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Trang 1A STUDY OF THE INFLUENCES OF PIPE ON VALVE CONTROL
HYDRAULIC SYSTEM
Kong Xiaowu Qiu Minxiu, Wei Jianhua, Wu Genmao State Key Laboratory of Fluid Power, Zhejiang University, Hangzhou, Zhejiang, 310027,P.R.China
Xwkong@sfp.zju.edu.cn
ABSTRACT
The accurate mathematical model of valve control
hydraulic system with long pipeline is constructed
through theoretical analysis The influences of long
pipeline on valve control hydraulic system are
investigated A series of conclusions were obtained,
which are important to the design and analysis of valve
control hydraulic system
INTRODUCTION
Large-sized construction machinery usually has tens of
actuators All of them get power from a central
hydraulic source Some are far away from the hydraulic
source The long pipeline between actuator and
hydraulic source is essential sometimes It causes many
problems to electro-hydraulic system This paper studies
the influences of long pipeline on valve control system
and comes to some simply and valuable conclusions
TRANSFER FUNCTION OF VALVE
CONTROL SYSTEM
In order to analyze the characteristics of valve control
system with long pipeline, The transfer function of
valve control system must be established Fig.1 shows
the principle of valve control system with long pipeline
Fig.1 The principle of valve control system
(1) Pipe Dynamic Characteristics
Γ +
Γ
=
Γ +
Γ
=
) ( ) ( ) (
1 ) ( ) )
(
) ( ) ( ) ( ) ( ) ( )
(
2 2
1
2 2
1
s sh s P s Z s ch s Q s
Q
s sh s Q s Z s ch s P s
P
C C
Assume that the hydraulic source supply constant
pressure oil, the return pressure is zero and the length of
in-line and return line is equal, then we obtain
0 ) ) ) ( ) )
(
0 ) ( ) ( ) ( ) ( )
(
0
= Γ +
Γ
s sh s Q s Z s ch
s
P
s sh s Q s Z s ch
s
P
v C v
sv C
) 2 ( ) 1 (
where Γ(s)—propagation operator
Z c (s) characteristic impedance
(2) Four-way Slide valve Dynamic Equation
If orifice area of slide valve is matching and symmetric, then the flow-pressure equation is
ρ ρ
v f sv d v f sv d L
P P P A C P P P A C
−
−
−
ρ ρ
v f sv d v f sv d v sv
P P P A C P P P A C Q
2 0 1
0
− + +
−
−
=
=
(4) where
−
≤
−
≥
⋅ +
=
W
A X W
A X X W A A
V
V V
10
10 10
1
, 0 ,
≥
≤
⋅
−
=
W
A X W
A X X W A A
V
V V
20
20 20
2
, 0 ,
1
A is the orifice area of P→A or B→T, A2 is the orifice area of P→B or A→T, A and 10 A are the20
orifice area of operating point, W is the area gradient,
v
X is the relative motion of spool to operating point
d
C is the flow coefficient The Laplace transforms of
Eq (3) and Eq (4) are as follows
) 6 ( ) ( ) ( ) ( ) ( ) (
) 5 ( ) )
( ) ( ) ( )
0 0 0 0
s P K s P K s P K s X K s Q
s P K s P K s P K s X K s Q
v S sv SS f CS v QS sv
v sv
S f C v Q L
+ +
−
=
+ +
−
=
Trang 2
=
⋅
≠
⋅
−
−
− + +
−
−
=
∂
∂
=
0
0
,
,
)
|
| (
) (
20 10
20 10
0
0 0
A A
A A P
P P W
C
P P P P P P
W
C
X
Q
K
v f sv d
v f sv v f sv
d
v
L
Q
ρ
ρ
f
L
C
P
Q
K
∂
∂
=
=
⋅
≠
⋅
−
− +
− +
+
−
−
=
0
0
,
,
)
|
|
( 2
) (
2
20 10
20 10
0 20 10
0 20 0
10
A A
A A
P P P A A C
P P P
A P
P P
A C
v f sv d
v f sv v f sv
d
ρ
ρ
=
≥
−
−
−
=
≥
−
−
≠
⋅
− +
−
−
−
=
∂
∂
−
=
0 0 ,
|
| 2
0 0 ,
|
| 2
0 ,
) (
2
10 20 0
20
20 10 0
10
20 10 0
20 0
10
A A P
P P A C
A A P
P P A C
A A P P P
A P
P
P
A
C
P
Q
K
v f sv d
v f sv d
v f sv v f
sv
d
f
S
CS
đồ đồ
ρ
ρ
ρ
=
≥
−
−
−
=
≥
−
−
≠
⋅
− +
−
−
−
=
∂
∂
=
0 0 ,
|
|
0 0
|
|
0 )
(
10 20 0
20 10 0
20 10 0 0
A A P
P P W
C
A A P
P P W
C
A A P P P P P
P
W
C
X
Q
K
v f sv d
v f sv d
v f sv v f
sv
d
v
S
QS
đồ
đồ
ẳŨ
ẳŨ
ρ
ρ
ρ
CS L CS
S
L
P
Q K K P
Q
∂
∂
=
=
∂
∂
=
0 0
,
C S S C S
S
P
Q K K P
Q
∂
∂
=
=
∂
∂
=
0 0
,
(3) The Continuity Equation and Force
Balance Equation of Cylinder
) 8 ( ) (
) 7 ( ) (
4
2 2
Equation Balance
Force
F X K dt
dX B dt X d m
P
A
Equation Continuity
P C dt
dP E
V dt
dX A
Q
L t t t t t t f
t
f sl f y t t t
L
+ + +
=
⋅ +
⋅ +
=
where A t and X t are the area and motion of hydraulic
cylinder piston respectively, E Y is the equivalent
volume elastic modulus, V t is the general volume of
hydraulic cylinder, C sl is the general leakage
coefficient Eqs (1), (2), (5), (6) together with the
Laplace transforms of Eq (7) and Eq (8) composed a
set equations, from which we can obtain the transfer
function of system as follows
v t
X
X s
G( ) =
) 9 ( ) 1 2 ( ) 2 ) 1 2 (
) ( 2
' 2 2 1 2
2
1
+ + +
+ +
+
=
s s K s G s s
s G K K
h h h C h
h h
vp v
ω
ξ ω ω
ξ ω
where
)) ( ( )) ( ( ) (
1
s ch s sh Z s
Γ
Γ
=
t t
t y h
V m
A
E 2 4
=
ω
t y t
t t
t
t y
t
sl C h
m E
V A
B V
m E A
C K
4
) (
+ +
=
ξ
t
t y
C t
CS h h
V
m E K A
K2 ' =ξ −
ξ
t
Q v
A
K
K =
t
CS QS C Q vp
A
K K K K
=
THEORETICAL ANALYSIS OF THE INFLUENCES OF PIPE ON VALVE CONTROL HYDRAULIC SYSTEM
When the influence of pipe is neglected
s
sv P
P = =constant P0v=P0=0 G1(s)=0 The transfer function of system is
1 2 )
(
2 2 '
+ +
=
=
Ễ
s s
K X
X s G
h h h
v v
t
ω
ξ ω
The influences of pipe on system can be measured by the difference between G (s) and '( )
s
G While the difference in amplitude frequency and phase-frequency characteristic is expressed by
| ) (
|
||
(
|
| ) (
||
) (
'
ω ω ω
ω
j G
j G j
G
and
| )) ( ( )) ( (
| ) (ω ϕ ω ϕ ' ω
respectively, we can reach the following conclusion
If 2(2 )| ( )| 1
1 ≤ <<
K
K
Q
QS
E
e A(ω) ≤ and e ϕ(ω) ≤E
The certification is neglected here
If we define
| ) (
| ) 2
( 2 )
K
K K
Q
QS
C −
then e(ω) can be used to measure the influences of pipe
on system approximately
When slide valve is in different operating position, the
Trang 3influences of pipe to system are discussed as follows
(i) Zero position
When slide valve is in zero position, K C=K CS=0,
0
)
e Pipe has a little influence on the dynamic
characteristics of system The actual value of K c and
cs
K aren’t zero but very small So, the influence of pipe
to system is minimal under the condition
(2) Nonzero position
When slide valve is in nonzero position,
QS
K = ,K C =K CS ,e(ω)=2K C|G1(j ω)|
It will be seen that if K C is small enough, the influences
of pipe on system can be neglected According to the
theory of fluid transmission lines, |G1(j ω)| reaches
maximal point at resonance frequency and fluctuates
periodically as frequency ascends Accordingly, G(j ω)
fluctuates periodically relating to G'(j ω) The
fluctuation frequency is proportional to the length of
pipe The fluctuation amplitude descends as frequency
ascends
SIMULATION STUDY
It will be seen that the influences of pipe on hydraulic
system are related to the steady-state point of slide
valve Slide valve is in zero position in position
control system and in nonzero position in velocity
control system The following is the simulation study
of them
(1) Position Control System
The simulation parameters are as follows:
2
137
=
h
ω
1
−
5
0
=
K
5
0
=
h
9
10
7
9 × −
=
vp
K
Fig.2 presents the frequency response characteristics of
valve control hydraulic system under different pipe
length The simulation result shows:
the frequency response curve of system exists periodic fluctuation
the fluctuation frequency is proportional to the length
of pipe
the fluctuation amplitude reaches maximum near the natural frequency of system and is smaller in low-frequency and high-low-frequency stage
The frequency response is generally approximate to second-order system
Fig.2 The frequency response characteristic of system
when slide valve is in zero Position
Fig.3 The frequency response characteristic of system
when slide valve is in nonzero position
50 100 150 200 250 300 350 400 450 500 -180
-160 -140 -120 -100 -80 -60 -40 -20 0 Phase-frequency characteristics
¦Ø£¨1/s£©
L = 2 5 m
L = 5 0 m
L = 0 m
50 100 150 200 250 300 350 400 450 500 -40
-30 -20 -10 0 10 20 30 40 50 Amplitude frequency characteristic
¦ Ø £ ¨ 1 / s £ ©
L = 0 m
L = 5 0 m L = 2 5 m
50 100 150 200 250 300 350 400 450 500 -250
-200 -150 -100 -50 0 50 100
Phase-frequency characteristic
¦ Ø £ ¨ 1 / s £ ©
L = 2 5 m
L = 5 0 m
L = 0 m
50 100 150 200 250 300 350 400 450 500
25
30
35
40
45
50
55
Amplitude frequency characteristic
¦ Ø £ ¨ 1 / s £ ©
L = 2 5 m
L = 5 0 m
L = 0 m
Trang 4(2) Velocity Control System
The simulation parameters are as follows
2
137
=
h
ω
1
−
10 2
4 × −
=
C
K
12 10
2
4 × −
=
CS
5
0
=
h
Fig.3 presents the frequency response characteristics of
valve control hydraulic system under different pipe
length
The simulation result shows:
the frequency response of system fluctuates
periodically
the fluctuation amplitude descends when the
frequency ascends
the fluctuation frequency is proportional to the length
of pipe
If the length of pipe or the value of K C isn’t small
enough, the system can’t be considered as
second-orde system
CONCLUSION
This paper has presented an accurate mathematical
model for valve control hydraulic system with long
pipeline On the basis of the analysis to it, some
conclusions are reached
1 The influences of pipe on system can be measured
approximately with the frequency domain criterion
| ) (
| ) 2
( 2
)
K
K K
Q
QS
C −
=
2 For given pipe parameters, K c decides the influences
of pipe on system in terms of ideal zero lap slide
valve
3 Pipe makes the frequency response of system
fluctuating periodically The fluctuation frequency is
proportional to the length of pipe The fluctuation
amplitude is decided by valve coefficient, pipe elastic
modulo and pipe inner diameter
4 The influences of pipe are greater to velocity control
system than to position control system
REFERENCES
[1] T.J.Viersma, A.A.Ham, “Hydraulic Line
Dynamics”,1979
[2]
1986
976
” CAD
” CAD
[8] Chen, Jine, “Theoretic solution of the transient flow
of liquid in the pipe with fluid Machinery”, Journal
of Hydrodynamics, v 4 n 4 Oct 1992 p 119-126