset 
threshold (called “dead band”), the system changes the interval 
time at a fixed percentage (1%-10%), otherwise it stays 
unchanged. If the DP is very low and the filter already has a 
very long interval time (usually limit values are set a priori), 
the washing cycle can be stopped. It is resumed when DP is 
greater than a certain threshold. 

C. General Notes 
Usually, the factory set of the pulse frequency can range 

from a few seconds to a few minutes; this clearly depends on 
the number of valves and the filter size. The number of valves 
inside a filter can vary from 10-16 up to 180-200. If the filter is 
stopped for low DP or low compressed air by the compressors, 
when it is resumed it must restart from the valve next to the one 
where it was previously stopped. In this way, all the sleeves of 
a filter are washed the same number of times. Specific sensors 
can measure the cleaning results inside the filter and according 
to the programmed settings, a potential re-definition of the 
pulse and pause interval between consecutive pulses can be 
automatically obtained.  

III. ELECTRONIC BLOCKS DESCRIPTION 
The system is made by a set of different electronic blocks. 

Their description and their functionalities are presented below, 
according to the different subsystems of the modular control 
board for pulse-jet cleaning of dust collector filter bags: 

 power supply 

 human machine interface 

 output and input of the controller board (the subsystem that 
supervises the whole modular system and can be 

programmed to automatically re-configure the operational 
model) 

 output of the electro valves driver board (the board that 
directly controls the electro valves activation which is 
directly linked with the controller board). 

A scheme of the connection between control board and electro 
valve output control boards using a serial interface is shown in 
Figure 3. 

A. Power Supply 
Industrial pulse jet timer controllers (PJTCs), commonly 

used for baghouse filters, established that control boards that 
use a universal alternating current (AC) input in a full range 
power supply 115/230 VAC. These control boards usually have 
on-board power supplies. It means that whenever there is a 
problem with the circuit power supply, the entire control board 
must be replaced and the new control board must be properly 
reprogrammed. The developed solution aims to separate the 
different possible problems and to make the solution more 
flexible and versatile. Together with common full AC range 
power supply, a system that has a 24 V DC power supply is 
included. It adds robustness to the system and, if failure occurs, 
the power supply can easily be substituted without need of 
reprogramming the entire system, giving thus a noteworthy 
advantage in terms of cost, materials and time saving. 

B. Human-Machine Interface 
A large part of timer controller has an interface that 

operates fully integrated on board without the possibility of 
sending or receiving data from a remote management system. 
For instance the cement industry routinely implements human 
machine interface (HMI) and supervisory control and data 
acquisition (SCADA) interfaces for a wide range of processes, 
maintenance and environmental compliance requirements. 
These sophisticated systems do not offer the possibility to 
adapt to specialized systems dedicated to particulate matter 
(PM) control and associated with advanced baghouse 
diagnostics. PM and baghouse specific systems are certified 
with fieldbus ports to communicate with existing PLCs and 
DCS systems to enable seamless integration with most of the 
existing plant equipment. A common and versatile family of 
standards and technologies that can be used in innovative 
electronic boards is the industrial Ethernet (IE). It consists on 
the use of Ethernet technologies in an industrial environment 
with protocols that provide determinism and real- time control 
(e.g. EtherCAT, EtherNet/IP, PROFINET, POWERLINK, 
SERCOS III, CC-Link IE, and Modbus/TCP [12, 13]). Using 
IE, data collected on the filter bag can be stored and displayed 
on a dashboard, and by sharing them on a shared platform it is 
possible to compare them with others collected by other 
systems. Moreover, using devices connected to a network and a 
centralized interface capable to get data and send commands to 
all devices, it is possible to control the electro valves using 
different information acquired by other sensors distributed on 
the industrial plant. In order to overcome the above difficulties, 
the proposed control board is equipped with an IE controller, 
thus giving the board the whole set of described advantages, 
including the possibility to remotely reprogramming the 
systems, if needed. 



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C. Outputs of the Controller Board 
The control systems available on the market to integrate 

everything on the same board present several inputs and 
outputs. It is possible to find boards with 8/16/32 outputs to 
control solenoid valves. This could be a problem when having 
in mind to further expand the system. If it is necessary to 
control more electro valves and if the system has a limited 
number of outputs, it should be replaced and reprogrammed, 
leading to extra working time and adjustments. The proposed 
electronic board is actually a modular system. It is possible to 
add more output modules to the solenoid valves as needed, 
without changing the control board, by simply adding new 
expansion boards in which the actuation drivers are placed. 
This modularization allows the separation of the actuation 
modules (also referred to as electro valve driver board) from 
the control module. When a failure in one of the actuation 
modules occurs, any of the actuation modules may be 
substituted without modifying the setup and configurations in 
the control module. The board control that drives the solenoid 
valves is controlled by a serial interface. Even if the serial 
communication interface is not a recent one, it allows 
increasing the number of outputs without compromising many 
pins of the microcontroller and, at the same time, giving 
robustness to the system. The serial communication used is 
then a “synchronous serial communication” where each 
actuating board of the solenoid valve has a shift register circuit 
that can trigger sequentially each valve. Each shift register 
circuit has 8 outputs that are used for the control of the electric 
valves. It is possible to increase the number of outputs by 
simply linking several registers together. Other outputs of the 
control board are the alarm signals. They can be programmed 
according to a predefined setup or depending on specific inputs 
coming from dedicated sensors aiming to trigger the alarm 
signals. These outputs can be used to give a visual feedback on 
the system-operating situation or to communicate the presence 
of a possible problem detected by an external sensor. The alarm 
output is an optically isolated transistor that can trigger an 
external device (e.g. acoustic or visual alarm signaling devices).  

D. Input Sensors of the Controller Board 
A DP sensor is commonly used as input of the timing 

control board. The developed system is engineered to allow 
both the input of the DP sensors and the input of a second 
control based on another sensor that can be chosen according to 
specific needs of the industrial process. The automation of the 
system is made according to the input of all those sensors.  

E. Outputs of the Electro Valve Driver Board 
Due to the existence of different types of electronic valves 

in the market, a board with a power interface operating in both 
DC and AC has been designed, thus increasing the system’s 
versatility. Another possibility given by the present modular 
system is the use of AC or DC solenoids using the same circuit. 
Considering a large set of electro valves available on the 
market, it is possible to find electro valves with voltages that 
range in the interval of 115V-230V AC and 24V DC, which are 
generally widespread in the industry. Two common types of 
control boards for electro valves are commercially available. 
They are different on the basis of the circuit used as actuator 
for the solenoid valves. Generally the control boards that 

control AC electro valves use relay or TRIAC (TRIode for 
Alternating Current). The disadvantage of the circuits using 
TRIAC is that they work only for AC thus losing the 
probability to control DC electro valves. In this work, a circuit 
is proposed that can operate with both AC and DC valves. It 
uses a bidirectional electronic switch based on MOSFETS (a 
type of circuit widely used in solid-state relays). By using this 
topology is possible to design a robust circuit at low cost (very 
similar to a simple and standard circuit based on common 
relays). Figure 4 illustrates two bi-directional switches used to 
control two different electrovalves separately. In this case the 
signals defined by IN1 and IN2 are connected in phase with 
respect to the signal considering AC or at the positive signal in 
case of DC. The outputs defined by Pout1 and Pout2 are 
connected to the returns that feed the solenoid valves. This 
circuit has the possibility to use both AC and DC without the 
need to change the power supply modules. Through the Shunt 
resistors (represented in Figure 4 as Shunt 1-4) the electric 
current that supplies the electro valves can be monitored, thus 
controlling if some valve is disconnected or damaged. If a short 
circuit occurs, the activation of a specific electro valve may be 
canceled and in this case an alarm signal can be generated as 
output of the modular control board and sent to the system that 
controls the industrial plant exploiting the IE communication. 

 

 
Fig. 3.  Connection between control board and electro valve output control 
boards using a serial interface 

 

 
Fig. 4.  Bidirectional switches used to control two separated electro valves. 

IV. INSTALLATION 
The proposed modular electronic board can be integrated 

with a large number of systems commonly and widely present 
in a large number of industrial plants. Generally, other systems 
must be installed together with the air filtration system and they 
already have their own power supplies. On the diagram 
represented in Figure 5 it is possible to note the presence of two 



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different circuits: the proper control board of the entire system 
and the board devoted to electro valve controlling (electro 
valve driver board). It is evident that supplying the circuits 
directly with the 24V source, if available, could be optional or 
to supply them with the standard AC provided by the power 
grid. At the same time, it is possible to activate electro valves 
of both types, as described above. Figure 6 represents an 
example of realization of a modular installation using the 
realized boards. The smaller board on top is the control board 
(Figure 7), the other three are the electro valve driver boards 
(Figure 8). It is evident that multiple control boards can be 
interconnected to each other. 

 

 
Fig. 5.  Wiring diagram of the installation of the boards on the system. 

 

 
Fig. 6.  Example of assembled system with 1 controller board and 3 
electrovalves driver boards. 

 

 
Fig. 7.  The realized control board. 

 

 
Fig. 8.  Picture of the realized driver board. 

V. CONCLUSION 
Present work presents the prototypal realization of a 

modular low cost control board for a system for baghouses 
cleaning. Some advantages have been already described in the 
introduction. However, the improvements introduced by these 
boards compared to the usual practice are mainly related to 
their possible integration with already existing commercial 
systems and to the versatility of the system itself. The same 
board allows the automation of the cleaning cycle according to 
measured parameters acquired by dedicated sensors and the 
possibility of operation with both fixed and variable cleaning 
cycles. The modular structure of the boards allows users to 
install them in any desired number without difficult operations 
of reprogramming the entire systems. The possibility to 
connect different drive boards together, controlled by a single 
control board, allows a wide number of drive outputs, widening 
the number of potential applications. The possibility to 
automatically reprogram the entire system using the 
information provided by sensors devoted to check the state and 
the “health” of the filter to be cleaned is very significant. The 
configuration and the programming of the control board can be 
easily made by using a common PC. It is possible to setup the 
number of valves to be activated and the system can be 
configure remotely, since the board is equipped with an IE that 
allows the system itself to be accessible within a company 
network and even in the world of internet (of course, only for 
authorized users). For what concerns the electric drive, it is 
important to highlight that the proposed prototypal board 
allows using the same drive circuit for different types of electro 
valves, thanks to its high versatility.  

REFERENCES 
[1] R. E. Frey,T. V. Reinauer, “New filter rate guide”, Air Engineering, 

Vol. 30, 1964 
[2] E. Bakke, “Optimizing Filtration Parameters”, Journal of the Air 

Pollution Control Association, Vol. 24, No. 12, pp. 1150-1154, 
1974 

[3] A. K. Choudhary, A. Mukhopadhyay, “Particulates: Selection of 
cleaning pulse pressure for pulse jet fabric filtration”, Filtration + 
Separation, Vol. 50, No. 4, pp. 28-30, 2013 

[4] M. Gabella, R. Notarpietro, S. Bertoldo, A. Prato, C. Lucianaz, O. 
Rorato, M. Allegretti, G. Perona, “A Network of Portable, Low-
Cost, X-Band Radars”, in: Doppler Radar Observations - Weather 
Radar, Wind Profiler, Ionospheric Radar, and Other Advanced 
Applications, InTech, 2012 

[5] A. Losso, L. Corgnati, S. Bertoldo, M. Allegretti, R. Notarpietro, G. 
Perona, “SIRIO: an integrated forest fires monitoring, detection 
and decision support system using low cost commercial sensors. 
Performance and result of the experimental installation in Sanremo 
(Italy)”, in: C. A. Brebbia (ed.), Modelling, Monitoring and 
Management of Forest Fires III, pp. 79-90, WIT Press, 2012 

[6] A. A. Khamukhin, A. Y. Demin, D. M. Sonkin, S. Bertoldo, G. 
Perona, V. Kretova, “An algorithm of the wildfire classification by 
its acoustic emission spectrum using Wireless Sensor Networks”, 
Journal Of Physics: Conference Series, Vol. 803, No. 1, Article No. 
012067, 2017 

[7] O. Rorato, C. Lucianaz, S. Bertoldo, M. Allegretti, G. Perona, “A 
multipurpose node for low cost wireless sensor network”, IEEE 
APWC, Cape Town, South Africa, pp. 247-250, September 2-7, 
2012 

[8] S. Bertoldo, O. Rorato, C. Lucianaz, M. Allegretti, “A Wireless 
Sensor Network ad-hoc designed as anti-theft alarm system for 



Engineering, Technology & Applied Science Research Vol. 8, No. 2, 2018, 2799-2804 2804  
 

www.etasr.com Carosso et al.: A New Modular Control Board for Pulse-Jet Cleaning of Dust Collector Filter Bags 
 

photovoltaic panels”, Wireless Sensor Network, Vol. 4, No. 4, pp. 
107-112, 2012 

[9] G. Greco, C. Lucianaz, S. Bertoldo, M. Allegretti, “A solution for 
monitoring operations in harsh environment: a RFID reader for 
small UAV”, IEEE ICEAA, Turin, Italy, pp. 859-862, September 
7-11, 2015 

[10] L. Carosso, M. Allegretti, S. Bertoldo, “Innovative Wireless 
Sensor Network for monitoring and diagnosis of civil 
infrastructures”, IEEE APWC, Verona, Italy, pp. 8-11, September 
11-15, 2017 

[11] P. S. Abhishek, P. N. Ramachandran, “Design of pleated bag filter 
system for particulate emission control in cement industry”, 
International Research Journal of Engineering and Technology, 
Vol. 2 No. 05, pp. 763-768, 2015 

[12] Z. Lin, S. Pearson, An inside look at industrial Ethernet 
communication protocols, Texas Instruments, 2017 

[13] R. Zurawski (ed.), Industrial Communication Technology 
Handbook, CRC Press, 2014