2018 International Conference on Sensor Network and Computer Engineering (ICSNCE 2018) 

77 

 

Design of Pellet Recycle Scraper System in Sand-Blasting Chamber 

Wang Baoli  

Bombardier Sifang (Qingdao)  

Transportation Ltd 

Shandong 266111, China 

Wang Junli  

Bombardier Sifang (Qingdao)  

Transportation Ltd 

Shandong 266111,China 

Zhao Zhipeng 

Bombardier Sifang (Qingdao)  

Transportation Ltd 

Shandong 266111, China 

e-mail: 760907040@qq.com 

 
 

 

 

 

 

 

 

Abstract—In the process of industrial sand-blasting, it is 

necessary to recycle the pellet. In order to solve the existing 

problems such as high cost, vulnerability, maintenance 

difficulty and low recycle efficiency in pneumatic recycling 

system and mechanical recycling system of pellet, we designed 

a trapezoidal scraper recycle system of pellet which powered 

by the cylinder and controlled by PLC to realize the pellet 

collection. The core component of the system is the scraper 

mechanical structure which mainly composed of scraper, 

scraper cylinder, baffle, scraper frame, bearing. This design 

has the advantages such as simple structure, resistant to 

breakdown, easy dismantlement. By installing pneumatic valve 

on the cylinder, the sand scraping speed can be adjusted. The 

trapezoidal scraper pellet recycling system efficiency is much 

higher after the contrast experiments between trapezoidal 

scraper and mechanical screw conveyor of the original 

equipment. 

Keywords-Pellet; Cylinder; PLC; Scraper; Trapezoid  

 

I. INTRODUCTION 

In order to improve the adhesion of the surface paint, it is 
necessary to sand-blast on the workpiece. During the 
sand-blasting process, pellet need to be recycled for the 
purpose of cost reduction [1-2]. At present, pneumatic 
recycling system [3] and mechanical recycling system [4-5] 
are widely used in our country for pellet recycle. However, 
problems such as high cost, vulnerability and maintenance 
difficulty still exist. Therefore, it is overwhelming important 
to design a recycle system for pellet of low cost, resistance to 
breakdown and easy maintenance. 

II. PELLET RECYCLE SYSTEM 

Scraper-typed pellet recycle system [6] designed by this 
design is mainly composed of 2 rod, 3 scraper, 5 cylinder, 6 
pellet-collect container and so on. As shown in Figure 1, 1 is 
trench, 4 is air rod and 7 is pellet material. The air rod is 
fixedly connected with the pull rod. Numerous scrapers with 
the same structure are fixedly connected with the pull rod. 
The scraper has the function of one-way reversing. When the 
air rod is retracted, the scraper will move the pellet material 

to the material collecting container. When the air rod is 
stretched out, the scraper will flip without pushing pellet, so 
that pellet will achieve a cycle of directional movement. By 
installing pneumatic valve on the cylinder, air rod speed can 
be adjusted. 

 
1

7

2 3 4 5

6

 
Figure 1. Scraper pellet recycle system 

 

III. MECHANICAL SYSTEM DESIGN 

A. Scraper structure 

The core component of the material recycle system is the 
scraper. For the scraper system designed in this design as 
shown in Fig. 2, Fig. 3, Fig. 4, Fig. 5, 1 is trench, 7 is the 
pellet material. The physical map is shown in Figure 3-4. 
Scraper system is mainly composed of 2 bearing mounting 
plates, 3 scraper frame, 4 vertical bearing, 5 lateral bearing, 6 
scraper, 8 baffle, 9 bayonet and 10 scraper cylinder as shown 
in Figure 3-1 and Figure 3-2. Scraper and scraper cylinder 
are in dynamic connection, with functions such as one-way 
flip and reverse scraping. The basic scraper structure is 
trapezoidal. The role of bayonet is to constrain the freedom 
for scraper up and down. The surface of the scraper frame is 
fixedly connected with the scraper cylinder and the baffle. 
Lateral bearing and vertical bearing are cross-typed with 
functions of guiding and undertaking weight respectively as 
shown in Figure 3-3. Lateral bearing and vertical bearing are 
mounted on the bearing mounting plate. Bearing mounting 
plate is fixedly installed on the inner wall of the trench. One 
end of the scraper frame is fixedly connected with the air rod. 
The pneumatic control valves and proximity switch are 
mounted onto the air cylinder. 



2018 International Conference on Sensor Network and Computer Engineering (ICSNCE 2018) 

78 

 

1

A

A

2

3

4

5

6

7

10

9

8

I

 
Figure 2. Scraper system 

 

10

6

9

8

7

3

 
Figure 3. A-A directional view 

 

3

4

2

5
8

 
Figure 4. I partial view 

 

 

Figure 5. Physical map of trapezoidal scraper 

B. Scraper’s working theory 

Once the scraper-typed pellet recycle is started, the 
scraper frame will move the trapezoid scraper forward and 

backward by scraper cylinder. When the scraper moves 
forward, the scraper will push the pellet forward due to the 
pulling force of the air cylinder and the blocking effect of the 
baffle up on the scraper. When the scraper moves backward, 
the baffle won’t have blocking effect on the scraper, the 
scraper rotates around the scraper cylinder under the reaction 
force of the pellet on the ground, it won’t push the pellet 
material. With such a reciprocating rhyme, directional 
movement of pellet material can be completed as well as 
pellet will be collected. Pneumatic valve can adjust the air 
rod running speed according to the current situation, hence 
adjust the scraping pellet speed by scraper. 

C. Scraper performance analysis 

 The scraper major components are cylinder, scraper, 
scraper frame, bearing and so on. It has advantages 
such as simple structure, low cost, easy 
dismantlement.  

 This design uses trapezoidal scraper and make full 
use of the trench surface to supervise the height of 
pellet piled in case it affects scraper flip. Its 
influence is most obvious when the width of trench 
is small.  

 The bearings are distant from the ground, which can 
prevent the accumulation of pellet from damaging 
the bearings to reduce the maintenance times.  

 The pneumatic speed control valve is installed onto 
the cylinder so the scraper speed can be reduced 
when there are fewer pellet, which can reduce 
scraper loss. 

IV. ELECTRICAL SYSTEM DESIGN  

According to requirements of the system, this design uses 
Siemens S7-200 PLC to control the scraper. This product is 
cheap, powerful with great practicality. PLC I/O allocation 
table is shown in Table 1. Its external wiring diagram is 
shown in Fig 6. Proximate to the switch, PLC detects the 
position of the air rod and controls direction change of the 
cylinder through solenoid valve. When the air rod fails to 
change direction, the PLC will stop and give alarms [7-8]. 

TABLE I. PLC I/O ALLOCATION  

Input Output 

Input component Address 
Output 

component 
Address 

SB1, start I0 Y1, cylinder out Q0 

SB2, stop I1 
Y2, cylinder 

contraction 
Q1 

SQ1, cylinder 
stretched out 

until the position 

of test 

I2 
BJ1, warning 

light 
Q2 

SQ2, cylinder 
contracted until 

the position of 

test 

I3   



2018 International Conference on Sensor Network and Computer Engineering (ICSNCE 2018) 

79 

 

SB1

SB2

SQ1

SQ2

Y1

Y2

BJ1

COM

I0

I1

I2

I3

Q0

Q1

Q2

DC24V

+24V

0V

 
Figure 6. Schema of electrical control 

 

V. EFFICIENCY COMPARISON BETWEEN TRAPEZOIDAL 
SCRAPER AND MECHANICAL PELLET CECYCLE SYSTEM 

In this design, trapezoidal scraper and the original 
mechanical screw conveyor pellet recycling efficiencies are 
compared. The same amount of pellet are placed in two 
ditches. With both systems under the best operating 
efficiency, statistics of recycle time will be collected 
according to 5 kg, 10 kg and 15 kg pellet. The result is 
shown in Table 2. 

TABLE II. PELLET RECOVERY TIME 

Recycled 

pellet quality 

(kg) 

Pellet recovery time(hour) 

Screw 

conveyor 
Trapezoidal 

scraper 

5 0.51 0.30 

10 1.11 0.62 

15 1.56 0.89 

Data show that under the same condition, the time 
required to complete the 5 kg, 10 kg, 15 kg recycle by 
trapezoidal scraper is significantly less than that of the 
mechanical screw conveyor thus prove that the trapezoidal 
scraper pellet recycle system efficiency is much higher. 

VI. CONCLUSION 

Scraped pellet recycle system is proposed in this design. 
It uses Siemens S7-200 PLC as the controller and it's core 
component is the trapezoidal scraper whose advantages are 
simple structure, resistance to breakdown and easy 
dismantlement. With comparison of experiments, it shows 
high efficiency in recycling pellet. Hence it is worthwhile of 
popularization. 

 

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[4] Wang Yongli. Application Examples by Sand-Blasting Machine in 
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[6] Luan Xianyu, Liu Hongnan. Design of Blasting Chamber Scraper 
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