Numerical Research on Water Hammer in Propellant Filling Pipeline

based on Spectral Method

Youhuan Xiang, Ping Zhang, Jianguo Pang, Hui Zhang and Quansheng He

Technical Department, Taiyuan Satellite Launch Center, Taiyuan, China

Keywords: Filling System, Water Hammer, Spectral Method, Characteristic Line Method.

Abstract: In order to research the water hammer problem in the filling pipeline during the rocket propellant filling

process for the spaceflight launch site, improved schemes are proposed. Chebyshev spectral method is

adopted to solve the water hammer problem in the paper. The law of pressure change is analyzed when

water hammer occurs, and the results calculated by the spectral method are compared with the results

calculated by the characteristic line method and the experimental results. The results show that the proposed

schemes can effectively weaken the water hammer in the pipeline during the filling process, improve the

reliability and security of the filling system, and verify the feasibility that adopting the Chebyshev spectral

method to solve the water hammer problem in the filling pipeline.

1 INTRODUCTION

The rockets propellant filling system is an important

part of the spaceflight launch site, and the filling

pipeline is a key assembly in the filling system.

Accurately grasp the work state of the filling

pipeline in the rocket propellant filling process is

very important for the filling accuracy and the

reliability and security of the system (Xiang, 2015).

The filling pipeline in the launch site can provide

routeway for the propellant transporting from the

storehouse horizontal tank to the rocket tank. It’s

stability, reliability and security is very important for

the success of the spaceflight launch. The water

hammer is a water power phenomena in the pipeline

that the water flow rate changed suddenly, leading to

the pressure rise and fall sharply, caused by some

external reasons, such as the valve suddenly open or

close. In the process of rocket propellant filling in

the spaceflight launch site filling system, it often

takes place the phenomena that the pressure of the

filling pipeline is far higher than the designed

pressure, and it is far more than the normal working

pressure range. It is a potential danger for the

system.

The water hammer can damage equipment,

increase the fault probability of the system. It also

can cause violent vibration of the filling pipeline,

result in measurement error for the vortex-shedding

flowmeter. It will reduce the actual propellant filling

precision. Therefore, it requires numerical research

on water hammer problem in the filling system, and

proposes effectively improved schemes. It is very

important for improving the filling precision and

guaranteeing the success of rocket launch.

The rest parts of the paper are organized as

follows: Section 2 introduces the related work.

Section 3 adopts the spectral method to solve the

water hammer problem. The experimental results are

compared and analyzed in section 4. Section 5

makes the conclusions.

2 RELATED WORK

The characteristic line method is widely applied for

solving the water hammer problem. (Liu, 2005)

Firstly it changes the partial differential equation

into ordinary differential equation along the

characteristic line, and then changes it into first order

finite difference equation. The method can solve the

water hammer problem of complicated piping

system with boundary conditions, and the calculation

accuracy of the method is high.

In literature (Yan, 2012), Yan Zheng researches

the water hammer problem of the spacecraft

propulsion system in the processes of priming and

shutdown. On the basic of the established simulation

Xiang, Y., Zhang, P., Pang, J., Zhang, H. and He, Q.

Numerical Research on Water Hammer in Propellant Filling Pipeline based on Spectral Method.

DOI: 10.5220/0005949803930398

In Proceedings of the 13th International Conference on Informatics in Control, Automation and Robotics (ICINCO 2016) - Volume 1, pages 393-398

ISBN: 978-989-758-198-4

393

model of the spacecraft propulsion system, the

simulation research was conducted and the

suppression effect of water hammer for the orifice

and bent duct was analyzed. In literature (Lin, 2008),

Lin Jing-song studies the fluid transients of the

propellant pipes after the liquid rocket engine shut

down, and carries out numerical simulation of water

hammer in shutting liquid rocket engine based on the

method of characteristic line. The correctness of the

simulation results was approved by comparison with

the experiment data. In literature (Nie, 2003), Nie

Wan-sheng researches the pressure and the flow

transients characteristic when the liquid rocket

engine system shut down based on the method of

finite difference characteristic line. In literature (Liu,

2010), Liu Zhao-zhi analyzes the water-hammer

problem based on the characteristic line method for

the actual pipeline structure in the liquid hydrogen

filling system, and the useful measures are proposed

to reduce peak pressure of the water-hammer.

The following are the steps that using the

characteristic line to solve the water hammer

problems. The first step: the partial differential

equation that can’t directly to solve should be

changed into a specific form of ordinary differential

equation, namely characteristic line equation. The

second step: carrying through integral calculus for

the ordinary differential equations, getting the

approximate algebraic integral formula, namely

finite difference equation. The third step: according

to the finite difference equation and bound condition

equation of piping system to calculate. However,

when adopting the spectral method to solve water

hammer in the filling pipeline, the boundary

conditions are complicated, the coordination of time

step is difficult, and the nonlinear iterative

convergence is slow.

The spectral method is discrete method for a kind

of partial differential equation. It is a calculation

method that takes orthogonal function or inherent

function as the approximate function. The spectral

approximation contains two approximate ways, that

is function approximation and equation

approximation (Wang, 2001). On the way of

function approximation, the spectral method contains

three methods: the Fourier method, the Chebyshev

method and the Legendre method. The former is

suitable for the periodic problem, and the latter is

suitable for aperiodic problem. On the way of

equation approximation, the spectral method

contains Collocation method, Galerkin method and

Pseudo-spectral method. The Collocation method is

suitable for the nonlinear problem in the physical

space. The Galerkin method is suitable for the linear

problem in the spectral space. The Pseudo-spectral

method is suitable for nonlinear term processing in

the combination of physical space and spectral

space.

The main characteristic of the spectral method is

fast convergence speed, no phase error, higher

precision and global. It makes the spectral method be

widely adopted in high precision calculation. In

literature (Chen, 2012), Chen Hong-yu proposes a

new algorithm that adopting the Fourier spectral

method to solve the nonlinear hyperbolic partial

differential equations for governing the fluid

transient. By adopting the method, it solves the water

hammer and pressure oscillation formed in the

pipeline when the valve is shut down. It proves the

credibility of the method. In literature (Chen, 2013),

Chen Hong-yu proposes the Chebyshev spectral

method to solve the nonlinear hyperbolic partial

differential equations for governing the fluid

transient in the propellant pipelines. It solves the

water hammer problem in the pipeline when the

valve is shut down by the method, and proves the

feasibility of the method.

In order to further analyzing the generating

mechanism of water hammer problem in the filling

pipeline and the water hammer change law

influenced by the control process of filling system,

and researching the scheme weakening the water

hammer problem in the filling pipeline, the

Chebyshev spectral method is adopted to solve the

water hammer problem in the filling system in the

paper.

3 SOLVE THE WATER HAMMER

PROBLEM BASED ON THE

CHEBYSHEV SPECTRAL

METHOD

3.1 Basic Differential Equation of

Water Hammer

The theoretical basic of the water hammer basic

equation is the mechanics law and continuous

principle of water flow movement. It includes the

motion equation and the continuity equation which

expressed in differential equation. It reflects the flow

velocity of instability flow and the changing rule of

water head in the process of hydraulic transient

(Xiang, 2015), (Lin, 2007).

The continuous differential equation of water

hammer is:

ICINCO 2016 - 13th International Conference on Informatics in Control, Automation and Robotics

394

0sin















(1)

The motion differential equation of water hammer is:













(2)

In the equation, v is the flow velocity of water

hammer, h is the piezometric head of water hammer.

D is the pipe diameter, f is the pipe friction

coefficient, g is the acceleration of gravity. θ is the

angle between pipeline and horizontal plane, c is the

wave velocity of water hammer, s is the distance,

and t is the time.

The basic differential equation of water hammer

is a first order quasilinear hyperbolic partial

differential equations thanks to considering the loss

of the frictional head. The equations contains two

dependent variables and two independent variables.

It is difficult to accurately solve the equations.

3.2 Solve the Problem by the

Chebyshev Spectral Method

The basic differential equation of Water Hammer is

solved based on the Chebyshev spectral method in

this paper. Chebyshev spectral method takes the

Chebyshev polynomial as the basis function. The

function defined in the computational domain can be

go to approximation by the basis function. Then the

partial differential equation can be solved through

the weighted residual method.

When adopting the Chebyshev spectral method,

firstly we take N+1 Chebyshev-Gauss-Lobatto (CLG

for short) (Yang, 2015) points in the interval of [-1,1].

Namely,





cos

，n=0,1,2,…,N.

Then the Chebyshev polynomial is as follow:

)]arccos(cos[)(

nnm





, m=0,1,2,…,N

(3)

The approximate values of state variable and control

variable for the basic differential equation of water

hammer are:







kkN

hhh

)()()()(



(4)







kkN

vvv

)()()()(



(5)

For k=0,1,2, … ,N, the N-order Lagrange

polynomial is as follow:















)(')1(

)1(

)(

(6)

In the above equation,

)('



is the derivative of

)(



which is the N-order Chebyshev polynomial,

and parameter

c satisfy the following condition:











111

,02

, and

)('

jkjk







the Chebyshev differential matrix, the expression

is as follow:



































Nkj

11,

)1(2

)1(





(7)

The water hammer problem has discontinuous

solutions, and larger oscillation can be produced near

the discontinuity point. In order to solve the problem,

the viscous term is introduced in the equation (Chen,

2013), (Ma, 2006). For the continuous differential

equation, the viscous term is

)1(







. For

the motion differential equation, the viscous term is

)1(







. In the viscous term,



is the

viscous amplitude,

is the viscous operator, and

21











The calculation formula of water hammer wave

velocity is (Xu, 2012):







DEK





. In the

formula, K is the fluid bulk modulus,

ρ is the fluid

density, E is the piping materials elastic modulus, D

is the pipe diameter,



is the pipe wall thickness.

According to the calculation formula of water

hammer wave velocity, the water hammer wave

velocity of oxidant pipeline in the propellant filling

system can be get through calculation, c=850m/s.

4 EXPERIMENTAL RESULT

ANALYSIS

The pipeline model for the rocket propellant filling

system is established as Fig.1. In the Fig, the rocket

Numerical Research on Water Hammer in Propellant Filling Pipeline based on Spectral Method

395

tank is vertically located on the launch pad and on

one horizontal plane. Except that, the equipments

such as pump, flowmeter, valve and pressure gauges,

are all located in the pump room of the filling

storehouse and on the same horizontal plane. The

height from the 125# valve to the filling port of the

rocket oxidizer tank is 30 meter or so, and they are

connected together through the filling pipeline.

Pressure

Gauge

Flowmeter

Pump

Flowmeter

125#

124#

Rocket tank

Outlet

134#

Inlet

DT4

121#

122#

Figure 1: Pipeline model for the filling system.

The fluid in the pipeline is N

, and the physical

parameter of N

at the temperature of 20℃ is: the

density ρ=1.446g/cm

, the viscosity

μ=0.4189×10

-3

Pa·s, the saturation pressure

Ps=0.096MPa, the fluid bulk modulus K=1.27GPa.

Before water hammer in the filling pipeline occurs,

the initial state is: the opening of electric control

valve is 30%, the frequency of pump inverter is 50Hz,

the state of the 121# 124# and 134# valve is open,

and the state of the 122# and 125# valve is close.

In order to verify the validity of adopting the

Chebyshev spectral method to solve water hammer

problem in the filling pipeline, the following four

experiments that reduce water hammer in the pipeline

are calculated. The results calculated by the

Chebyshev spectral method are compared with the

results calculated by the characteristic line method

and the experimental results.

Experiment 1: According to the existing filling

process, that is: open up 125# valve, delay of 1

second, at the same time close 124# and 134# valve,

the pump speed is 50Hz, the opening of electric

control valve DT4 is 30%. The calculation results

are shown in Fig. 2.

Fig. 2 shows the comparison and pressure change

law when water hammer happens under the existing

process.

024681012

-0.5

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

Pressure (MPa)

Time (s)

characteristic line method

experimental data

spectral method

Figure 2: Comparison and pressure change law under the

existing process.

The ordinate shows the pressure, and the abscissa

shows the test time. The read curve shows the results

calculated by the Chebyshev spectral method, the

black curve shows the results calculated by the

characteristic line method, and the blue curve shows

the real experimental data. From the Fig we can

know, before water hammer happens, the pressure of

the filling pipeline is 0.25MPa. When water hammer

happens, the pressure increases rapidly, and the peak

pressure calculated by the Chebyshev spectral

method is as high as 3.22MPa. The pressure in the

pipeline has changed dramatically, and there is 13

times difference of the pressure when water hammer

happens.

024681012

-0.5

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

characteristic line method

experimental data

spectral method

Pressure (MPa)

Time (s)

Figure 3: Comparison and pressure change law after

changing the sequential.

Experiment 2: On the basis of the above

experiment, we change the closed sequential of the

related valve when water hammer happens. The

closed sequential of the related valve are changed as

follow: close the 124# valve, 1 second later close the

ICINCO 2016 - 13th International Conference on Informatics in Control, Automation and Robotics

396

134# valve. The calculation results are shown in

Fig.3.

Fig. 3 shows the comparison and pressure change

law when water hammer happens after changing the

sequential. The ordinate shows the pressure, and the

abscissa shows the test time. Through comparing

Fig.2 and Fig.3, we can know that the scheme which

changing the closed sequential of the related valve

can effectively weaken the water hammer problem in

the filling pipeline. Compared with the results in

experiment 1, the peak pressure calculated by the

Chebyshev spectral method is reduced from 3.22MPa

to 2.81MPa, reduced by 12.7%.

Experiment 3: On the basis of the above

experiment, we change the speed of the filling pump

when water hammer happens. The speed of the filling

pump is changed from 50Hz to 40Hz. The calculation

results are shown in Fig.4.

024681012

-0.5

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

characteristic line method

experimental data

spectral method

Pressure (MPa)

Time (s)

Figure 4: Comparison and pressure change law after

changing the pump speed.

Fig. 4 shows the comparison and pressure change

law when water hammer happens after changing the

speed of the filling pump. The ordinate shows the

pressure, and the abscissa shows the test time.

Through comparing Fig.3 and Fig.4, we can know

that the scheme which changing the speed of the

filling pump can effectively weaken the water

hammer problem in the filling pipeline. Compared

with the results in experiment 2, the peak pressure

calculated by the Chebyshev spectral method is

reduced from 2.81MPa to 2.5MPa, reduced by 11%.

Experiment 4: On the basis of the above

experiment, we change the opening of the electric

control valve DT4 when water hammer happens. The

opening of the electric control valve DT4 is changed

from 30% to 60%. The calculation results are shown

in Fig. 5.

024681012

-0.5

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

characteristic line method

experimental data

spectral method

Pressure (MPa)

Time (s)

Figure 5: Comparison and pressure change law after

changing the opening of electric control valve.

Fig. 5 shows the comparison and pressure change

law when water hammer happens after changing the

opening of electric control valve DT4. The ordinate

shows the pressure, and the abscissa shows the test

time. Through comparing Fig.4 and Fig.5, we can

know that the scheme which changing the opening of

electric control valve can effectively weaken the

water hammer problem in the filling pipeline.

Compared with the results in experiment 3, the peak

pressure calculated by the Chebyshev spectral

method is reduced from 2.5MPa to 2.28MPa, reduced

by 8.8%.

123

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

spectral

method

characteristic line

method

Pressure (MPa)

experimental

data

experiment 1

experiment 2

experiment 3

experiment 4

Figure 6: Comparison of water hammer peak pressure

under different experimental conditions.

The comparison of water hammer peak pressure

under different experimental conditions is show in

Fig.6. From the Fig, we can know that the water

hammer peak pressure in experiment 1 is the highest,

it decreased gradually in experiment 2, 3 and 4, and

the water hammer peak pressure in experiment 4 is

the lowest. There is little difference among the three

peak pressures.

Numerical Research on Water Hammer in Propellant Filling Pipeline based on Spectral Method

397

Overall, when adopting the spectral method to

solve water hammer problem, boundary conditions is

simple and computational efficiency is high. The

results calculated by the spectral method under

different experiments are well consistent with the

results calculated by the characteristic line method

and the experimental results. It shows that the

spectral method can well solve the water hammer

problem in propellant filling pipeline as well as the

characteristic line method.

5 CONCLUSION

This paper researches the water hammer problem in

the rocket propellant filling pipeline under the filling

process of the spaceflight launch site, and analyzes

the effects of filling process on water hammer. The

law of pressure change is analyzed when water

hammer happens. Improved schemes are proposed to

weaken the water hammer in the filling pipeline. We

adopt the Chebyshev spectral method to solve the

water hammer problem, and present the calculation

results. We can come to the following conclusions:

(1) The Chebyshev spectral method can well solve

the water hammer problem in propellant filling

pipeline. (2) The proposed schemes can effectively

weaken water hammer in the pipeline during the

filling process, and improve the reliability and

security of the filling system. Through numerical

analysis for the different experiments, it can provide

theoretical basis and data support for weakening

water hammer problem in the filling system and

optimizing filling process.

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