Modeling and Simulation of Reaction and Fractionation Systems for the Industrial Residue Hydrotreating Process

Since the constants of LHHW in Equations (1) and (2) ascertained by basic research are scarcely 

found, general kinetic reactions are applied to describe the reaction network of petroleum based on 

the Arrhenius equation. And researchers have different opinions about the order of the reactions 

[27,28]. In this paper, it is presumed that the whole reaction pathway consists of first-order reactions. 

In addition, due to the low gas yield of the entire reaction system, the volume of the reaction system 

is assumed to be immutable.   

The reaction rate  R   can also be expressed in the form of the power law model: 

,

,

=

−

where  k   denotes the reaction rate constant; 

 and 

  are the molar concentrations of lump 

and  j , respectively; 

  reaction orders of lump 

 and  j , respectively. 

In this paper, all constants for 

,

m i   are set to 1.   

In fact, the data obtained from the factory is based on mass flow rate. It is difficult to acquire 

mole fractions of the lumps. Instead, the mass concentration is adopted to calculate the kinetic 

parameters. Accordingly, the rate equation can be rewritten as: 

m,i

m, j

l

l

i

j

R = -k y y

(4) 

 and 

  indicate the mass concentrations of lump 

 and  j , respectively; 

  is the rate 

constant of the 

th

l

 reaction for lump 

 and  j , Thus, based on the reaction network of asphaltene 

conversion, the mathematical equations of the kinetic model can be rewritten in the following forms: 

1

1 1

3 1

(

)

= −

+

+

(5) 

1 1

6 2

(

)

=

−

+

3

2 1

8 3

=

+

(7) 

6 2

=

+

(8) 

Kinetic scheme for the six-lump model of asphaltene hydrogenation.

Since the constants of LHHW in Equations (1) and (2) ascertained by basic research are scarcely

found, general kinetic reactions are applied to describe the reaction network of petroleum based on the

Arrhenius equation. And researchers have di

fferent opinions about the order of the reactions [

27

,

28

this paper, it is presumed that the whole reaction pathway consists of first-order reactions. In addition,

due to the low gas yield of the entire reaction system, the volume of the reaction system is assumed to

be immutable.

The reaction rate R can also be expressed in the form of the power law model:

R

=

m,i

C

m,j

(3)

i

and C

are the molar concentrations of lump i and j,

respectively; m, i and m, j denote the m

th

reaction orders of lump i and j, respectively. In this paper, all

In fact, the data obtained from the factory is based on mass flow rate. It is di

fficult to acquire mole

fractions of the lumps. Instead, the mass concentration is adopted to calculate the kinetic parameters.

Accordingly, the rate equation can be rewritten as:

R

l

−k

l

m,i

y

m,j

(4)

i

and y

indicate the mass concentrations of lump i and j, respectively; k

l

is the rate constant of

th

reaction for lump i and j, Thus, based on the reaction network of asphaltene conversion, the

dy

1

=

−

k

1

1

+

2

y

+

k

y

1

k

4

1

)

dy

2

=

k

y

1

(

k

y

2

k

6

2

+

7

y

)

(6)

3

dt

k

2

1

+

5

y

− k

y

3

dy

4

=

k

y

2

k

8

3

(8)

Processes 2020, 8, 32

7 of 19

dy

5

dt

=

k

3

y

1

+

k

7

y

2

(9)

dy

6

dt

=

k

4

y

1

(10)

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