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CHEMICAL ENGINEERING TRANSACTIONS 

VOL. 59, 2017 

A publication of 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Zhuo Yang, Junjie Ba, Jing Pan

Copyright © 2017, AIDIC Servizi S.r.l. 

ISBN 978-88-95608- 49-5; ISSN 2283-9216 

On the Influence of Inlet Distortion on Syngas Compressor for 

Coal Chemical Industry
 
Yong Li, Hongtao Zhang
 Zhengzhou Railway Vocational & Technical College, Zhengzhou 451460, China 

 767991413@qq.com 

Based on numerical simulation and laboratory test, the radial distortion of air flow in a double inlet syngas 

compressor is analysed in this paper. The author also considers the compressor’s mechanical response to 

homogeneous inflow, mixed inflow, and the length of mixing chambers. Finally, the feasibility of the numerical 

simulation is verified, drawing such conclusions: The efficiency and pressure rise of a compressor with 

distorted inlet will decrease by 6.1% and 210Pa, respectively, in the case of mixed inflow, indicating that the 

inlet flow field of the compressor and the one of subsequent fans match poorly, which is a direct cause to the 

degrade in overall compressor performance; the mixing speed is ascending from outer diameter to inner 

diameter at 90 degrees or above in the circumferential direction and descending at 270 degrees or above; the 

internal diameter velocity is higher than the external diameter velocity in the radial direction; the maximum flow 

rate measured by turbine flow meter is 0.201kg/s and the minimum one is 0.0256kg/s. The maximum inflow 

rate is 0.089kg/s and the minimum one is 0.064kg/s. The total pressure loss of compressor inflow is in positive 

proportion to the length of the mixing chamber. The longer the mixing chamber is, the greater the loss 

coefficient is. When the length of the mixing chamber is fixed, the loss coefficient is inversely proportional to 

Re. 

1. Introduction

Coal resource is the principal energy source in China. With low production efficiency in the traditional coal 

chemical industry, coal burns incompletely and generates a huge amount of CO2 that pollutes environment 

severely. In this case, new coal chemical industry is of great practical significance. In the coal chemical 

industry, operating efficiency and equipment status directly affect the economic benefits of coal production. 

High-pressure cycle technology is widely used to improve the synthesis efficiency of synthetic gas 

compressor. However, this approach has the disadvantages of large design error caused by the 

inhomogeneity of circulating inflow, lack of correlation parameter correction in the circulation section, and 

overall performance not good enough to meet the design requirements. 

Figure 1: Trend of the centrifugal compressor efficiency 

 

   

DOI: 10.3303/CET1759003

 
 
 
 

 
 
 
 

 

 
 
 
 
 

 
 

Please cite this article as: Yong Li, Hongtao Zhang, 2017, On the influence of inlet distortion on syngas compressor for coal chemical 
industry, Chemical Engineering Transactions, 59, 13-18  DOI:10.3303/CET1759003   

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To solve these problems, it has been a topical study to develop high-efficiency syngas compressor. The 

variation curve of the peak efficiency of compressors between 1950 and 2010 is shown in Figure 1, showing 

that most of the centrifugal compressors are 70%-75% efficient. With continuous technological update, the 

efficiency of centrifugal compressor can reach about 88% by the year 2010. 

In order to further improve the operating efficiency of syngas compressors, researchers studied the 

mechanism of centrifugal compressors in the aspects of aerodynamic theories (Dowson, Walker and Watson, 

2004; Denton and Horlock, 2005; Mitsuhashi, 2002), aerodynamic experiments (Boncinelli, 2007; Xie, 2005; 

Bulot and Trébinjac, 2009; Lee, 2013; Everitt and Spakovszky, 2011); manufacturing technologies (Boncinelli, 

2007 (Wei and Jin, 2012; Li and Xi, 2007), etc. In recent years, syngas compressors have been developed 

and commercialized as a modified version of traditional synthetic gas compressors, whose structures are 

related to working pressure. Researchers analysed syngas compressors from different perspectives, 

achieving some positive outcomes (Rubechini and Boncinelli, 2004; Rubechini and Boncinelli, 2004; Pinto, 

2016; Subramanian, Sekhar and Prasad, 2015; Rafiee and Sadeghiazad, 2016; Mahdy, 2009; Arabawy, 2009; 

Murgi et al., 2016; Freitas et al., 2016; Saebea et al., 2017; Tan et al., 2017; Herman et al., 2016; Chen et al., 

2016; Lestinsky et al., 2016). Based on numerical simulation and laboratory test, the radial distortion of air flow 

in a double inlet syngas compressor is analysed in this paper. The author also considers the compressor’s 

mechanical response to homogeneous inflow, mixed inflow, and the length of mixing chambers. Finally, the 

feasibility of the numerical simulation is verified. 

2. Analysis of the influence of the inlet distortion of double inlet gas compressor 

2.1 Test setup 

At present, the common commercial gas compressor is double-cylinder with an average pressure of about 

14MPa. In order to measure the internal flow field in the circulation section of the synthesis gas compressor, a 

circulating intake air ventilation test equipment is developed with a double inlet device, a centrifugal machine 

and a connecting pipe. There are 10 2mm-thick blades in front of the fan. The turbine is 50.6mm wide, and the 

inlet and outlet diameters are 230.5mm and 593.5mm, respectively. The inlet is composed of double pipes at 

the diameter of respective 100mm and 180mm. The field test device is shown in Figure 1. 

 

 

Figure 2: Field test graph of synthetic gas compressor 

Our tests include the performance test of the synthesis gas compressor and the speed test of the mixing 

chamber in the compressor. The performance test mainly serves to monitor the fan performance in the 

conditions of homogeneous inflow and mixed flow. Pneumatic monitoring consists of static pressures in the 

inlet, in the mixing chamber and in the outlet. 

2.2 The effects of homogeneous flow and mixed flow on compressor performance 

The effect of mixed flow and homogeneous flow on the performance of the compressor was verified by 

numerical simulation and laboratory test. The length of the mixing chamber was set as 210mm. The test 

results are shown in Figure 3, where ΔP is the pressure rise, η is the efficiency, and the abscissa represents 

the ratio of the actual flow Q and the designed flow Qdesign. As can be seen from the figure, the change trend 

of numerical results is similar to that of experimental results, albeit different in the large volume side. When Q / 

Qdesign>1.2, ΔP (numerical simulation) is about 7% higher than ΔP (test). Their little difference in the small 

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volume side is caused by the large value of ΔP obtained when the simulative turbulence intensity is ideally 

lower than the actual one. The two calculation results show that the efficiency and pressure rise of a 

compressor with distorted inlet will decrease by 6.1% and 210Pa, respectively, in the case of mixed inflow. 

This phenomenon indicates that the inlet flow field of the compressor and the one of subsequent fans match 

poorly, which is a direct cause to the degrade in overall compressor performance. 

 

  
(a) Numerical Simulation  (b) Laboratory test 

Figure 3: Performance comparisons of the centrifugal with numerical simulation and laboratory test 

Figure 4 is the distribution of mass flow rates in every flow pass at the designed flow Qdesign. It can be seen 

from the figure that the maximum flow rate is 0.201kg / s in the No. 12 flow pass and the minimum flow rate is 

0.0256kg / s in the No. 1 flow pass. The flow in No. 11 and No. 12 passes is relatively large while the flow in 

No.1 and No. 8 passes is relatively small, all of which are at the outlet of the vortex tongue. In the case of 

homogenous flow, different flow passes have similar flow rates, with the maximum one of 0.089kg / s in the 

No.9 flow pass and the minimum one of 12, 0.064kg / s in the No.12 pass. In the whole, the mass flow rate 

presents periodic distribution. 

 

  

Figure 4: Mass flow distribution in blade passages at uniform and mixing inlet 

2.3 Effect of mixing chamber length on compressor performance 

The author compared the performance of the compressor when the mixing chamber was respective 100mm, 

200mm and 300mm long. It can be seen from the figure that the numerical and experimental fan efficiencies 

decrease with the extension of the mixing chamber. However, when Q/Qdesign<1.1, the fan efficiency at the 

mixing chamber length of 200mm exceeds the one at the mixing chamber length of 100mm. Therefore, it can 

be seen that the length of the mixing chamber exerts some influence on fan efficiency, but not in terms of “the 

longer, the better”. We compared Figure 5 with Figure 3 and summarized that the influence of mixing chamber 

length on ΔP in the inlet and outlet is insignificant. 

 

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(a) Numerical Simulation  (b) Laboratory test 

Figure 5: Performance comparisons of the centrifugal with numerical simulation and laboratory test 

On the basis of the test results, the inflow pressure loss at the three mixing chamber lengths is plotted in 

Figure 6. It can be seen from the figure that the total pressure loss in the three mixing chambers increases 

with the increase of Q/Qdesign, and the longer the mixing chamber is, the greater the total pressure loss 

becomes. This phenomenon is a reflection of the correlation between total pressure loss and route loss in the 

cavity and between total pressure loss and the inflow’s impact loss on the cavity wall. 

 

 

0.6 0.8 1.0 1.2 1.4 1.6
0.0

0.5

1.0

1.5

2.0

2.5

3.0

T
o

ta
l 

p
re

ss
u

re
 l

o
ss

/k
P

a

Q/Q
design

 Mix 100

 Mix 200

 Mix 300

 

Figure 6: Comparisons of total pressure loss with different mixing length 

We expressed the total pressure loss coefficient with F, which is equal to the ratio of the total pressure loss to 

1 / 2ρvmix2. According to the statistical results, we determined the relationship formula of F: 

0.3747
0.58 49.4 Remix

h

l
F

d


     (1) 

Re mix mix h

mix

v d


                                                                                                                                             (2) 

Where Lmix is the length of the mixing chamber; vmix is the mixing speed; dh is the hydraulic diameter; and 

Re is calculated from vmix and dh. The loss coefficient curves at the three mixing chamber lengths are shown 

in Figure 7. As can be seen from the figure, the longer the mixing chamber is, the greater the loss coefficient 

is; and that when the length of the mixing chamber is fixed, the loss coefficient is inversely proportional to Re. 

 

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4 5 6 7 8 9
0.04

0.05

0.06

0.07

0.08

0.09

0.10

0.11

0.12

0.13

 Mix 100

 Mix 200

 Mix 300

L
o
ss

 c
o
e
ff

ic
ie

n
t

Re/105
 

Figure 7: Reynolds number on import resistance coefficient with different mixing length 

3. Conclusion 

Based on numerical simulation and laboratory test, the radial distortion of air flow in a double inlet syngas 

compressor is analysed in this paper. The author also considers the compressor’s mechanical response to 

homogeneous inflow, mixed inflow, and the length of mixing chambers. Finally, the feasibility of the numerical 

simulation is verified, drawing such conclusions:  

The efficiency and pressure rise of a compressor with distorted inlet will decrease by 6.1% and 210Pa, 

respectively, in the case of mixed inflow, indicating that the inlet flow field of the compressor and the one of 

subsequent fans match poorly, which is a direct cause to the degrade in overall compressor performance. 

The mixing speed is ascending from outer diameter to inner diameter at 90 degrees or above in the 

circumferential direction and descending at 270 degrees or above; the internal diameter velocity is higher than 

the external diameter velocity in the radial direction; the maximum flow rate measured by turbine flow meter is 

0.201kg / s and the minimum one is 0.0256kg / s. The maximum inflow rate is 0.089kg / s and the minimum 

one is 0.064kg / s.  

The total pressure loss of compressor inflow is in positive proportion to the length of the mixing chamber. The 

longer the mixing chamber is, the greater the loss coefficient is. When the length of the mixing chamber is 

fixed, the loss coefficient is inversely proportional to Re. 

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