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 CHEMICAL ENGINEERING TRANSACTIONS  
 

 VOL. 46, 2015 

A publication of 

 

The Italian Association 
of Chemical Engineering  

Online at www. aidic. it/cet 

Guest Editors: Peiyu Ren, Yanchang Li, Huiping Song 
Copyright © 2015, AIDIC Servizi S. r. l.,  

ISBN 978-88-95608-37-2; ISSN 2283-9216  

Research and Design of Control System for Vibration 
Transmission Machine 

Jian Chu*a, Guoyu W angb 

a Tianjin University of Technology and Education: Joint Lab of Information Sensing & Intelligent Control, 
b School of mechanical engineering, Tianjin University of Technology and Education, Tianjin, 300222, China.  
chujian6@126.com 

Currently, the vibration transmission machines are widely used in mining, metallurgy, coal, chemical, building  
material, light industry, food, and machinery manufacturing industries. Inertia vibrator is divided into two 
categories - non-resonant and resonant. The former has the following advantages: simple structure, 
conveniently manufactured, and stable working state. That is why non-resonant inertia vibrators are mostly 
used in engineering practices. The biggest disadvantage of non-resonant type is bigger power consumption. 
In contrast, the resonant type is durable, has compact structure and has less energy consumption. But it is 
difficult to adjust the working status; small frequency drift will cause large amplitude fluctuation. In order to 
improve energy efficiency and stability, we used vibration velocity as a closed-loop feedback signal and 
microcomputer technology to control resonance conveyor. In the control unit we utilized quadratic optimal 
control algorithm of PID parameter optimal tuning to maximize the automatic frequency tracking and achieved 
steady state of resonance and optimal energy efficiency. 

1. Introduction 

Material handling equipment plays an irreplaceable role in industrial automation. Resonance conveyor is a 
mechanical vibration system controlled by inertia vibrator. Although the resonance type vibrating machine has 
high efficiency, the slope of the response curve is very deep. W hile the system running, small changes in the 
load or other parameters can cause the output to alter significantly. In normal operation, the load of the 
vibration can be changed from 0 to 100%, sometimes it can be overloaded. The number of motor revolutions 
can also fluctuate. The gradual change of the stiffness of the main vibration spring is also hard to avoid. All of 
these would cause changes in the natural frequency. Therefore, the mechanical vibration system directly 
controlled by the inertial vibration exciter is seldom used in engineering.  
In order to solve the issues, we used the vibration velocity of the phase inverted signal for closed -loop 
feedback, namely using PLC for acquisition and processing of feedback signal to realize the frequency 
automatic tracking to achieve system resonance balance. Because of high reliability strong anti -interference 
ability, PLC can be a good candidate for achieving process control automation. This not only can improve  the 
efficiency and quality of the integrated control, but also can improve the working environment. In the future 
development of vibration transmission machine will improve the performance and reliability of components, to 
move towards standardization, serialization, generalization and improve vibration transmission machine 
control, regulation performance, reduce power consumption, reduce noise, achieve more environmentally 
friendly and humanized design. 

2. Working Principle 

The resonant type inertia transfer machine belongs to the single degree of freedom vibration system. With 
high efficiency and energy saving resonance, we can complete task of large power motor with small power 
motor [Sa’ed A. Musmar and T awfeeq Al-kanhal (2014)]. The benefit of energy saving are more obvious for 
large and medium resonance type. The structure diagram of the system is shown in Figure 1: 
 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1546192

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Chu J., Wang G.Y., 2015, Research and design of control system for vibration transmission machine, Chemical 
Engineering Transactions, 46, 1147-1152  DOI:10.3303/CET1546192  

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Figure 1: structure diagram of vibration transmission system 

Because the system uses the vibration speed sensor, it is possible to make the closed -loop feedback system 
to become self excited system of negative resistance. To achieve this, it must meet the following conditions: 
(1) The working frequency of the frequency conversion power supply shall be set to  . 

 1.05 0.05   n  

The frequency setting is easy to implement, and it is actually wider for the synchronization range.  
the forced vibration equation of a degree of freedom vibration system: 

0 0" ' sin  Mx fx kx F t  

In the formula: M--Quality; X--Displacement; K--Spring rigidity; f--Coefficient of friction; F0--Exciting force 
Equation solution: 

 0sin x A t   

The equations can be obtained by the above equation: 

 20 0 cos 0  k m A f   

0 0 sin 0 f A F   

Can be obtained: 
2

0 0cos /A m    
21

0 0/


 tg f k m    

Voltage output is 

 0 0cos v A t    

Therefore, the output voltage of the PLC is used to control the frequency power, so that the frequency 
conversion power and its phase locked synchronization work, you can achieve a stable vibration state, that is  

0  n  . 
(2) If the system is to show the negative resistance self - excited state, the method is to be 0 ﹤ . When 
debugging the system, cut off the frequency   of the feedback observation set, and to connect with the 
feedback observation 0 . 

3. Control Scheme Design 

For control system we selected S7-200 SIEMENS as the control center of the system. In terms of data 
acquisition we used electromagnetic induction vibration speed sensor to detect mechanical vibration velocity. 

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For inertial vibrator position detection we used infrared position sensor. For sensor and frequency converter 
simulation data input and output. We used module EM235 and S7-200 combination [O. Badran, H. And B. 
Alomour (2012)].  
By changing frequency of the converter, the vibration amplitude was transmitted to PLC through the sensor 
and was recorded. In the process of vibrating body movement cycle when the input voltage is i ncreased to the 
maximum, the vibration cycle T was obtained by PLC through a timing and vibration angular velocity 1  and 
eccentric block angular velocity 2  were detected. The PID controller was used to adjust the real and 
theoretical value of the four detection time of the eccentric block. At the same time, the two time optimal 
control algorithm was adopted to achieve the optimal tuning of PID parameters. According to the requirem ent 
of control system in the selected PLC, we used STEP7 Micro/W IN as a process control software development 
environment. PLC ladder diagram language was used to complete the design and debugging of PLC control 
program. We used WinCC as computer monitoring system, and touch screen monitor at lower machine for on-
site monitoring. The main module functions were: human-computer interaction, data acquisition, control, 
protection, communication, etc. 
We used the linear quadratic optimal control algorithm for the optimal tuning of PID parameters, so that the 
system can achieve optimal efficiency and energy saving when the resonance is reached. We set the 
performance index function as J, to optimize the system by adjusting the two performance index to reach the 
maximum. 

2

1

1
 J J

J  

                 

             
     

1

1 1 1 1
0

2

2 2 2

  
  

    


T T T
t

T

T T Tt

X t A t X t U t E t X t U t D t U t
J dt X t G t X t

X t D t U t X t a t U t b t

 

   
1

2
0

 
t

t
J E t I t dt  

In the form of J1, the displacement is the smallest, and the energy of J2 is the largest and the performance 
index is the largest. In the form of J1, X is an n-dimensional state vector, A, B and G are n x n, C is n x r, E is r 
× n, D is R x R matrix of order a n-dimensional, b is r-dimensional vector and their elements are a continuous 
function of t and D is a symmetric positive definite matrix, A and G is a symmetric matrix. In the form of J2, E 
for electromagnetic electromotive force, I for the current. 

The optimal control solution for the minimum value of J1 is the maximum value of 
1

1

J
. The minimum value of 

1J is: 

              0 0 0 0 0 1 0 0 2 0 0, 2  T TV X t t k t X t k t X t K t X t  

Where 2( )K t , 1( )k t , and 0( )k t  are calculated by the following equation: 

     1 22 2 2 2



      

T
T T T

K t E C K D E C K A K B B K
 

     11 2 1 1



    

T
T T T

k t E C K D b C k a B k
 

     10 1 1



  

T
T T

k t b C k D b C k
 

   2 1 1K t G t
, 

 1 1 k t
zero vector, 

 0 0k t
 

The optimal control for the minimum value of J1 is: 
 

   1 2 1        
T T

u D E C K X b C k  

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Optimal control for the maximum value of 2J , Euler equations can be obtained by 2 0J , The values of 
the extreme values can be obtained by the 2J  Euler equation. According to the conditions to determine the 

maximum value of 
'

0
  

  
  

F d F

y dx y
, when 22 0, 0 J J   gets maximum value, when 

2
0, 0 J J   gets minimal value, objective functional J reaches maximum value, which makes the 

system to achieve the maximum energy efficiency. We can analyze the power saving of our optimization 
design by comparing the power usage of before and after optimization desi gn. In practice, the system needs 
the power of 11kw, through the optimal control only need 3KW, energy efficiency is 72.73%. From the results 
we can see the energy saving effect is obvious. Program flow chart of the system is shown in Figure 2: 
 

 
 

Figure 2: System program flow chart 

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4. System Processes 

(1) Searching for synchronization frequency: 
The above calculation shows that the frequency of the converter is about 40 Hz at the time of resonance. We 
gradually increased the frequency by 0.2 Hz at a time, and recorded the amplitude of the vibration body from 
generating type magnetic sensor to magnifier to PLC. Due to the inertia of the mechanical device, each 
frequency increase to a new level should delay 3 cycles. 
(2) Resonance operating control: 
After finding the same frequency, the procedures of vibration body movement cycle were determined, that is 
the process - T1 for input voltage changing to its maximum. In this process, the vibration cycle T was obtained 
through timing by PLC, and then the angular velocity 1  of the vibration body is detected. 
Similarly angular velocity of the eccentric block can be measured. The signal of the two diodes installed on the 
outer orbit of the eccentric block was received by PLC. The conducting time interval between the two adjacent 
receiving diodes is T2/4. Then angular velocity 2  can be obtained through the time recoded by PLC. 
Output voltage control: 
The position of the eccentric block was detected four times in one cycle T1 through encoder at T1/4, T1/2, 
T3/4, and T1. The values were compared with the theoretical value. If the two values were the same, no 
adjustment were needed; otherwise, the optimal control algorithm was used to tune the PID parameters. The 
input signal to the digital regulator was altered by "discrete quantization". Digital regulator output signals must 
be sent to the "recovery" of zero order holder, which recovers the discrete signal to continuous signal. This 
way the object can be effectively controlled. Figure 3 is a block diagram of the digital control: 
 
 

 

Figure 3: Digital control principle 

After the optimal setting of PID parameters, the output of the D/A converter was sent to the frequency 
converter. W hen the speed of the motor was controlled to the same speed and same phase with the vibrating 
body, the system was in the resonance state. 

5. Conclusions 

After the overall design of the vibration transmission system, PLC, frequency converter, vibrating body, exciter 
and advanced control algorithm are the key components for the vibration transmission and control system. 
The vibration type transmission machine is a mechanical vibration system which is controlled by the inertia 
vibration exciter, to achieve high efficiency and energy saving, and increase the system control ability by using 
resonance. The microcomputer control technology is used to control the resonant transmission to realize the 
resonance state of the automatic frequency tracking. PID parameters are adjusted through the optimal control 
algorithm, therefore the vibration system is always running with high efficiency and the energy saving effect is 
obvious. Along with the progress of science and industry, the resonant transmission machine will be widely 
used in the industry. 

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