380X4-MH A3 Assembly Diagrams
SERVICE MANUAL
Feb. 2017
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Contents Travel Circuit ........................................................................................................................................................................... 2 Travel Low-speed Circuit ........................................................................................................................................................ 2 Travel High-speed Circuit ........................................................................................................................................................ 4 Straight Travel Circuit (with HBCV) .............................................................................................................................. 6 Swing Circuit ........................................................................................................................................................................... 8
J Explanation of Hydraulic Circuit and Operations (standard model)
.............................................................................................................................. 8 Swing Speed Limit Control Circuit ............................................................................................................................ 10 Swing Relief Cut Control Circuit Swing Brake Circuit ............................................................................................................................................................... 12 ............................................................................................................................ 14 Free Swing Circuit (when starting) ............................................................................................................................ 16 Free Swing Circuit (when stopping) ............................................................................................................................ 18 Swing Parking Circuit (lever in neutral) ............................................................................................................................ 20 Swing Parking Circuit (brake release) ............................................................................................................................ 22 Swing Parking Circuit (machine stop) Boom Circuit .......................................................................................................................................................................... 24 Boom-up Circuit (for independent operation) (with HBCV) Boom-down Regenerative Circuit (with HBCV) Boom-down Load Holding Valve Circuit Boom-up Interference Prevention Circuit (with HBCV) Boom-up End Shock Reduction Circuit (with HBCV)
............................................................................................................................ 24 ............................................................................................................................ 26 ............................................................................................................................ 28 ............................................................................................................................ 30 ............................................................................................................................ 32
Arm Circuit ............................................................................................................................................................................. 34 Arm-in Circuit (with HBCV) .................................................................................................................................................... 34 Arm Semi-parallel 1 Circuit (with HBCV) ............................................................................................................................ 36 Arm Semi-parallel 1 Circuit (for ............................................................................................................................ 38 compound operation) (ex.: arm-out + right swing operations) (with HBCV) Arm Semi-parallel 2 Circuit (for ............................................................................................................................ 40 independent operation) (with HBCV) Arm Semi-parallel 2 Circuit (for ............................................................................................................................ 42 compound operation) (ex.: arm-out + boom-up operations) (with HBCV) Arm-out Regenerative Circuit (with ............................................................................................................................ 44 HBCV) Arm-in Interference Prevention Circuit ............................................................................................................................ 46 (with HBCV) Arm-in Shock Reduction Circuit (with ............................................................................................................................ 48 HBCV) Arm-out End Shock Reduction Circuit ............................................................................................................................ 50 (with HBCV) Negative Control Circuit ....................................................................................................................................................... 52 Negative Control Circuit ........................................................................................................................................................ 52 Other Circuits ........................................................................................................................................................................ 54
Cushion Circuit (ex.: when stopping arm- ............................................................................................................................ 56 out operation) Heat Circuit (lever in neutral) ................................................................................................................................................ 58 Auto Pressure Boost Circuit (arm in) (with ............................................................................................................................ 60 HBCV) Elevator Cab Up/Down Circuit .............................................................................................................................................. 62 LM Circuit .............................................................................................................................................................................. 64
model)
(standard
Operations
and
Circuit
Hydraulic
of
Explanation
1
2
Travel Circuit Travel Low-speed Circuit
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2 CCW par2
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
ELEVATOR UP pbr1 DOWN par1
P
P
MA
MB
ps1
T3
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
VB
P3 ps2
2.55MPa at 30L/min
11
12
CENTER CUT pcc
pga1
35.8-37.8MPa at 50L/min
VA
VA
REG
VB
REG
35.8-37.8MPa at 50L/min
pga2
pdp A5
TRAVEL(L)
39.2MPa at 20L/min 39.2MPa at 20L/min
B5
TRAVEL(R)
ARM(2)
ARM(1) pb5 OUT
OUT pb9
pa5 IN
IN pa9
BACKWARD
BACKWARD
par ARM REGENERATIVE D
MB
MA
D
ARM 2 SUB CONTROL
13
pap pgb
pc3 ARM 1 SUB CONTROL
13
10
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
BOOM(2)
B8
T
BOOM(1)
pb4 DOWN
DOWN pb8
P
UP pa8
pa4 UP
1
9
39.2MPa at 20L/min 39.2MPa at 20L/min
B3 A3 SWING
5
B7
2
4
6
3
A7
BUCKET
pb3 LEFT
CLOSE pb7
pa3 RIGHT
OPEN pa7
B2 A2
B6
39.2MPa at 20L/min 39.2MPa at 20L/min
OPTION pb2 GRAPPLE OPEN
BACKWARD
pa2 GRAPPLE CLOSE
FORWARD
A6 pb6
pa6
P4
B1 A1 BACKWARD
DR3p
pb1 FORWARD
TRAVEL STRAIGHT
pst
pa1
15 MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
14
P1
P2
PH
6 6 P1
16
C2
SWING BRAKE
C3
2-STAGE RELIEF
D1
4
5
CENTER CUT
A1
C12
C1
8 3 1
17 P0 1932BC5D
7
A2
A3
3 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
7
Oil cooler
13
Swash plate
2
Control valve
8
Main computer
14
Left travel spool
3
5-stack solenoid valve
9
Travel motor
15
Right travel spool
4
Lever lock solenoid valve
10
Travel remote control valve
16
Travel high-speed select switch
5
Console lever lock switch
11
Forward left
17
Travel high-speed solenoid valve
6
Check valve
12
Forward right
The machine travels at high speed when the angle of the travel motor (9) swash plate (13) is small. The machine travels at low speed when the angle of the travel motor (9) swash plate (13) is large. As an example, this section explains the case in which the forward travel operation is carried out. When the travel remote control valve (10) is operated to the forward side, the pilot pressure oil is fed to Port pa1 of the control valve (2) and switches the left travel spool (14) to the forward side. At the same time, the pressure oil is also fed to Port pa6 of the control valve (2) and switches the right travel spool (15) to the forward side. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and the discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2). Switching the left travel spool (14) and right travel spool (15) lets each discharge oil flow to the travel motor (9) and causes forward travel. When the travel high-speed select switch (16) is set to low-speed travel, the travel high-speed solenoid valve (17) is turned OFF and the pilot pressure oil from Port P of the travel motor (9) returns to the hydraulic tank through Port C1 of the 5-stack solenoid valve (3). As a result, the angle of the travel motor (9) swash plate (13) becomes larger and the machine travels at low speed. Even if the travel high-speed select switch (16) is set to high-speed travel, when the key switch is turned OFF and then ON again, the swash plate (13) angle becomes larger and the low-speed travel is resumed. The return oil from the travel motor (9) returns to the hydraulic tank through the left and right travel spools.
4
Travel High-speed Circuit
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2 CCW par2
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
ELEVATOR UP pbr1 DOWN par1
P
MB
P
MA
T3
ps1
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
VB
P3 ps2
2.55MPa at 30L/min
11
12
CENTER CUT pcc
pga1
35.8-37.8MPa at 50L/min
VA
VA
REG
VB
REG
35.8-37.8MPa at 50L/min
pga2
pdp A5
TRAVEL(L)
TRAVEL(R)
BACKWARD
BACKWARD
39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(1)
ARM(2)
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE
D
MB
MA
D
ARM 2 SUB CONTROL
13
pap pgb
pc3 ARM 1 SUB CONTROL
13
10
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
BOOM(2)
B8
T
BOOM(1)
pb4 DOWN
DOWN pb8
pa4 UP
P
UP pa8
1
9
39.2MPa at 20L/min 39.2MPa at 20L/min
B3 A3 SWING
5
B7
2
4
6
3
A7
BUCKET
pb3 LEFT
CLOSE pb7
pa3 RIGHT
OPEN pa7
B2 A2
B6
39.2MPa at 20L/min 39.2MPa at 20L/min
OPTION pb2 GRAPPLE OPEN
BACKWARD
pa2 GRAPPLE CLOSE
FORWARD
A6 pb6
pa6
P4
B1 A1 BACKWARD
DR3p
pb1 FORWARD
TRAVEL STRAIGHT
pst
pa1
15 MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
14
P1
P2
PH
6 P1
16
C2
SWING BRAKE
C3
2-STAGE RELIEF
6 D1
4
5 7
CENTER CUT
C12
A1
C1
19 8 3 1
17 P0 53662675
A2
A3
5 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
7
Oil cooler
13
Swash plate
2
Control valve
8
Main computer
14
Left travel spool
3
5-stack solenoid valve
9
Travel motor
15
Right travel spool
4
Lever lock solenoid valve
10
Travel remote control valve
16
Travel high-speed select switch
5
Console lever lock switch
11
Forward left
17
Travel high-speed solenoid valve
6
Check valve
12
Forward right
The machine travels at high speed when the angle of the travel motor (9) swash plate (13) is small. The machine travels at low speed when the angle of the travel motor (9) swash plate (13) is large. As an example, this section explains the case in which the forward travel operation is carried out. When the travel remote control valve (10) is operated to the forward side, the pilot pressure oil is fed to Port pa1 of the control valve (2) and switches the left travel spool (14) to the forward side. At the same time, the pressure oil is also fed to Port pa6 of the control valve (2) and switches the right travel spool (15) to the forward side. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and the discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2). Switching the left travel spool (14) and right travel spool (15) lets each discharge oil flow to the travel motor (9) and causes forward travel. When the travel high-speed select switch (16) is set to high-speed travel, the travel high-speed solenoid valve (17) is turned ON and the pilot pressure oil from Port C1 of the 5-stack solenoid valve (3) flows into Port P of the travel motor (9). As a result, the angle of the travel motor (9) swash plate (13) becomes smaller and the machine travels at high speed. Even if the travel high-speed select switch (16) is set to high-speed travel, when the key switch is turned OFF and then ON again, the swash plate (13) angle becomes larger and the low-speed travel is resumed. The return oil from the travel motor (9) returns to the hydraulic tank through the left and right travel spools.
6
Straight Travel Circuit (with HBCV)
Tr1
P
MB
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
P
MA
2ND OPTION CW pbr2 CCW par2
REG
VA VB
VA
35.8-37.8MPa at 50L/min
VB
REG
35.8-37.8MPa at 50L/min
26 BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
ELEVATOR UP pbr1 DOWN par1
T3
ps1
T4
DR2h
T1
T2
DR1h 2.55MPa at 30L/min
pga2
D
MB
MA
13
D
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
G1
(G3)
C 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
9
B A
B A
pdp
13
A5
(G3)
G1 C
ARM(2)
ARM(1) pb5 OUT
OUT pb9
pa5 IN
IN pa9
PL PL
par ARM REGENERATIVE
I
K
Q
A
E
C
M
G
PN
DR
O ARM 2 SUB CONTROL
T
20
pc3 ARM 1 SUB CONTROL
pgb
A8 B8
39.2MPa at 20L/min 27.4MPa at 280L/min
pb4 DOWN
DOWN pb8
pa4 UP
R J
L
RIGHT
PB
LEFT
D
B
IN
PD
PF
OUT
UP
F
H
PH
N
PP
P
UP 39.2MPa at 20L/min 39.2MPa at 20L/min
B3 A3
DOWN
SWING
CLOSE
A7
pa3 RIGHT
OPEN pa7
B2 A2
B6
39.2MPa at 20L/min 39.2MPa at 20L/min
OPTION
23
pb2 GRAPPLE OPEN
12
BACKWARD
P1
FORWARD
pa6
TRAVEL(L)
TRAVEL(R)
B1
BACKWARD
BACKWARD
A1 BACKWARD
15 TRAVEL STRAIGHT
FORWARD
pst
pa1
P3
T
ARM A2
P1
EV
C
BUCKET CLOSE-CONT
D
ARM 2 SUB-CONT
E
ARM REGENE
F
BOOM REGENE
ARM 1 SUB-CONT
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
T
A1
B
A
22
14 BOOM
21
DR3p
pb1
10 P2
A6 pb6
pa2 GRAPPLE CLOSE P4
27
19
CLOSE pb7
18 11
pa8 B7
BUCKET
pb3 LEFT
OPEN
DR
pap
P1
P2
PH
A3
A1
P 5
1
2
4
6
T1
3
6 P1 P
D1
5
4
C2 SWING BRAKE T
7
24
C3
2-STAGE RELIEF
CENTER CUT
A1
C12
BOOM 2
4
3
GRAPPLE DOWN
CLOSE 1
OPEN 3
C1
16 8
25 F4AA6DA9
1 17 P0
A2
A3
6
7 Pressure line (P1 side)
Pilot pressure line
Pressure line (P2 side)
Pilot tank line
Tank line
Electric line
1
Hydraulic pump
10
Travel remote control valve
19
Boom [1] spool
2
Control valve
11
Forward left
20
Boom [2] spool
3
5-stack solenoid valve
12
Forward right
21
Straight travel spool control
4
Lever lock solenoid valve
13
Swash plate
22
Straight travel spool
5
Console lever lock switch
14
Left travel spool
23
Check valve with travel merge orifice
6
Check valve
15
Right travel spool
24
Remote control valve (boom, bucket)
7
Oil cooler
16
Travel high-speed select switch
25
Boom up
8
Main computer
17
Travel high-speed solenoid valve
26
Boom cylinder
9
Travel motor
18
Cushion valve
27
3-stack pressure reducing valve
As an example, this section explains the case in which forward travel and boom-up operation are carried out simultaneously. When the travel remote control valve (10) is operated to the forward side, the pilot pressure oil is fed to Port pa1 of the control valve (2) and switches the left travel spool (14) to the forward side. In the same way, the oil is also fed to Port Pa6 of the control valve (2) and switches the right travel spool (15) to the forward side. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and the discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2). Switching the left travel spool (14) and right travel spool (15) lets each discharge oil flow to the travel motor (9) and causes forward travel. If a boom-up operation is carried out during travel, the pilot pressure oil is fed to Port pa8 and Port pa4 of the control valve (2) via the cushion valve (18) and switches the boom [1] spool (19) and boom [2] spool (20) to the up side. When a compound operation (it is a boom-up operation and forward travel operation this time) is detected by the sensors, the main computer (8) turns ON the straight travel spool control (21) and the pilot pressure oil is fed to Port pst of the control valve (2) and switches the straight travel spool (22). The amount of switching of the straight travel spool (22) varies with the upper pilot pressure. (The pilot pressure is low for slight upper operation. As a result, the amount of switching of the straight travel spool (22) is reduced and the travel speed is stabilized.) Switching the straight travel spool (22) allows the pressure oil from Port P1 of the control valve (2) to drive the left and right travel motors (9) and the pressure oil from Port P2 of the control valve (2) to drive the boom. Because the left and right motors are driven by 1 pump, the left and right motors have the same pressure and straight travel is possible. Furthermore, the excess oil from P2 of the control valve (2) is fed to the travel side via the check valve with travel merge orifice (23) to minimize the drop in speed. The same operations are carried out when travel and an upper actuator other than for the boom are operated simultaneously.
8
Swing Circuit Swing Speed Limit Control Circuit
Tr1
LEFT
A
RIGHT
MU
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2
9
B
CCW par2
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
ELEVATOR UP pbr1
2
GB
29.4MPa at 350L/min
GA
DOWN par1
T3
ps1
T4
DR2h
T1 T2
DR1h
13
Dr
2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
pdp A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(1)
250.0cm 3/rev
ARM(2)
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
Au
pap pgb
pc3 ARM 1 SUB CONTROL
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
17
BOOM(2)
P
B8
BOOM(1)
pb4 DOWN
DOWN pb8 UP pa8
pa4 UP
B3
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
A3 LEFT
B7 A7
BUCKET
CLOSE pb7
pb3
RIGHT
6
OPEN pa7
pa3
B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
6
TRAVEL(R)
OPTION pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
7
P4
14
B1 A1
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
TRAVEL STRAIGHT
pst
10 Q
I
K
C
A
E
G
M
PN
O
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
P1
T
PH
P2
15
R
J RIGHT
L
PB
LEFT
IN
D
B
PD
PF
OUT
UP
F
H
PH
N
PP
P
(FRONT)
Psv1
a1
DOWN CLOSE
OPEN
A1
A2
a2
Psv2
(REAR)
8 3
11
P1
5
D1
C2 P
T
18 C3 2-STAGE RELIEF
CENTER CUT C12
ARM IN
SWING OUT
2
4
LEFT 3
C1
16
M
a5
A3 a3
Dr
2-STAGE TRAVEL
1
RIGHT
B1
1
B3 OUT
12 38C9C112
4
P0
IN
Dr3
9 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
7
Oil cooler
13
Swing motor relief valve
2
Control valve
8
Main computer
14
Swing pilot pressure sensor
3
5-stack solenoid valve
9
Swing motor
15
P1 pressure sensor
4
Lever lock solenoid valve
10
Cushion valve
16
P1 flow control proportional valve
5
Console lever lock switch
11
Remote control valve (arm, swing)
17
Swing spool
6
Check valve
12
Right swing
18
Swing brake solenoid
This control suppresses swing speed increase caused by increased pump flow. (Only in H and SP modes) When an independent swing operation is carried out, the main computer (8) receives electrical signals from the swing pilot pressure sensor (14) and P1 pressure sensor (15) and outputs an electrical signal to the P1 flow control proportional valve (16). The discharge oil from A3 of the hydraulic pump (1) is fed to the P1 flow control proportional valve (16). The electrical signal output from the main computer (8) to the P1 flow control proportional valve (16) reduces the discharge flow on A1 of the hydraulic pump (1). The control is canceled when a compound operation is performed.
10
Swing Relief Cut Control Circuit
Tr1
LEFT
A
RIGHT
MU
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2
9
B
CCW par2
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
ELEVATOR UP pbr1
2
GB
29.4MPa at 350L/min
GA
DOWN par1
T3
ps1
T4
DR2h
T1 T2
DR1h
13
Dr
2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
pdp A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(1)
250.0cm 3/rev
ARM(2)
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
Au
pap pgb
pc3 ARM 1 SUB CONTROL
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
17
BOOM(2)
P
B8
BOOM(1)
pb4 DOWN
DOWN pb8 UP pa8
pa4 UP
B3
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
A3 LEFT
B7 A7
BUCKET
CLOSE pb7
pb3
RIGHT
6
OPEN pa7
pa3
B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
6
TRAVEL(R)
OPTION pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
7
P4
14
B1 A1
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
TRAVEL STRAIGHT
pst
10 Q
I
K
C
A
E
G
M
PN
O
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
P1
T
PH
P2
15
R
J RIGHT
L
PB
LEFT
IN
D
B
PD
PF
OUT
UP
F
H
PH
N
PP
P
(FRONT)
Psv1
a1
DOWN CLOSE
OPEN
A1
A2
a2
Psv2
(REAR)
8 3
11
P1
5
D1
C2 P
T
18 C3 2-STAGE RELIEF
CENTER CUT C12
ARM IN
SWING OUT
2
4
LEFT 3
C1
16
M
a5
A3 a3
Dr
2-STAGE TRAVEL
1
RIGHT
B1
1
B3 OUT
12 38C9C112
4
P0
IN
Dr3
11 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
7
Oil cooler
13
Swing motor relief valve
2
Control valve
8
Main computer
14
Swing pilot pressure sensor
3
5-stack solenoid valve
9
Swing motor
15
P1 pressure sensor
4
Lever lock solenoid valve
10
Cushion valve
16
P1 flow control proportional valve
5
Console lever lock switch
11
Remote control valve (arm, swing)
17
Swing spool
6
Check valve
12
Right swing
18
Swing brake solenoid
When an independent abrupt swing operation is carried out, the starting pressure is boosted and the excess oil is ejected from the swing motor relief valve (13) to the tank line. This control provides an energy-saving effect by controlling the pump in such a way as to minimize the excess oil. As an example, this section explains the case in which the right swing operation is carried out. When a right swing operation starts, the main computer (8) receives electrical signals from the swing pilot pressure sensor (14) and P1 pressure sensor (15) and outputs an electrical signal to the P1 flow control proportional valve (16). The P1 flow control proportional valve (16) is controlled by the electrical signal output from the main computer (8) and the discharge flow on A1 of the hydraulic pump (1) is reduced. Also, the pilot pressure is controlled by an electrical signal input from the P1 pressure sensor (15) and the discharge flow on A1 of the hydraulic pump (1) increases gradually. The control is canceled when a compound operation is performed.
12
Swing Brake Circuit
LEFT
A
RIGHT
MU
B
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2
GB
29.4MPa at 350L/min
GA
CCW par2
19
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
13
ELEVATOR
2 Dr
UP pbr1
9
DOWN par1
T3
ps1
T4
DR2h
T1
T2
DR1h 2.55MPa at 30L/min
pga2
250.0cm3/rev
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
pdp A5
Au
39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(1)
P
ARM(2)
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
11
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
B8
BOOM(1)
BOOM(2)
P
pb4 DOWN
T
DOWN pb8
pa4 UP
UP pa8
B3
39.2MPa at 20L/min 39.2MPa at 20L/min
A3 LEFT
CLOSE pb7 OPEN pa7
pa3 B2 A2
17
SWING
2
4
1
3
7
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
LEFT
OUT
6
A7
BUCKET
RIGHT
ARM
6
B7
pb3
IN
pap pgb
pc3 ARM 1 SUB CONTROL
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4 B1 A1
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
TRAVEL STRAIGHT
pst
12 8
14
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
10
PH
P1
3 I
Q
K
A
C
E
G
M
PN
O
5
15
16 (FRONT)
T
P1
P2
1
Psv1
a1
A1
A2
a2
Psv2
(REAR)
D1
C2 R
J RIGHT
L
PB
LEFT
IN
B
D
PD
PF
OUT
UP
F
H
N
PH
PP
P
DOWN CLOSE
OPEN
C3
2-STAGE RELIEF
4
CENTER CUT
18
C12
C1
M
2-STAGE TRAVEL
a5
A3 a3
Dr
B1
B3 OUT
P0 IN 54EC05D5
Dr3
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13 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
8
Main computer
15
P1 pressure sensor
2
Control valve
9
Swing motor
16
P1 flow control proportional valve
3
5-stack solenoid valve
10
Cushion valve
17
Swing spool
4
Lever lock solenoid valve
11
Remote control valve (arm, swing)
18
Swing brake solenoid
5
Console lever lock switch
12
Right swing
19
Make-up check valve
6
Check valve
13
Swing motor relief valve
7
Oil cooler
14
Swing pilot pressure sensor
As an example, this section explains the case in which the brake circuit operation is carried out after the end of a right swing operation. When the remote control valve (11) is returned to neutral from the right swing side, the pilot pressure oil is cut off and the control valve (2) swing spool (17) returns to neutral. The pressure oil fed from Port A3 of the control valve (2) to Port B of the swing motor (9) is cut off. At the same time, the destination location is eliminated for the pressure oil flowing from Port A of the swing motor (9) to Port B3 of the control valve (2), so the pressure rises to the set pressure of the swing motor relief valve (13). The pressure generated here becomes a brake force and stops the swing motor (9). When the swing operation is stopped, since the swing motor (9) continues to rotate for a while due to inertia, the oil in the swing motor (9) falls short. In order to make up this shortfall, pressure oil is supplied from Port T3 of the control valve (2) through Port MU of the swing motor (9) and make-up check valve (19) to prevent cavitation.
14
Free Swing Circuit (when starting)
Tr1
20
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2
21
A
LEFT
A
RIGHT
MU
CCW par2
9
B
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
ELEVATOR UP pbr1
T
P
DOWN par1
GB
29.4MPa at 350L/min
GA
T3
ps1
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
pga2
13
Dr
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
pdp A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(2)
ARM(1)
250.0cm3/rev
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE
Au
ARM 2 SUB CONTROL
pap pgb
pc3 ARM 1 SUB CONTROL
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
P
BOOM(2)
B8
BOOM(1)
pb4 DOWN
DOWN pb8 UP pa8
pa4 UP
B3
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
A3 LEFT pb3
B7
CLOSE pb7
RIGHT
OPEN pa7
pa3 B2 A2
6
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
17
6
A7
BUCKET
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
7
P4
14
B1 A1
TRAVEL(L)
pb1 BACKWARD
10 Q
I
A
K
DR3p
pa1 FORWARD
C
G
E
M
PN
TRAVEL STRAIGHT
O
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
P1
T
pst
P2
PH
15
16
1
R
J RIGHT
8 L
PB
LEFT
IN
B
D
PD
PF
OUT
UP
F
H
N
PH
PP
19
(FRONT)
Psv1
a1
P
A1
A2
a2
Psv2
(REAR)
DOWN CLOSE
OPEN
3
5
11 P1 P
D1
C2 T
18
C3
2-STAGE RELIEF
M
CENTER CUT C12
a5
A3 a3
4 Dr
ARM IN 2
B1
SWING OUT
LEFT
RIGHT
4
3
1
C1
B3 OUT
2-STAGE TRAVEL
IN
12 P0 8019AACE
Dr3
15 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
8
Main computer
15
P1 pressure sensor
2
Control valve
9
Swing motor
16
P1 flow control proportional valve
3
5-stack solenoid valve
10
Cushion valve
17
Swing spool
4
Lever lock solenoid valve
11
Remote control valve (arm, swing)
18
Swing brake solenoid
5
Console lever lock switch
12
Right swing
19
Free swing switch
6
Check valve
13
Swing motor relief valve
20
Free swing solenoid valve
7
Oil cooler
14
Swing pilot pressure sensor
21
Orifice
Purpose Reduces the shock generated when a swing operation is started or stopped. Caution When the free swing is turned ON, the acceleration performance when starting a swing operation deteriorates. Also, the swing flow continues to increase even after the swing operation is stopped, therefore it takes longer to stop. Operation explanation When the free swing switch (19) is turned ON, the free swing solenoid valve (20) is switched by the electrical signal output from the main computer (8), connecting Port GA and Port GB of the swing motor (9) via the orifice (21). When the remote control valve (11) is operated to the right swing side, the pilot pressure oil is fed to Port Pa3 of the control valve (2) and switches the swing spool (17) to the right swing side. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the swing spool (17) via the parallel oil path. Switching the swing spool (17) lets the pressure oil flow into Port B of the swing motor (9) and the right swing operation is carried out. The pressure oil branched off inside the swing motor (9) flows into Port GA of the swing motor (9) through Port GB of the swing motor (9), the free swing solenoid valve (20), and the orifice (21) to reduce the shock generated when the swing operation starts. The return oil from Port GA of the swing motor (9) returns to the hydraulic tank through Port A of the swing motor (9) and the swing spool (17).
16
Free Swing Circuit (when stopping)
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
20
2ND OPTION CW pbr2
13 LEFT
21
A
A
RIGHT
MU
9
CCW par2
B
T
P
ELEVATOR UP pbr1 DOWN par1
GB
29.4MPa at 350L/min
GA
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2 ps1
T3
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
Dr
CENTER CUT pcc
pga1
pdp A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(2)
ARM(1) pb5 OUT
OUT pb9
pa5 IN
IN pa9
250.0cm3/rev
par ARM REGENERATIVE
Au
ARM 2 SUB CONTROL
pap pgb
pc3 ARM 1 SUB CONTROL
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
P
BOOM(2)
B8
BOOM(1)
pb4 DOWN
DOWN pb8 UP pa8
pa4 UP
B3 A3 LEFT
39.2MPa at 20L/min 39.2MPa at 20L/min
B7
CLOSE pb7
pb3 RIGHT
OPEN pa7
pa3 B2 A2
6
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
17
6
A7
BUCKET
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
7
P4
14
B1 A1
TRAVEL(L)
pb1 BACKWARD
10 Q
I
A
K
DR3p
pa1 FORWARD
C
G
E
M
PN
TRAVEL STRAIGHT
O
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
PH
P1
T
pst
P2
1
15
16 R
J RIGHT
8 L
PB
LEFT
IN
B
D
PD
PF
OUT
UP
F
H
N
PH
PP
19
(FRONT)
Psv1
a1
P
A1
A2
a2
Psv2
(REAR)
DOWN CLOSE
OPEN
3
5
11 P1 P
D1
C2 T
18
C3
2-STAGE RELIEF
M
CENTER CUT C12
a5
A3 a3
4 Dr
ARM IN 2
B1
SWING OUT
LEFT
RIGHT
4
3
1
C1
B3 OUT
2-STAGE TRAVEL
IN
12 P0 5778D685
Dr3
17 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
8
Main computer
15
P1 pressure sensor
2
Control valve
9
Swing motor
16
P1 flow control proportional valve
3
5-stack solenoid valve
10
Cushion valve
17
Swing spool
4
Lever lock solenoid valve
11
Remote control valve (arm, swing)
18
Swing brake solenoid
5
Console lever lock switch
12
Right swing
19
Free swing switch
6
Check valve
13
Swing motor relief valve
20
Free swing solenoid valve
7
Oil cooler
14
Swing pilot pressure sensor
21
Orifice
Purpose Reduces the shock generated when a swing operation is started or stopped. Caution When the free swing is turned ON, the acceleration performance when starting a swing operation deteriorates. Also, the swing flow continues to increase even after the swing operation is stopped, therefore it takes longer to stop. Operation explanation When the free swing switch (19) is turned ON, the free swing solenoid valve (20) is switched by the electrical signal output from the main computer (8), connecting Port GA and Port GB of the swing motor (9) via the orifice (21). When the remote control valve (11) is returned to neutral from the right swing side, the pilot pressure oil is cut off and the control valve (2) swing spool (17) returns to neutral. The pressure oil fed from Port A3 of the control valve (2) to Port B of the swing motor (9) is cut off. At the same time, the destination location is eliminated for the pressure oil flowing from Port A of the swing motor (9) to Port B3 of the control valve (2), so the pressure rises to the set pressure of the swing motor relief valve (13) in the swing motor (9). The pressure oil that reached the set pressure opens the swing motor relief valve (13) and flows into Port B of the swing motor (9). Also, the pressure oil flows into Port GB through Port GA of the swing motor (9), the orifice (21), and the free swing solenoid valve (20) to reduce the shock generated when the swing operation is stopped. When the swing operation is stopped, since the swing motor (9) continues to rotate for a while due to inertia, the oil in the swing motor (9) falls short. In order to make up this shortfall, the pressure oil is supplied from Port T3 of the control valve (2) to Port MU of the swing motor (9) to prevent cavitation.
18
Swing Parking Circuit (lever in neutral)
LEFT
A
9
RIGHT
MU
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
B
2ND OPTION CW pbr2 CCW par2
GB
29.4MPa at 350L/min
GA
11
ELEVATOR UP pbr1 DOWN par1
13
Dr
P
19
T
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2 ps1
T3
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
250.0cm3/rev
pdp A5
ARM
ARM(1)
SWING
IN
OUT 2
LEFT
4
RIGHT
P
1
3
39.2MPa at 20L/min 39.2MPa at 20L/min
B5
Au
ARM(2)
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
pap pgb
pc3 ARM 1 SUB CONTROL
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
12
B8
BOOM(1)
BOOM(2) pb4 DOWN
DOWN pb8
pa4 UP
14
UP pa8
B3
39.2MPa at 20L/min 39.2MPa at 20L/min
Q
RIGHT
OPEN pa7
pa3 B2 A2
K
A7 CLOSE pb7
pb3
10 I
B7
BUCKET
A3 LEFT
A
C
G
E
M
PN
O
TRAVEL(R)
OPTION
17
T
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4 B1 A1
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
R
J RIGHT
L
PB
LEFT
IN
B
D
PD
PF
OUT
UP
F
PH
H
N
PP
TRAVEL STRAIGHT
P
DOWN CLOSE
OPEN
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
3 P1
D1
5
16
6
PH
P1
P2
6 1
15 (FRONT)
Psv1
a1
A1
A2
a2
Psv2
(REAR)
C2
8 18
C3
2-STAGE RELIEF
CENTER CUT C12
20 C1
2-STAGE TRAVEL
4
M
a5
A3 a3
Dr
P0
B1
B3 OUT
IN 2BA86E16
pst
Dr3
7
19 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
8
Main computer
15
P1 pressure sensor
2
Control valve
9
Swing motor
16
P1 flow control proportional valve
3
5-stack solenoid valve
10
Cushion valve
17
Swing spool
4
Lever lock solenoid valve
11
Remote control valve (arm, swing)
18
Swing brake solenoid
5
Console lever lock switch
12
Right swing
19
Make-up check valve
6
Check valve
13
Swing motor relief valve
20
Key switch
7
Oil cooler
14
Swing pilot pressure sensor
When the key switch (20) is turned ON, the swing brake solenoid (18) is switched by the electrical signal from the main computer (8). The pressure oil from Port P of the swing motor (9) returns to the hydraulic tank through Port C2 of the 5-stack solenoid valve (3) and the swing brake solenoid (18) to hold the swing parking brake.
20
Swing Parking Circuit (brake release)
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2 CCW par2
LEFT
A
RIGHT
MU
9
B
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
ELEVATOR UP pbr1 DOWN par1
GB
29.4MPa at 350L/min
GA
T3
ps1
T4
DR2h
T1
T2
DR1h 2.55MPa at 30L/min
pga2
13
Dr
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
pdp A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(2)
ARM(1)
250.0cm3/rev
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
Au
pap pgb
pc3 ARM 1 SUB CONTROL
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
P
B8
BOOM(1)
BOOM(2) pb4 DOWN
DOWN pb8 UP pa8
pa4 UP
B3
39.2MPa at 20L/min 39.2MPa at 20L/min
B7
CLOSE pb7
pb3
RIGHT
OPEN pa7
pa3 B2 A2
6
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
17
6
A7
BUCKET
A3 LEFT
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
7
P4
14
B1 A1
TRAVEL(L)
pb1 BACKWARD
10 Q
I
A
K
DR3p
pa1 FORWARD
C
G
E
M
PN
TRAVEL STRAIGHT
O
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
PH
P1
T
pst
P2
R
RIGHT
L
PB
LEFT
IN
B
D
PD
PF
OUT
UP
F
H
N
PH
PP
P
DOWN
(FRONT)
CLOSE
1
15
16 J
Psv1
a1
A1
A2
a2
Psv2
(REAR)
OPEN
3 P1
11
5
D1
C2 P
8
T
18
C3
2-STAGE RELIEF
CENTER CUT C12
ARM IN 2
C1
SWING OUT
LEFT
RIGHT
4
3
1
M
a5
A3 a3
Dr
2-STAGE TRAVEL
B1
B3 OUT
12 63AFB779
4
P0
IN
Dr3
21 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
7
Oil cooler
13
Swing motor relief valve
2
Control valve
8
Main computer
14
Swing pilot pressure sensor
3
5-stack solenoid valve
9
Swing motor
15
P1 pressure sensor
4
Lever lock solenoid valve
10
Cushion valve
16
P1 flow control proportional valve
5
Console lever lock switch
11
Remote control valve (arm, swing)
17
Swing spool
6
Check valve
12
Right swing
18
Swing brake solenoid
As an example, this section explains the case in which the right swing operation is carried out. When the swing lever is in neutral after the engine is started, the swing brake solenoid (18) comes ON and the pressure oil to Port P of the swing motor (9) is cut off. The swing parking brake is being applied. When the remote control valve (11) is operated to the right swing side, the pilot pressure oil is fed to Port pa3 of the control valve (2) via the cushion valve (10) and switches the swing spool (17) to the right swing side. At the same time, the main computer (8) detects the electrical signal from the swing pilot pressure sensor (14) and judges that a swing operation is being performed. The electrical signal output from the main computer (8) goes OFF to switch the swing brake solenoid (18). The pilot pressure oil is fed to Port P of the swing motor (9) via Port C2 of the 5-stack solenoid valve (3) to release the swing parking brake. The discharge oil from A1 of the hydraulic pump (1) flows into Port B of the swing motor (9) through Port P1 of the control valve (2), the parallel oil path, and the swing spool (17), and the right swing operation is carried out. The pressure oil that passed through the swing motor (9) returns to the hydraulic tank through Port A and swing spool (17). When this is followed by an attachment operation, the pilot pressure is detected by respective pressure sensors and the swing parking brake continues to be released. After the swing operation ends, if about 5 sec. pass with no upper operation, the electrical signal output from the main computer (8) to the swing brake solenoid (18) turns ON and the swing parking brake is applied again. When an upper operation is carried out after the swing operation, the swing parking brake is applied again about 1 sec. after the end of the upper operation. When an independent upper operation is carried out, the swing parking brake is released. Also, the swing parking brake is applied again about 1 sec. after the end of the upper operation. KEY SWITCH OFF ON ON
Swing pilot pressure sensor OFF OFF Higher than specified pressure
ON
OFF
ON
Higher than specified pressure
Attachment pilot pressure sensors OFF OFF
Swing brake solenoid valve OFF ON
Swing motor mechanical brake ON ON
OFF
OFF
OFF
OFF
OFF
OFF
OFF
Higher than specified pressure Higher than specified pressure
CLICK HERE TO
DOWNLOAD THE COMPLETE MANUAL
• Thank you very much for reading the preview of the manual. • You can download the complete manual from: www.heydownloads.com by clicking the link below
• Please note: If there is no response to CLICKING the link, please download this PDF first and then click on it.
CLICK HERE TO
DOWNLOAD THE COMPLETE MANUAL
22
Swing Parking Circuit (machine stop)
LEFT
A
9
RIGHT
MU
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
B
2ND OPTION CW pbr2 CCW par2
GB
29.4MPa at 350L/min
GA
11
ELEVATOR UP pbr1 DOWN par1
13
Dr
P
19
T
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2 ps1
T3
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
250.0cm3/rev
pdp A5
ARM
ARM(1)
SWING
IN
OUT 2
LEFT
4
RIGHT
P
1
3
39.2MPa at 20L/min 39.2MPa at 20L/min
B5
Au
ARM(2)
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
pap pgb
pc3 ARM 1 SUB CONTROL
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
12
B8
BOOM(1)
BOOM(2) pb4 DOWN
DOWN pb8
pa4 UP
14
UP pa8
B3
39.2MPa at 20L/min 39.2MPa at 20L/min
Q
RIGHT
OPEN pa7
pa3 B2 A2
K
A7 CLOSE pb7
pb3
10 I
B7
BUCKET
A3 LEFT
A
C
G
E
M
PN
O
TRAVEL(R)
OPTION
17
T
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4 B1 A1
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
R
J RIGHT
L
PB
LEFT
IN
B
D
PD
PF
OUT
UP
F
PH
H
N
PP
TRAVEL STRAIGHT
P
DOWN CLOSE
OPEN
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
3 P1
D1
5
16
6
PH
P1
P2
6 1
15 (FRONT)
Psv1
a1
A1
A2
a2
Psv2
(REAR)
C2
8 18
C3
2-STAGE RELIEF
CENTER CUT C12
20 C1
2-STAGE TRAVEL
4
M
a5
A3 a3
Dr
P0
B1
B3 OUT
IN 2BA86E16
pst
Dr3
7
23 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
8
Main computer
15
P1 pressure sensor
2
Control valve
9
Swing motor
16
P1 flow control proportional valve
3
5-stack solenoid valve
10
Cushion valve
17
Swing spool
4
Lever lock solenoid valve
11
Remote control valve (arm, swing)
18
Swing brake solenoid
5
Console lever lock switch
12
Right swing
19
Make-up check valve
6
Check valve
13
Swing motor relief valve
20
Key switch
7
Oil cooler
14
Swing pilot pressure sensor
When the machine is stopped (with the key switch OFF), the pressure oil from Port P of the swing motor (9) returns to the hydraulic tank through the swing brake solenoid (18). The swing parking brake stays applied.
24
Boom Circuit Boom-up Circuit (for independent operation) (with HBCV)
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2
10
CCW par2
2
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
ELEVATOR UP pbr1 DOWN par1
ps1
T3
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
pga2
9
P3 ps2
2.55MPa at 30L/min
G1
pga1
(G3)
B A
C
CENTER CUT pcc
B A
(G3)
G1 C
pdp A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
PL ARM(2)
ARM(1)
I
K
Q
A
E
C
G
M PN
O
PL
pb5 OUT
OUT pb9
pa5 IN
IN pa9
DR
DR
T par ARM REGENERATIVE ARM 2 SUB CONTROL
12
R J
RIGHT
L
PB
LEFT
IN
B
D
PF
PD
F
H
N
PH
PP
A8 B8
39.2MPa at 20L/min 27.4MPa at 280L/min
P
OUT
pb4 DOWN
CLOSE
OPEN
DOWN pb8
pa4 UP
UP
B3 A3
19
CLOSE pb7
pa3 RIGHT
OPEN pa7
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4
P1
P2
P3 B1 A1
T
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
BOOM
A1
11
A7
BUCKET
pb3 LEFT
B2 A2
20
pa8 B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
18
pap pgb
pc3 ARM 1 SUB CONTROL
ARM A2
TRAVEL STRAIGHT
pst
EV A3 MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
PH
P1
P2
13
6 P1
P
T
C2
4
D1
SWING BRAKE
5 C3
2-STAGE RELIEF
16
7
17
CENTER CUT C12
A1 BOOM
GRAPPLE CLOSE
4
2
1
OPEN C1
3
2-STAGE TRAVEL
1 14 C68D10D6
15
3
P0
A2
A3
6
25 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
8
Main computer
15
Boom (down)
2
Control valve
9
Cushion valve
16
P1 pressure sensor
3
5-stack solenoid valve
10
Boom cylinder
17
P2 pressure sensor
4
Lever lock solenoid valve
11
Boom [1] spool
18
Boom-up pilot pressure sensor
5
Console lever lock switch
12
Boom [2] spool
19
Boom-down pilot pressure sensor
6
Check valve
13
Remote control valve (boom, bucket)
20
3-stack proportional valve
7
Oil cooler
14
Boom (up)
When the remote control valve (13) is operated to the boom-up side, the pilot pressure oil is fed to Port pa8 and Port pa4 of the control valve (2) via the cushion valve (9) and 3-stack proportional valve (20), and switches the boom [1] spool (11) and boom [2] spool (12) to the up side. The pressure oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the boom [2] spool (12) via the parallel oil path. The pressure oil from A2 of the hydraulic pump (1) is fed to the boom [1] spool (11) via the parallel oil path. The pressure oil that passed through the boom [1] spool (11) merges with the pressure oil that passed through the boom [2] spool (12) downstream of the spool and flows into the boom cylinder (10) bottom side, and the boom-up operation is carried out. The return oil on the boom cylinder (10) rod side returns to the hydraulic tank through the boom [1] spool (11).
26
Boom-down Regenerative Circuit (with HBCV)
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
10
10
2ND OPTION CW pbr2 CCW par2
2
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
ELEVATOR UP pbr1 DOWN par1
ps1
13
T3
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
G1
CENTER CUT pcc
pga1
P
ARM(2)
pb5 OUT
OUT pb9
pa5 IN
IN pa9
PL PL
20
DR
par ARM REGENERATIVE ARM 2 SUB CONTROL
4
CLOSE
2
1
pgb
pc3 ARM 1 SUB CONTROL
OPEN 3
A8 B8 DOWN pb8
39.2MPa at 20L/min 27.4MPa at 280L/min
pa4 UP
14
UP pa8
15 39.2MPa at 20L/min 39.2MPa at 20L/min
B3 A3 SWING
9 12 Q
K
C
A
DR
pap
GRAPPLE DOWN
pb4 DOWN
I
C
39.2MPa at 20L/min 39.2MPa at 20L/min
ARM(1)
BOOM
G1
B A
B A
A5 B5
UP
(G3)
(G3)
C
pdp
T
OPEN pa7
11
A8
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
O
TRAVEL(R)
OPTION
T
A7 CLOSE pb7
pa3 RIGHT B2 A2
G M PN
E
B7
BUCKET
pb3 LEFT
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
B8
P4 B1 A1
DOWN
TRAVEL(L)
pb1 BACKWARD
R
pa1 FORWARD
J
RIGHT
L
PB
LEFT
IN
B
D
PD
PF
F
H
PH
N
PP
TRAVEL STRAIGHT
pst
P
OUT CLOSE
21
OPEN
PH
P2
6
19
7
5 P1 C2
SWING BRAKE
C3
2-STAGE RELIEF
D1
17
16
1 4
CENTER CUT C12
C1
2-STAGE TRAVEL
3 P0 524B3509
22
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
P1
18
pb8
DR3p
A1
A2
A3
6
27 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
9
Cushion valve
17
P2 pressure sensor
2
Control valve
10
Boom cylinder
18
Boom-up pilot pressure sensor
3
5-stack solenoid valve
11
Boom [1] spool
19
Boom-down pilot pressure sensor
4
Lever lock solenoid valve
12
Boom [2] spool
20
Boom load holding valve check valve
5
Console lever lock switch
13
Remote control valve (boom, bucket)
21
Regeneration orifice
6
Check valve
14
Boom (up)
22
Check valve
7
Oil cooler
15
Boom (down)
8
Main computer
16
P1 pressure sensor
When the remote control valve (13) is operated to the boom-down side, the pilot pressure oil is fed to Port pb8 of the control valve (2) via the cushion valve (9) and switches the boom [1] spool (11). The pressure oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2) and is fed to the boom [1] spool (11) via the parallel oil path. The pressure oil fed to the boom [1] spool (11) flows into the boom cylinder (10) rod side, and the boom-down operation is carried out. The pressure oil on the boom cylinder (10) bottom side returns to the hydraulic tank through the boom load holding valve check valve (20) and boom [1] spool (11). At that time, the pressure oil is metered by the boom [1] spool (11) regeneration orifice (21) and pushes open the check valve (22) and is regenerated on the boom cylinder (10) rod side. The lower the load pressure on the boom cylinder (10) rod side, the greater the volume of regeneration. When the load pressure on the boom cylinder (10) rod side becomes high, the check valve (22) is closed and the return oil on the boom cylinder (10) bottom side returns to the hydraulic tank through the boom [1] spool (11) without regeneration.
28
Boom-down Load Holding Valve Circuit
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
10
10
2ND OPTION CW pbr2 CCW par2
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
ELEVATOR UP pbr1 DOWN par1
T3
ps1
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
pdp A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(1)
20
ARM(2)
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
pgb
pc3 ARM 1 SUB CONTROL
9
A8 B8 DOWN pb8
39.2MPa at 20L/min 27.4MPa at 280L/min
pb4 DOWN I
K
Q
A
C
G M PN
E
pa4 UP
O
UP pa8 39.2MPa at 20L/min 39.2MPa at 20L/min
B3 A3
T
12
pap
SWING
B7
11
A7 CLOSE pb7
BUCKET
pb3 LEFT pa3 RIGHT
OPEN pa7
R J
RIGHT
L
PB
LEFT
IN
B
D
PD
PF
OUT
UP
F
H PH
N
DOWN CLOSE
B2 A2
PP P
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
OPEN
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4 B1 A1
TRAVEL(L)
pb1 BACKWARD
18
19
DR3p
pa1 FORWARD
TRAVEL STRAIGHT
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
PH
P1
pst
P2
6 13 6 P1 P
T
C2
4
D1
5
SWING BRAKE
16
17
7 1
C3
2-STAGE RELIEF
CENTER CUT C12
A1 BOOM 4
2
14 E1456DA3
GRAPPLE CLOSE
OPEN
1
3
15
C1
2-STAGE TRAVEL
3
P0
A2
A3
29 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
8
Main computer
15
Boom (down)
2
Control valve
9
Cushion valve
16
P1 pressure sensor
3
5-stack solenoid valve
10
Boom cylinder
17
P2 pressure sensor
4
Lever lock solenoid valve
11
Boom [1] spool
18
Boom-up pilot pressure sensor
5
Console lever lock switch
12
Boom [2] spool
19
Boom-down pilot pressure sensor
6
Check valve
13
Remote control valve (boom, bucket)
20
Boom load holding valve check valve
7
Oil cooler
14
Boom (up)
When the remote control valve (13) boom operation lever is in neutral, the pressure oil on the boom cylinder (10) bottom side is sealed by the boom load holding valve check valve (20), reducing internal leakage from the boom [1] spool (11) to reduce the hydraulic drift of the boom.
30
Boom-up Interference Prevention Circuit (with HBCV)
13 P
Tr1
T
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2 CCW par2
BOOM 2
4
UP pbr1
3
1
DOWN par1
ps1
14
15
K
T4
DR2h
T1 T2
2.55MPa at 30L/min
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
E
C
A
T3
DR1h pga2
Q
10
ELEVATOR
9
I
10
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
GRAPPLE CLOSE OPEN
G
M PN
pdp
O
A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
T
ARM(1)
ARM(2)
G1 OUT pb9
pb5 OUT
(G3)
B A
C
IN pa9
pa5 IN
B A
(G3)
G1 C
par ARM REGENERATIVE
R J
RIGHT
L
PB
LEFT
IN
B
D
PF
PD
PL ARM 2 SUB CONTROL
F
H
PH
N
PP
P
OUT
pb4 DOWN
DOWN pb8
pa4 UP
19
UP
B3 A3
pa3 RIGHT
OPEN pa7
B2 A2
P1
P2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
P3
TRAVEL(R)
OPTION
T
11
A7 CLOSE pb7
BUCKET
pb3 LEFT
12
pa8 B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
20
DR
A8 B8
OPEN 39.2MPa at 20L/min 27.4MPa at 280L/min
18
DR
pgb
pc3 ARM 1 SUB CONTROL
CLOSE
PL
pap
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4 B1 A1
TRAVEL(L)
pb1 BACKWARD
BOOM
ARM A2
A1
EV
DR3p
pa1 FORWARD
A3
TRAVEL STRAIGHT
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
26 22 23
P1 C2
4
D1
PH
P1
6 P2
5
SWING BRAKE
7 16
8 C3
2-STAGE RELIEF
17 1
CENTER CUT C12
24 25
C1
A1
2-STAGE TRAVEL
21 3 P0
91F73584
pst
A2
A3
6
31 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
10
Boom cylinder
19
Boom-down pilot pressure sensor
2
Control valve
11
Boom [1] spool
20
3-stack proportional valve
3
5-stack solenoid valve
12
Boom [2] spool
21
Computer C
4
Lever lock solenoid valve
13
Remote control valve (boom, bucket)
22
Angle sensor (bucket)
5
Console lever lock switch
14
Boom (up)
23
Angle sensor (arm)
6
Check valve
15
Boom (down)
24
Angle sensor (boom)
7
Oil cooler
16
P1 pressure sensor
25
Angle sensor (EV)
8
Main computer
17
P2 pressure sensor
26
Monitor display
9
Cushion valve
18
Boom-up pilot pressure sensor
Boom up When the remote control valve (13) is operated to the boom-up side, the pilot pressure oil is fed to Port pa8 and Port pa4 of the control valve (2) via the cushion valve (9) and 3-stack proportional valve (20), and switches the boom [1] spool (11) and boom [2] spool (12) to the up side. The pressure oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the boom [2] spool (12) via the parallel oil path. The pressure oil from A2 of the hydraulic pump (1) is fed to the boom [1] spool (11) via the parallel oil path. The pressure oil that passed through the boom [1] spool (11) merges with the pressure oil that passed through the boom [2] spool (12) downstream of the spool and flows into the boom cylinder (10) bottom side, and the boom-up operation is carried out. The return oil on the boom cylinder (10) rod side returns to the hydraulic tank through the boom [1] spool (11). Interference prevention Computer C (21) detects the positions of the attachment and elevator cab by electrical signals from the angle sensors (22) (23) (24) (25). When the cab and end attachment come closer to each other during a boom-up operation, the main computer (8) stops the boom by closing the opening of the 3-stack proportional valve (20). When a sensor abnormality or electrical circuit abnormality occurs, computer C (21) sends an electrical signal to the main computer (8) to operate the lever lock solenoid valve (4) and stop all the operations. Also, a message is displayed on the monitor display (26) and the warning buzzer sounds at the same time. Note that cushioning performance can be adjusted by adjusting the output current or control angle on the service support screen.
32
Boom-up End Shock Reduction Circuit (with HBCV)
13 P
Tr1
T
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2 CCW par2
BOOM 2
4
UP pbr1
3
1
DOWN par1
ps1
14
15
K
T4
DR2h
T1 T2
2.55MPa at 30L/min
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
E
C
A
T3
DR1h pga2
Q
10
ELEVATOR
9
I
10
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
GRAPPLE CLOSE OPEN
G
M PN
pdp
O
A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
T
ARM(1)
ARM(2)
G1 OUT pb9
pb5 OUT
(G3)
B A
C
IN pa9
pa5 IN
B A
(G3)
G1 C
par ARM REGENERATIVE
R J
RIGHT
L
PB
LEFT
IN
B
D
PF
PD
PL ARM 2 SUB CONTROL
F
H
PH
N
PP
P
OUT
pb4 DOWN
DOWN pb8
pa4 UP
19
UP
B3 A3
pa3 RIGHT
OPEN pa7
B2 A2
P1
P2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
P3
TRAVEL(R)
OPTION
T
11
A7 CLOSE pb7
BUCKET
pb3 LEFT
12
pa8 B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
20
DR
A8 B8
OPEN 39.2MPa at 20L/min 27.4MPa at 280L/min
18
DR
pgb
pc3 ARM 1 SUB CONTROL
CLOSE
PL
pap
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4 B1 A1
TRAVEL(L)
pb1 BACKWARD
BOOM
ARM A2
A1
EV
DR3p
pa1 FORWARD
A3
TRAVEL STRAIGHT
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
26 22 23
P1 C2
4
D1
PH
P1
6 P2
5
SWING BRAKE
7 16
8 C3
2-STAGE RELIEF
17 1
CENTER CUT C12
24 25
C1
A1
2-STAGE TRAVEL
21 3 P0
91F73584
pst
A2
A3
6
33 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
10
Boom cylinder
19
Boom-down pilot pressure sensor
2
Control valve
11
Boom [1] spool
20
3-stack proportional valve
3
5-stack solenoid valve
12
Boom [2] spool
21
Computer C
4
Lever lock solenoid valve
13
Remote control valve (boom, bucket)
22
Angle sensor (bucket)
5
Console lever lock switch
14
Boom (up)
23
Angle sensor (arm)
6
Check valve
15
Boom (down)
24
Angle sensor (boom)
7
Oil cooler
16
P1 pressure sensor
25
Angle sensor (EV)
8
Main computer
17
P2 pressure sensor
26
Monitor display
9
Cushion valve
18
Boom-up pilot pressure sensor
Boom up When the remote control valve (13) is operated to the boom-up side, the pilot pressure oil is fed to Port pa8 and Port pa4 of the control valve (2) via the cushion valve (9) and 3-stack proportional valve (20), and switches the boom [1] spool (11) and boom [2] spool (12) to the up side. The pressure oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the boom [2] spool (12) via the parallel oil path. The pressure oil from A2 of the hydraulic pump (1) is fed to the boom [1] spool (11) via the parallel oil path. The pressure oil that passed through the boom [1] spool (11) merges with the pressure oil that passed through the boom [2] spool (12) downstream of the spool and flows into the boom cylinder (10) bottom side, and the boom-up operation is carried out. The return oil on the boom cylinder (10) rod side returns to the hydraulic tank through the boom [1] spool (11). End shock reduction Computer C (21) detects the boom angle by electrical signals from the angle sensor (24). When the boom is raised close to the boom-up end, the main computer (8) gradually closes the opening of the 3-stack proportional valve (20). This decreases the boom-up speed and reduces the shock on the boom-up stroke end.
34
Arm Circuit Arm-in Circuit (with HBCV)
19
19
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION CW pbr2 CCW par2
G1
(G3)
B
(G3)
B
G1
C
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
20
2
C
ELEVATOR UP pbr1
A
A
21
PL
PL
DOWN par1
T3
ps1 DR
T4
DR2h
T1 T2
DR1h
DR
2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
pdp
A5 B5
39.2MPa at 20L/min 39.2MPa at 20L/min
OUT pb9
pb5 OUT
pa5 IN
IN
pa9
par ARM REGENERATIVE
9
17
ARM 2 SUB CONTROL
Q
I
A
K
C
G
E
M PN
39.2MPa at 20L/min 27.4MPa at 280L/min
T
B8
BOOM(1)
pb4 DOWN
DOWN pb8
pa4 UP
UP pa8
B3 A3
R
RIGHT
PB
LEFT
B
A7
BUCKET
pb3 LEFT D
PF
PD
UP
F
H
PH
N
DOWN CLOSE
CLOSE pb7
PP P
pa3 RIGHT
OPEN pa7
OPEN B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
22
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING L
15
18
A8
O
BOOM(2)
J
pap pgb
pc3 ARM 1 SUB CONTROL
16
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4
P2
P1
B1 A1
P3
TRAVEL(L)
pb1 BACKWARD
T
DR3p
pa1 FORWARD
BOOM
ARM
A1
TRAVEL STRAIGHT
EV
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
A3
A2
BOOST
PH
P1
pst
P2
12 4 P1 P
T
C2
SWING BRAKE
C3
2-STAGE RELIEF
5
D1
6
11
10
7 CENTER CUT
1
C12
ARM
2
LEFT
RIGHT
3
1
A1 C1
2-STAGE TRAVEL
3
13 F7FD1461
SWING 4
14
P0
A2
A3
6
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35 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
9
Cushion valve
17
Arm [1] spool
2
Control valve
10
P1 pressure sensor
18
Arm [2] spool
3
5-stack solenoid valve
11
P2 pressure sensor
19
Arm cylinder
4
Lever lock solenoid valve
12
Remote control valve (arm, swing)
20
Arm load holding valve check valve
5
Console lever lock switch
13
Arm (in)
21
Arm-in pressure sensor
6
Check valve
14
Arm (out)
22
3-stack proportional valve
7
Oil cooler
15
Arm-in pilot pressure sensor
8
Main computer
16
Arm-out pilot pressure sensor
When the remote control valve (12) is operated to the arm-in side, the pilot pressure oil is fed to Port pa5 and Port pa9 of the control valve (2) via the cushion valve (9) and 3-stack proportional valve (22) and switches the arm [1] spool (17) and arm [2] spool (18) to the in side. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the arm [1] spool (17) via the center bypass oil path. The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2) and is fed to the arm [2] spool (18) via the center bypass oil path. The merged pressure oil merges downstream of the spool and then flows into the arm cylinder (19) rod side through the arm load holding valve check valve (20), and the arm-in operation is carried out. The return oil on the arm cylinder (19) bottom side returns to the hydraulic tank through the arm [1] spool (17).
36
Arm Semi-parallel 1 Circuit (with HBCV)
19
19 Tr1
12
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION G1
P
(G3)
B
(G3)
B
G1
C
T
CW pbr2 CCW par2
C
A
A
ELEVATOR
2
UP pbr1
20
DR
DR
ps1
ARM
21
SWING LEFT
RIGHT
3
1
4
2
DOWN par1
T3
T4
DR2h
T1
T2
DR1h 2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
pdp
A5 B5 pb5 OUT
14
13
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
PL
PL
39.2MPa at 20L/min 39.2MPa at 20L/min
OUT
pb9
IN pa9
pa5 IN par ARM REGENERATIVE
9 17 I
Q
C
A
K
E
G
M PN
ARM 2 SUB CONTROL
pc3 ARM 1 SUB CONTROL
O
pap
18
pgb A8 39.2MPa at 20L/min 27.4MPa at 280L/min
T
B8
BOOM(1)
BOOM(2) pb4 DOWN
DOWN pb8
24
UP pa8
pa4 UP R
B3 A3 J
RIGHT
L
PB
D
B
LEFT
PD
PF
F
H
UP
PH
N
PP
CLOSE pb7
pa3 RIGHT
OPEN
OPEN pa7
B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
15
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4
8
16
A7
BUCKET
pb3 LEFT
DOWN CLOSE
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
P
B1 A1
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
A
B
BUCKET CLOSE-CONT
C
TRAVEL STRAIGHT
D
ARM 2 SUB-CONT
pst
22
F
E
ARM REGENE
TRAVEL STRAIGHT
BOOM REGENE MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
P1
PH
P1
P2
6
A1 T1
P1
23 C2
SWING BRAKE
C3
2-STAGE RELIEF
D1
11
10
5
4
7
CENTER CUT C12
A1
3 C1
2-STAGE TRAVEL
1 P0 585C2883
A2
A3
6
37 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
9
Cushion valve
17
Arm [1] spool
2
Control valve
10
P1 pressure sensor
18
Arm [2] spool
3
5-stack solenoid valve
11
P2 pressure sensor
19
Arm cylinder
4
Lever lock solenoid valve
12
Remote control valve (arm, swing)
20
Arm load holding valve check valve
5
Console lever lock switch
13
Arm (in)
21
Arm-out pressure sensor
6
Check valve
14
Arm (out)
22
6-stack pressure reducing valve
7
Oil cooler
15
Arm-in pilot pressure sensor
23
Arm semi-parallel [1] spool control
8
Main computer
16
Arm-out pilot pressure sensor
24
Arm semi-parallel [1] spool
Purpose Reduces the pressure drops while the oil flows into the arm via the P1 parallel path (mainly during a compound operation). Secures swing pressure for arm + swing compound operation. Independent operation (ex.: arm-out operation) When the remote control valve (12) is operated to the arm-out side, the pilot pressure oil is fed to Port pb5 and Port pb9 of the control valve (2) via the cushion valve (9) and switches the arm [1] spool (17) and arm [2] spool (18) to the out side. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the arm [1] spool (17) via the center bypass oil path. At the same time, the oil is fed to the arm [1] spool (17) via the parallel oil path and arm semi-parallel [1] spool (24). The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2), is fed to the arm [2] spool (18) via the center bypass oil path and merges downstream of the arm [1] spool (17). The merged pressure oil flows into the arm cylinder (19) bottom side, and the arm-out operation is carried out. The return oil on the arm cylinder (19) rod side returns to the hydraulic tank through the arm [1] spool (17). The main computer (8) sends an electrical signal to the arm semi-parallel [1] spool control (23) and changes the opening of the arm semi-parallel [1] spool (24) according to the pilot pressure during an arm operation to control the flow volume to the arm [1] spool (17).
38
Arm Semi-parallel 1 Circuit (for compound operation) (ex.: arm-out + right swing operations) (with HBCV) 12 P
19
19 Tr1
T
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION G1
(G3)
B
B
(G3)
CW pbr2
G1
C
CCW par2
C
A
A PL
PL
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
ELEVATOR UP pbr1
ARM
SWING
20
DR
DR
4
2
1
3
21 14
25
T3
ps1
T4
DR2h
T1 T2
DR1h 2.55MPa at 30L/min
pga2
13
DOWN par1
P3 ps2
2.55MPa at 30L/min
pga1
26
CENTER CUT pcc
pdp
A5 B5 pb5 OUT
27
39.2MPa at 20L/min 39.2MPa at 20L/min
OUT
pb9
IN pa9
pa5 IN par ARM REGENERATIVE
9
17 Q
I
C
A
K
E
G
M PN
ARM 2 SUB CONTROL
pc3 ARM 1 SUB CONTROL
O
pap
18
pgb A8 39.2MPa at 20L/min 27.4MPa at 280L/min
T
RIGHT
LEFT
A
MU
pb4 DOWN
B8
BOOM(1)
BOOM(2)
B
DOWN pb8
24
pa4 UP
RIGHT
J
L
PB
B
LEFT
D
PD
PF
F
PH
H
UP
PP
29.4MPa at 350L/min
GA
P
GB
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
28
A3 LEFT
DOWN
A7
BUCKET
CLOSE pb7
pb3
CLOSE
16
15
N
UP pa8
B3
R
RIGHT
OPEN
OPEN pa7
pa3
Dr
B2 A2
29 250.0cm3/rev
TRAVEL(R)
OPTION pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4 Au
8
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
B1 A1
TRAVEL(L)
pb1 BACKWARD
22 A
B
BUCKET CLOSE-CONT
C
TRAVEL STRAIGHT
D
ARM 2 SUB-CONT
TRAVEL STRAIGHT
pst
F
E
ARM REGENE
DR3p
pa1 FORWARD
P
BOOM REGENE MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
P1
PH
P1
P2
6
A1 T1
P1
23 C2
SWING BRAKE
C3
2-STAGE RELIEF
D1
4
11
10
5
7
CENTER CUT C12
A1 C1
3
2-STAGE TRAVEL
1 P0 67F04378
A2
A3
6
39 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
11
P2 pressure sensor
21
Arm-out pressure sensor
2
Control valve
12
Remote control valve (arm, swing)
22
6-stack pressure reducing valve
3
5-stack solenoid valve
13
Arm (in)
23
Arm semi-parallel [1] spool control
4
Lever lock solenoid valve
14
Arm (out)
24
Arm semi-parallel [1] spool
5
Console lever lock switch
15
Arm-in pilot pressure sensor
25
Left swing
6
Check valve
16
Arm-out pilot pressure sensor
26
Right swing
7
Oil cooler
17
Arm [1] spool
27
Swing pilot pressure sensor
8
Main computer
18
Arm [2] spool
28
Swing spool
9
Cushion valve
19
Arm cylinder
29
Swing motor
10
P1 pressure sensor
20
Arm load holding valve check valve
Purpose Reduces the pressure drops while the oil flows into the arm via the P1 parallel path (mainly during a compound operation). Secures swing pressure for arm + swing compound operation. Compound operation (ex.: arm-out + right swing operations) When the remote control valve (12) is operated to the arm-out side, the pilot pressure oil is fed to Port pb5 and Port pb9 of the control valve (2) via the cushion valve (9) and switches the arm [1] spool (17) and arm [2] spool (18) to the out side. When the remote control valve (12) is operated to the right swing side, the pilot pressure oil is fed to Port pa3 of the control valve (2) via the cushion valve (9) and switches the swing spool (28) to the right swing side. The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2), is fed to the arm [2] spool (18) via the center bypass oil path and merges with the pressure oil from A1 of the hydraulic pump (1) downstream of the arm [1] spool (17). The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the swing spool (28) via the parallel oil path. At the same time, the oil is fed to the arm [1] spool (17) via the arm semi-parallel [1] spool (24). The pressure oil fed to the arm [1] spool (17) merges with the pressure oil from the arm [2] spool (18) and flows into the arm cylinder (19) bottom side, and the arm-out operation is carried out. The pressure oil fed to the swing spool (28) flows into Port B of the swing motor (29) and the right swing operation is carried out. The main computer (8) sends an electrical signal to the arm semi-parallel [1] spool control (23) and changes the opening of the arm semi-parallel [1] spool (24) according to the pilot pressure during an arm operation to control the flow volume to the arm [1] spool (17). When an arm operation and swing operation are carried out at the same time and the pilot pressure during the arm operation is high, swing operation pressure is secured by metering the arm semi-parallel [1] spool (24) opening to increase the flow to the swing motor (29). Also for a swing press digging operation, pressure is secured with the same control.
40
Arm Semi-parallel 2 Circuit (for independent operation) (with HBCV)
19
19
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
12
2ND OPTION CW pbr2
(G3)
G1
P
T
B
(G3)
B
CCW par2
G1
C
C
2
PL
PL
ELEVATOR UP pbr1
20 DR
DR
ps1
21 ARM LEFT
RIGHT
pga2
3
1
pga1
4
T3
T4
DR2h
T1
T2
2.55MPa at 30L/min
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pdp
A5 B5 pb5 OUT
14
13
DOWN par1
DR1h
SWING
2
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
A
A
39.2MPa at 20L/min 39.2MPa at 20L/min
OUT
par ARM REGENERATIVE
9 Q
C
A
K
E
G
M PN
18
24
17 I
ARM 2 SUB CONTROL
pap pgb
pc3 ARM 1 SUB CONTROL
O
pb9
IN pa9
pa5 IN
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
T
B8
BOOM(1)
BOOM(2) pb4 DOWN
DOWN pb8 UP pa8
pa4 UP R
B3 A3 J
RIGHT
L
PB
D
B
PD
F
PF
LEFT
H
UP
PP
CLOSE
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
P
A7
BUCKET
pb3 LEFT
DOWN
16
15
N
PH
CLOSE pb7
pa3 RIGHT
OPEN
OPEN pa7
B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
8
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4 B1 A1
TRAVEL(L)
pb1 BACKWARD A
C
B
BUCKET CLOSE-CONT
TRAVEL STRAIGHT
D
E
ARM REGENE
22
F
BOOM REGENE
ARM 1 SUB-CONT
DR3p
pa1 FORWARD
TRAVEL STRAIGHT
6
P1 A1
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
P1
T1
P2
PH
7
23 11
10 P1 C2
D1
4
SWING BRAKE
5 C3
2-STAGE RELIEF
CENTER CUT C12
C1
A1
3
2-STAGE TRAVEL
1 P0 F21B8980
pst
A2
A3
6
41 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
9
Cushion valve
17
Arm [1] spool
2
Control valve
10
P1 pressure sensor
18
Arm [2] spool
3
5-stack solenoid valve
11
P2 pressure sensor
19
Arm cylinder
4
Lever lock solenoid valve
12
Remote control valve (arm, swing)
20
Arm load holding valve check valve
5
Console lever lock switch
13
Arm (in)
21
Arm-out pressure sensor
6
Check valve
14
Arm (out)
22
6-stack pressure reducing valve
7
Oil cooler
15
Arm-in pilot pressure sensor
23
Arm semi-parallel [2] spool control
8
Main computer
16
Arm-out pilot pressure sensor
24
Arm semi-parallel [2] spool
Purpose Reduces the pressure drops while the oil flows into the arm via the P2 parallel path (mainly during a compound operation). Secures pressure for arm + boom compound operation. Independent operation (ex.: arm-out operation) When the remote control valve (12) is operated to the arm-out side, the pilot pressure oil is fed to Port pb5 and Port pb9 of the control valve (2) via the cushion valve (9) and switches the arm [1] spool (17) and arm [2] spool (18) to the out side. The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2) and is fed to the arm [2] spool (18) via the center bypass oil path. At the same time, the oil is fed to the arm [2] spool (18) via the parallel oil path and arm semi-parallel [2] spool (24). The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2), is fed to the arm [1] spool (17) via the center bypass oil path and merges with the pressure oil from the arm [2] spool. The merged pressure oil flows into the arm cylinder (19) bottom side, and the arm-out operation is carried out. The return oil on the arm cylinder (19) rod side returns to the hydraulic tank through the arm [1] spool (17). The main computer (8) sends an electrical signal to the arm semi-parallel [2] spool control (23) and changes the opening of the arm semi-parallel [2] spool (24) according to the pilot pressure during an arm operation to control the flow volume to the arm [2] spool (18).
42
Arm Semi-parallel 2 Circuit (for compound operation) (ex.: arm-out + boom-up operations) (with HBCV) 19 G1
(G3)
B
(G3)
B
19 33
Tr1
G1
C
33
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
C
2ND OPTION CW pbr2
A
A
CCW par2
PL
PL
2
ELEVATOR UP pbr1
20
DOWN par1
26
12
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
DR
DR
ps1
T3
T4
DR2h
T1
T2
G1
DR1h
P
P
T
21
T
2.55MPa at 30L/min
pga2
pga1 A5 B5
2.55MPa at 30L/min
ARM
SWING
4
LEFT
RIGHT
3
1
CLOSE
4
2
DR
ARM(2) OUT
14
13
pgb
A8 B8
39.2MPa at 20L/min 27.4MPa at 280L/min
28
BOOM(2)
BOOM(1)
pb4 DOWN
DOWN pb8
pa4 UP
9
UP
B3 I
K
Q
C
A
E
G
M PN
T
SWING
CLOSE pb7
pa3 RIGHT
OPEN pa7
RIGHT
L
PB
D
B
PD
F
PF
LEFT
H
UP
PP
TRAVEL(R)
CLOSE
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4
P
DOWN
16
15
N
PH
B1 A1
OPEN
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
29
31
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
OPTION
J
A7
BUCKET
pb3 LEFT
B2 A2
R
pa8 B7
39.2MPa at 20L/min 39.2MPa at 20L/min
32 A3
O
DR
pb9
pap
ARM 2 SUB CONTROL
pc3 ARM 1 SUB CONTROL
27
C
18
25
17
3
G1
IN pa9
par ARM REGENERATIVE
OPEN
1
(G3)
PL
39.2MPa at 20L/min 39.2MPa at 20L/min
pa5 IN
2
B A
PL
pdp
ARM(1)
GRAPPLE
B A
CENTER CUT pcc
pb5 OUT BOOM
(G3)
C
P3 ps2
TRAVEL STRAIGHT
pst
30 6 22
P1
P2
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
PH
P1
P3
P2
7
T
BOOM
A1
8
ARM A2
P1
EV A3
C2
D1
11
10
4
SWING BRAKE
5 A
C
B
BUCKET CLOSE-CONT
TRAVEL STRAIGHT
D
E
ARM REGENE
C3
F
BOOM REGENE
23
ARM 1 SUB-CONT
2-STAGE RELIEF
CENTER CUT C12
A1 P1
C1
3
2-STAGE TRAVEL
A1 T1
24 F173A71C
P0
1
A2
A3
6
43 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
12
Remote control valve (arm, swing)
23
6-stack proportional valve
2
Control valve
13
Arm (in)
24
Arm semi-parallel [2] spool control
3
5-stack solenoid valve
14
Arm (out)
25
Arm semi-parallel [2] spool
4
Lever lock solenoid valve
15
Arm-in pilot pressure sensor
26
Remote control valve (boom, bucket)
5
Console lever lock switch
16
Arm-out pilot pressure sensor
27
Boom (up)
6
Check valve
17
Arm [1] spool
28
Boom (down)
7
Oil cooler
18
Arm [2] spool
29
Boom-up pilot pressure sensor
8
Main computer
19
Arm cylinder
30
Boom-down pilot pressure sensor
9
Cushion valve
20
Arm load holding valve check valve
31
Boom [1] spool
10
P1 pressure sensor
21
Arm-out pressure sensor
32
Boom [2] spool
11
P2 pressure sensor
22
3-stack proportional valve
33
Boom cylinder
Purpose Reduces the pressure drops while the oil flows into the arm via the P2 parallel path (mainly during a compound operation). Secures pressure for arm + boom compound operation. Compound operation (ex.: boom-up + arm-out operations) When the remote control valve (12) is operated to the arm-out side, the pilot pressure oil is fed to Port pb5 and Port pb9 of the control valve (2) and switches the arm [1] spool (17) and arm [2] spool (18). When the remote control valve (26) is operated to the boom-up side, the pilot pressure oil is fed to Port pa8 and Port pa4 of the control valve (2) and switches the boom [1] spool (31) and boom [2] spool (32). The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the boom [2] spool (32) and arm [1] spool (17) via the parallel oil path. The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2) and is fed to the boom [1] spool (31) and arm [2] spool (18) via the parallel oil path. The pressure oil fed to the arm [1] spool (17) merges with the pressure oil from the arm [2] spool (18) and flows into the arm cylinder (19) bottom side, and the arm-out operation is carried out. The pressure oil fed to the boom [1] spool (31) merges with the pressure oil from the boom [2] spool (32) and flows into the boom cylinder (33) bottom side, and the boom-up operation is carried out. The main computer (8) sends an electrical signal to the arm semi-parallel [2] spool control (24) and changes the opening of the arm semi-parallel [2] spool (25) according to the pilot pressure during an arm operation to control the flow volume to the arm [2] spool (18). When a boom-up operation is carried out, the arm semi-parallel [2] spool (25) opening is metered to increase the flow to the boom cylinder (33) for the smooth operation of the boom.
44
Arm-out Regenerative Circuit (with HBCV) 26
20
19
A5
G1
(G3)
B
(G3)
B
19
G1
C
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
C
2ND OPTION CW pbr2
B5
A
A
CCW par2
PL
PL
pb5 OUT DR
2
DR
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
20
ELEVATOR UP pbr1
pa5 IN
DOWN par1
par
T3
ps1
21 17
17 I
Q
K
C
A
E
G
M PN
T1
T2 P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1 A5 B5 pb5 OUT
24
DR2h
2.55MPa at 30L/min
pga2
25
T4
DR1h
pdp 39.2MPa at 20L/min 39.2MPa at 20L/min
ARM(2) OUT
pb9
IN pa9
pa5 IN ARM REGENERATIVE
O
par ARM 2 SUB CONTROL
pap
18
T
pgb
24pc3 ARM 1 SUB CONTROL
A8
9
39.2MPa at 20L/min 27.4MPa at 280L/min
R J
RIGHT
L LEFT
PB IN
B
D
PD OUT
F
PF UP
H
PH N DOWN CLOSE
PP P
pb4 DOWN
DOWN pb8 UP pa8
pa4 UP
OPEN
B3 A3
16
15
B8
BOOM(1)
BOOM(2)
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
A7
BUCKET
pb3 LEFT
CLOSE pb7
pa3 RIGHT
OPEN pa7
B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
22
A
B
BUCKET CLOSE-CONT
D
C
TRAVEL STRAIGHT
E
ARM 2 SUB-CONT
F
BOOM REGENE
ARM 1 SUB-CONT
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
P4
8
P1
B1 A1
TRAVEL(L)
pb1 BACKWARD A1
DR3p
pa1 FORWARD
TRAVEL STRAIGHT
pst
T1
23 12
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
PH
P1 P
P1
T C2
P2
6
4
D1
SWING BRAKE
5 C3
2-STAGE RELIEF
7
CENTER CUT C12
ARM
4
2
RIGHT
3
1 C1
A1
2-STAGE TRAVEL
3 13
14 P0
1 D8F6BFDE
11
10
SWING LEFT
A2
A3
6
45 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
10
P1 pressure sensor
19
Arm cylinder
2
Control valve
11
P2 pressure sensor
20
Arm load holding valve check valve
3
5-stack solenoid valve
12
Remote control valve (arm, swing)
21
Arm-out pressure sensor
4
Lever lock solenoid valve
13
Arm (in)
22
6-stack pressure reducing valve
5
Console lever lock switch
14
Arm (out)
23
Arm regeneration spool control
6
Check valve
15
Arm-in pilot pressure sensor
24
Arm regeneration spool
7
Oil cooler
16
Arm-out pilot pressure sensor
25
Regeneration orifice
8
Main computer
17
Arm [1] spool
26
Regeneration check valve
9
Cushion valve
18
Arm [2] spool
When the remote control valve (12) is operated to the arm-out side, the pilot pressure oil is fed to Port pb5 and Port pb9 of the control valve (2) and switches the arm [1] spool (17) and arm [2] spool (18) to the out side. The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2) and is fed to the arm [2] spool (18) via the center bypass oil path. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2), is fed to the arm [1] spool (17) via the center bypass oil path and merges with the pressure oil from the arm [2] spool (18). The merged pressure oil flows into the arm cylinder (19) bottom side, and the arm-out operation is carried out. The return oil on the arm cylinder (19) rod side returns to the hydraulic tank through the arm load holding valve check valve (20), arm [1] spool (17), and arm regeneration spool (24). At this time, the return oil is metered by the regeneration orifice (25), pushes open the arm regeneration check valve (26), and is regenerated on the bottom side, securing the arm speed for leveling work, etc. When the load pressure on the arm cylinder (19) bottom side becomes high, the arm regeneration spool (24) is switched to the right and the return opening becomes larger. This closes the regeneration check valve (26) and the return oil on the arm cylinder (19) rod side returns to the hydraulic tank through the arm [1] spool (17) and arm regeneration spool (24) without regeneration.
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46
Arm-in Interference Prevention Circuit (with HBCV) 19
19 Tr1
9
G1
(G3)
B
B
A
A
C I
A
K
Q
C
E
G
M PN
2ND OPTION
C
O
PL
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
G1
(G3)
CW pbr2 CCW par2
PL
T DR
DR
ELEVATOR
20
R J
RIGHT
L
B
PB
LEFT
D
PD
PF
F
H
UP
PH
N
ps1
OPEN
21 15
UP pbr1 DOWN par1
PP P
DOWN CLOSE
T3
T4
DR2h
T1
T2
DR1h
pga2
16
2.55MPa at 30L/min
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
P2
P1
pdp
A5 B5
22
P3
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
T
39.2MPa at 20L/min 39.2MPa at 20L/min
OUT pb9
pb5 OUT
pa5 IN BOOM A1
ARM
EV
17
A3
A2
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
pap
18
pgb
pc3 ARM 1 SUB CONTROL
A8
24
39.2MPa at 20L/min 27.4MPa at 280L/min
28
BOOM(2)
B8
BOOM(1)
pb4 DOWN
25
DOWN pb8
pa4 UP
UP pa8
8
26
B3 A3
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
A7
BUCKET
pb3 LEFT
27
CLOSE pb7
pa3 RIGHT
23
OPEN pa7
B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
6
P4
12 P
P1
SWING 4
5
LEFT
RIGHT
3
1
C2
SWING BRAKE
C3
2-STAGE RELIEF
6
B1 A1
TRAVEL(L)
pb1 BACKWARD D1
DR3p
pa1 FORWARD
T
ARM
2
4
TRAVEL STRAIGHT
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
CENTER CUT BOOST
C12
P1
pst
P2
PH
3 C1
13
2-STAGE TRAVEL
14 10
11 A1
P0
504C1D9A
1
A2
A3
A4
7
47 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
11
P2 pressure sensor
21
Arm-in pressure sensor
2
Control valve
12
Remote control valve (arm, swing)
22
3-stack proportional valve
3
5-stack solenoid valve
13
Arm (in)
23
Computer C
4
Lever lock solenoid valve
14
Arm (out)
24
Angle sensor (bucket)
5
Console lever lock switch
15
Arm-in pilot pressure sensor
25
Angle sensor (arm)
6
Check valve
16
Arm-out pilot pressure sensor
26
Angle sensor (boom)
7
Oil cooler
17
Arm [1] spool
27
Angle sensor (EV)
8
Main computer
18
Arm [2] spool
28
Monitor display
9
Cushion valve
19
Arm cylinder
10
P1 pressure sensor
20
Arm load holding valve check valve
Arm in When the remote control valve (12) is operated to the arm-in side, the pilot pressure oil is fed to Port pa5 and Port pa9 of the control valve (2) via the cushion valve (9) and 3-stack proportional valve (22) and switches the arm [1] spool (17) and arm [2] spool (18) to the in side. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the arm [1] spool (17) via the center bypass oil path. The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2) and is fed to the arm [2] spool (18) via the center bypass oil path. The merged pressure oil merges downstream of the spool and then flows into the arm cylinder (19) rod side through the arm load holding valve check valve (20), and the arm-in operation is carried out. The return oil on the arm cylinder (19) bottom side returns to the hydraulic tank through the arm [1] spool (17). Interference prevention Computer C (23) detects the positions of the attachment and elevator cab by electrical signals from the angle sensors (24) (25) (26) (27). When the cab and end attachment come closer to each other during an arm-in operation, the main computer (8) stops the arm by closing the opening of the 3-stack proportional valve (22). When a sensor abnormality or electrical circuit abnormality occurs, computer C (23) sends an electrical signal to the main computer (8) to operate the lever lock solenoid valve (4) and stop all the operations. Also, a message is displayed on the monitor display (28) and the warning buzzer sounds at the same time. Note that cushioning performance can be adjusted by adjusting the output current or control angle on the service support screen.
48
Arm-in Shock Reduction Circuit (with HBCV) 19
9
G1
(G3)
B
B
A
K
Q
C
E
G
M PN
2ND OPTION CW pbr2
A
A
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
C
PL
O
Tr1
G1
(G3)
C
I
19
PL
CCW par2
T DR
DR
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
20
2
ELEVATOR UP pbr1
R J
RIGHT
L
B
PB
LEFT
D
PD
PF
F
H
UP
PH
N
DOWN par1
PP P
DOWN CLOSE
21
OPEN
ps1
T3
T4
DR2h
T1
T2
DR1h
15
pga2
16
2.55MPa at 30L/min
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
P2
P1 T
BOOM A1
ARM
EV
17
A3
A2
pdp
A5 B5
22
P3
39.2MPa at 20L/min 39.2MPa at 20L/min
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
pap
18
pgb
pc3 ARM 1 SUB CONTROL
A8
24
39.2MPa at 20L/min 27.4MPa at 280L/min
28
BOOM(2)
B8
BOOM(1)
pb4 DOWN
25
DOWN pb8
pa4 UP
UP pa8
8
26
B3 A3
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
A7
BUCKET
pb3 LEFT
27
CLOSE pb7
pa3 RIGHT
23
OPEN pa7
B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
6
P4
12 P
P1
SWING 4
5
LEFT
RIGHT
3
1
C2
SWING BRAKE
C3
2-STAGE RELIEF
6
B1 A1
TRAVEL(L)
pb1 BACKWARD D1
DR3p
pa1 FORWARD
T
ARM
2
4
TRAVEL STRAIGHT
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
CENTER CUT BOOST
C12
P1
pst
PH
P2
3 C1
13
2-STAGE TRAVEL
14 10
11 A1
P0
85D49CAD
1
A2
A3
A4
7
49 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
11
P2 pressure sensor
21
Arm-in pressure sensor
2
Control valve
12
Remote control valve (arm, swing)
22
3-stack proportional valve
3
5-stack solenoid valve
13
Arm (in)
23
Computer C
4
Lever lock solenoid valve
14
Arm (out)
24
Angle sensor (bucket)
5
Console lever lock switch
15
Arm-in pilot pressure sensor
25
Angle sensor (arm)
6
Check valve
16
Arm-out pilot pressure sensor
26
Angle sensor (boom)
7
Oil cooler
17
Arm [1] spool
27
Angle sensor (EV)
8
Main computer
18
Arm [2] spool
28
Monitor display
9
Cushion valve
19
Arm cylinder
10
P1 pressure sensor
20
Arm load holding valve check valve
Arm in When the remote control valve (12) is operated to the arm-in side, the pilot pressure oil is fed to Port pa5 and Port pa9 of the control valve (2) via the cushion valve (9) and 3-stack proportional valve (22) and switches the arm [1] spool (17) and arm [2] spool (18) to the in side. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2) and is fed to the arm [1] spool (17) via the center bypass oil path. The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2) and is fed to the arm [2] spool (18) via the center bypass oil path. The merged pressure oil merges downstream of the spool and then flows into the arm cylinder (19) rod side through the arm load holding valve check valve (20), and the arm-in operation is carried out. The return oil on the arm cylinder (19) bottom side returns to the hydraulic tank through the arm [1] spool (17). Shock reduction Computer C (23) detects the arm angle by electrical signals from the angle sensor (25). When the arm is close to the arm-out end, the main computer (8) controls the opening area of the 3stack proportional valve (22) from P2 to A2 to reduce the shock generated when an arm operation is started. Note that cushioning performance can be adjusted by adjusting the output current or control angle on the service support screen.
50
Arm-out End Shock Reduction Circuit (with HBCV)
9
19
I
G1
C
A
K
Q
E
G
M PN
(G3)
B
O
B
19
Tr1
G1
(G3)
C
CW pbr2 C
T
A
CCW par2
A PL
PL
DR
DR J
L
PB
D PD
B
LEFT
PF
F
H
PH
UP
N
ELEVATOR
20
UP pbr1
PP P
DOWN CLOSE
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
2
R
RIGHT
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
2ND OPTION
DOWN par1
OPEN
ps1
T3
T4
DR2h
T1
T2
DR1h
15
16
21
2.55MPa at 30L/min
pga2
P3 ps2
2.55MPa at 30L/min
CENTER CUT pcc
pga1
25
pdp
A5 B5
26 17
27
39.2MPa at 20L/min 39.2MPa at 20L/min
pb5 OUT
OUT pb9
pa5 IN
IN pa9
par ARM REGENERATIVE ARM 2 SUB CONTROL
23
28 24
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
BOOM(2)
B8
BOOM(1)
pb4 DOWN
8
DOWN pb8
pa4 UP
UP pa8
B3 A3 A
B
BUCKET CLOSE-CONT
E
ARM 2 SUB-CONT
A7
BUCKET
pb3 LEFT
F
BOOM REGENE
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
D
C
TRAVEL STRAIGHT
18
pgb
pc3 ARM 1 SUB CONTROL
29
pap
ARM 1 SUB-CONT
CLOSE pb7
pa3 RIGHT
OPEN pa7
B2 A2
P1
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION
A1
pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
6
T1
P4
6
B1 A1
22
TRAVEL(L)
pb1 BACKWARD
4 P1
12 C2
P
5
DR3p
pa1 FORWARD
TRAVEL STRAIGHT
pst
D1
SWING BRAKE
T
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST C3
2-STAGE RELIEF
P1
CENTER CUT
PH
P2
C12
ARM
2
SWING 4
LEFT
RIGHT
3
1
3 C1
2-STAGE TRAVEL
10
11 A1
13
14
1 P0
2557AD59
A2
A3
A4
7
51 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line 1
Hydraulic pump
11
P2 pressure sensor
21
Arm-out pressure sensor
2
Control valve
12
Remote control valve (arm, swing)
22
Arm regeneration spool control
3
5-stack solenoid valve
13
Arm (in)
23
Arm regeneration spool
4
Lever lock solenoid valve
14
Arm (out)
24
Computer C
5
Console lever lock switch
15
Arm-in pilot pressure sensor
25
Angle sensor (bucket)
6
Check valve
16
Arm-out pilot pressure sensor
26
Angle sensor (arm)
7
Oil cooler
17
Arm [1] spool
27
Angle sensor (boom)
8
Main computer
18
Arm [2] spool
28
Angle sensor (EV)
9
Cushion valve
19
Arm cylinder
29
Monitor display
10
P1 pressure sensor
20
Arm load holding valve check valve
Arm out When the remote control valve (12) is operated to the arm-out side, the pilot pressure oil is fed to Port pb5 and Port pb9 of the control valve (2) and switches the arm [1] spool (17) and arm [2] spool (18) to the out side. The discharge oil from A2 of the hydraulic pump (1) flows into Port P2 of the control valve (2) and is fed to the arm [2] spool (18) via the center bypass oil path. The discharge oil from A1 of the hydraulic pump (1) flows into Port P1 of the control valve (2), is fed to the arm [1] spool (17) via the center bypass oil path and merges with the pressure oil from the arm [2] spool (18). The merged pressure oil flows into the arm cylinder (19) bottom side, and the arm-out operation is carried out. The return oil on the arm cylinder (19) rod side returns to the hydraulic tank through the arm load holding valve check valve (20), arm [1] spool (17), and arm regeneration spool (23). End shock reduction Computer C (24) detects the arm angle by electrical signals from the angle sensor (26). When the arm is raised close to the arm-out end, the main computer (8) meters the opening of the arm regeneration spool (23). This decreases the arm-out speed and reduces the shock on the arm-out stroke end. Note that cushioning performance can be adjusted by adjusting the output current or control angle on the service support screen.
52
Negative Control Circuit Negative Control Circuit
Tr1
BR2 AR2
22.6MPa at 20L/min 22.6MPa at 20L/min
5
2ND OPTION
4
CW pbr2 CCW par2
P1
BR1 AR1
20.6MPa at 20L/min 20.6MPa at 20L/min
11
2
C3
2-STAGE RELIEF
D1
UP pbr1 DOWN par1
T3
SWING BRAKE
ELEVATOR
9 ps1
C2
T4
DR2h
12
T1 T2
CENTER CUT C12
DR1h
P3 2.55MPa at 30L/min
pga2 pga1
ps2
2.55MPa at 30L/min
CENTER CUT pcc
10
C1
2-STAGE TRAVEL
pdp
A5 39.2MPa at 20L/min 39.2MPa at 20L/min
B5
ARM(2)
ARM(1) pb5 OUT
OUT pb9
pa5 IN
IN pa9
3
P0
par ARM REGENERATIVE ARM 2 SUB CONTROL
pap
6
pgb
pc3 ARM 1 SUB CONTROL
A8 39.2MPa at 20L/min 27.4MPa at 280L/min
B8
BOOM(1)
BOOM(2) pb4 DOWN
7
DOWN pb8 UP pa8
pa4 UP B3 A3
B7
39.2MPa at 20L/min 39.2MPa at 20L/min
SWING
A7
BUCKET
pb3 LEFT
CLOSE pb7
pa3 RIGHT
OPEN pa7
B2 A2
B6 A6
39.2MPa at 20L/min 39.2MPa at 20L/min
TRAVEL(R)
OPTION pb2 GRAPPLE OPEN
BACKWARD pb6
pa2 GRAPPLE CLOSE
FORWARD pa6
1
13
P4 (FRONT)
B1 A1
TRAVEL(L)
pb1 BACKWARD
DR3p
pa1 FORWARD
TRAVEL STRAIGHT
a1
A1
A2
a2
Psv2
(REAR)
8
pst
MAIN RELIEF V. 34.3MPa at 230L/min 37.3MPa at 210L/min
BOOST
P1
Psv1
14
PH
P2 a5
A3
M
a3 Dr
B1
15
15 IN
4FE3A51B
B3
OUT
Dr3
6
53 Pressure line
Pilot tank line
Tank line
Electric line
Pilot pressure line
Negative control line
1
Hydraulic pump
6
Check valve
11
N1 negative control pressure sensor
2
Control valve
7
Oil cooler
12
N2 negative control pressure sensor
3
5-stack solenoid valve
8
Main computer
13
P1 flow control proportional valve
4
Lever lock solenoid valve
9
P1 negative control relief valve
14
P2 flow control proportional valve
5
Console lever lock switch
10
P2 negative control relief valve
15
Swash plate
When the remote control valve operation lever is set to neutral, the discharge oil from A1 and A2 of the hydraulic pump (1) returns to the hydraulic tank through Port P1 and Port P2 of the control valve (2), the center bypass oil path, the downmost stream P1 negative control relief valve (9) and P2 negative control relief valve (10). The negative control pressure oil separated from the center bypass oil path is fed to the N1 negative control pressure sensor (11) through Port ps1 of the control valve (2) and to the N2 negative control pressure sensor (12) through Port ps2. Then, the P1 flow control proportional valve (13) and P2 flow control proportional valve (14) on the hydraulic pump (1) operate. As a result, the angle of the hydraulic pump (1) swash plate (15) becomes smaller, reducing the pump discharge flow.
54
Other Circuits As an example, this section explains the following items. ・ Cushion circuit (ex.: when stopping arm-out operation) ・ Heat circuit (lever in neutral) ・ Auto pressure boost circuit (arm in) (with HBCV) ・ Elevator cab up/down circuit ・ LM circuit
55
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DOWNLOAD THE COMPLETE MANUAL
• Thank you very much for reading the preview of the manual. • You can download the complete manual from: www.heydownloads.com by clicking the link below
• Please note: If there is no response to CLICKING the link, please download this PDF first and then click on it.
CLICK HERE TO
DOWNLOAD THE COMPLETE MANUAL