Information injection-pump assembly
BOSCH
9 400 615 643
9400615643
ZEXEL
101607-1800
1016071800
MITSUBISHI
XE130116
xe130116
Rating:
Include in #2:
104746-6610
as _
Cross reference number
BOSCH
9 400 615 643
9400615643
ZEXEL
101607-1800
1016071800
MITSUBISHI
XE130116
xe130116
Zexel num
Bosch num
Firm num
Name
Calibration Data:
Adjustment conditions
Test oil
1404 Test oil ISO4113 or {SAEJ967d}
1404 Test oil ISO4113 or {SAEJ967d}
Test oil temperature
degC
40
40
45
Nozzle and nozzle holder
105780-8140
Bosch type code
EF8511/9A
Nozzle
105780-0000
Bosch type code
DN12SD12T
Nozzle holder
105780-2080
Bosch type code
EF8511/9
Opening pressure
MPa
17.2
Opening pressure
kgf/cm2
175
Injection pipe
Outer diameter - inner diameter - length (mm) mm 6-2-600
Outer diameter - inner diameter - length (mm) mm 6-2-600
Overflow valve
131424-8420
Overflow valve opening pressure
kPa
255
221
289
Overflow valve opening pressure
kgf/cm2
2.6
2.25
2.95
Tester oil delivery pressure
kPa
157
157
157
Tester oil delivery pressure
kgf/cm2
1.6
1.6
1.6
Direction of rotation (viewed from drive side)
Left L
Left L
Injection timing adjustment
Direction of rotation (viewed from drive side)
Left L
Left L
Injection order
1-5-3-6-
2-4
Pre-stroke
mm
3.2
3.15
3.25
Beginning of injection position
Governor side NO.1
Governor side NO.1
Difference between angles 1
Cal 1-5 deg. 60 59.5 60.5
Cal 1-5 deg. 60 59.5 60.5
Difference between angles 2
Cal 1-3 deg. 120 119.5 120.5
Cal 1-3 deg. 120 119.5 120.5
Difference between angles 3
Cal 1-6 deg. 180 179.5 180.5
Cal 1-6 deg. 180 179.5 180.5
Difference between angles 4
Cyl.1-2 deg. 240 239.5 240.5
Cyl.1-2 deg. 240 239.5 240.5
Difference between angles 5
Cal 1-4 deg. 300 299.5 300.5
Cal 1-4 deg. 300 299.5 300.5
Injection quantity adjustment
Adjusting point
-
Rack position
12
Pump speed
r/min
850
850
850
Each cylinder's injection qty
mm3/st.
85.1
82.5
87.7
Basic
*
Fixing the rack
*
Standard for adjustment of the maximum variation between cylinders
*
Injection quantity adjustment_02
Adjusting point
Z
Rack position
9.5+-0.5
Pump speed
r/min
800
800
800
Each cylinder's injection qty
mm3/st.
10.8
9.2
12.4
Fixing the rack
*
Standard for adjustment of the maximum variation between cylinders
*
Injection quantity adjustment_03
Adjusting point
A
Rack position
R1(12)
Pump speed
r/min
850
850
850
Average injection quantity
mm3/st.
85.1
84.1
86.1
Basic
*
Fixing the lever
*
Injection quantity adjustment_04
Adjusting point
B
Rack position
R1+0.85
Pump speed
r/min
1450
1450
1450
Average injection quantity
mm3/st.
99.9
95.9
103.9
Fixing the lever
*
Injection quantity adjustment_05
Adjusting point
I
Rack position
-
Pump speed
r/min
100
100
100
Average injection quantity
mm3/st.
91
81
101
Fixing the lever
*
Rack limit
*
Injection quantity adjustment_06
Adjusting point
E
Rack position
R2(13)
Pump speed
r/min
1450
1450
1450
Average injection quantity
mm3/st.
107.9
105.9
109.9
Fixing the lever
*
Remarks
Set tamper proofing.
Set tamper proofing.
Timer adjustment
Pump speed
r/min
1150--
Advance angle
deg.
0
0
0
Remarks
Start
Start
Timer adjustment_02
Pump speed
r/min
1100
Advance angle
deg.
0.5
Timer adjustment_03
Pump speed
r/min
1450
Advance angle
deg.
6
5.5
6.5
Remarks
Finish
Finish
Test data Ex:
Governor adjustment
N:Pump speed
R:Rack position (mm)
(1)Torque cam stamping: T1
(2)Tolerance for racks not indicated: +-0.05mm.
(3)RACK LIMIT
----------
T1=G43
----------
----------
T1=G43
----------
Speed control lever angle
F:Full speed
I:Idle
(1)Stopper bolt set position 'H'
----------
----------
a=18.5deg+-5deg b=(42deg)+-3deg
----------
----------
a=18.5deg+-5deg b=(42deg)+-3deg
Stop lever angle
S:Stop the pump.
(1)Set the stopper bolt at pump speed = aa and rack position = bb (non-injection rack position). Confirm non-injection.
(2)After setting the stopper bolt, confirm non-injection at speed cc. Rack position = dd (non-injection rack position).
(3)Rack position = approximately ee.
(4)Free (at delivery)
(5)Normal use set at engine manufacturer.
----------
aa=1450r/min bb=7.2-0.5mm cc=275r/min dd=(8.8)mm ee=15mm
----------
a=36.5deg+-5deg b=(25deg) c=13deg+-5deg
----------
aa=1450r/min bb=7.2-0.5mm cc=275r/min dd=(8.8)mm ee=15mm
----------
a=36.5deg+-5deg b=(25deg) c=13deg+-5deg
0000001501 MICRO SWITCH
Adjustment of the micro-switch
Adjust the bolt to obtain the following lever position when the micro-switch is ON.
(1)Speed N1
(2)Rack position Ra
----------
N1=400r/min Ra=9.2+-0.1mm
----------
----------
N1=400r/min Ra=9.2+-0.1mm
----------
0000001601 LEVER
(A) Accelerator lever stopper bolt
(B) Link
(c) Nut
(D) Lever
(E) Pin
(f) lever
(G) Stopper bolt
(H) Return spring
(J) Pin (E) contacts lever.
(K) Load sensor terminal
(1)Black
(2)Blue-yellow
(3)Blue-red
Setting the accelerator lever angle, load sensor adjustment
1. Accelerator lever setting method
(1)Position the speed lever against the idle stopper bolt and fix.
(2)Screw in the accelerator lever stopper bolt (A) and back off the stopper bolt (A) from the position where the accelerator lever pin contacts the speed lever and set. (Gap: approx. 1 mm)
Tightening torque: 4.9~7 N.m {0.5~0.7 kgf.m}
2. Load sensor adjustment (See fig 1)
(1)Load sensor output measuring circuit
Apply DC5+-0.01V to the load sensor terminals and measure the output voltage.
(2)Load sensor output adjustment procedure
Hold the speed lever against the full side stopper bolt and fix. Adjust the load sensor output voltage to VF = 0.417+-0.1 V using the link (B) and then fix temporarily using nut (C).
Turn the speed lever from the idle side to the full side and confirm that output voltage VF = 0.417+-0.1 V is obtained. Confirm several times and then fix using nut (C).
Tightening torque: 3.4~4.9 N.m {0.35~0.5 kgf.m}
3. Setting the step motor's idle side stopper bolt
After adjustment in previous 1 and 2, position speed lever against idle stopper bolt and fix. Then, screw in stopper bolt G until step motor lever D's pin E contacts lever F. Back off 10+2 deg (approx. 3.5 mm) from this position and fix G. (See fig. 3)
4. Speed lever return confirmation
(1)Remove return spring (H) and confirm that the speed lever is returned to the idle position by the torsion spring.
(2)Reinstall the return spring (H) in its original position.
----------
----------
----------
----------
0000001701 TAMPER PROOF
1. Method for setting tamperproof proofing
(1)After governor adjustment (torque cam phase adjustment), move the load lever to increase the full rack position to Ra.
(2)At speed N1 screw in screw (A) to obtain the rack position (actual measurement: Rb) for injection quantity Q1.
(3)Temporarily caulk using the tip of a screwdriver
(4)Confirm that the rack at that time is at Rc.
(5)Lock using setscrew (B). (Tightening torque = T)
(6)Next, coat (C) with adhesive and then pressfit.
(7)Then, readjust the full rack position using the load lever.
----------
N1=1450r/min Q1=107.9+-2mm3/st Ra=(0.4)mm Rb=R2mm Rc=R2mm
----------
T=4.9~7N-m(0.5~0.7Kgf-m)
----------
N1=1450r/min Q1=107.9+-2mm3/st Ra=(0.4)mm Rb=R2mm Rc=R2mm
----------
T=4.9~7N-m(0.5~0.7Kgf-m)
Timing setting
(1)Pump vertical direction
(2)Position of timer's tooth at No 1 cylinder's beginning of injection
(3)B.T.D.C.: aa
(4)-
----------
aa=10deg
----------
a=(2deg)
----------
aa=10deg
----------
a=(2deg)
Information:
General Recommendations and Contamination Control Guidelines for Fuels
Follow all applicable industry standards and all applicable governmental, environmental, and safety guidelines, practices, regulations, and mandates.Note: These general recommendations and guidelines concerning maintenance and care of fuel and fuel storage systems are not intended to be all inclusive. Discuss proper fuel safety and health, handling, and maintenance practices with your fuel supplier. Use of these general recommendations and guidelines does not lessen the engine owners and/or fuel supplier responsibility to follow all industry standard practices for fuel storage and for fuel handling.Note: Where recommendations for draining water and/or sediment and/or debris are stated, dispose of this waste according to all applicable regulations and mandates.Note: Caterpillar filters are designed and built to provide optimal performance and protection of the fuel system components.Clean fuels, as detailed below, are strongly recommended to allow optimal performance and durability of the fuel systems and to reduce power loss, failures, and related down time of engines.Fuels of “ISO 18/16/13” cleanliness levels or cleaner as dispensed into the engine or machine fuel tank should be used. Reduced power, failures and related downtime can result if clean fuels are not used. Fuels of “ISO 18/16/13” are particularly important for new fuel system designs such as Common Rail injection systems and unit injection systems. These new injection system designs utilize higher fuel pressures and are designed with tight clearances between moving parts to meet required stringent emissions regulations. Peak injection pressures in current fuel injection systems may exceed 30,000 psi. Clearances in these systems are less than 5 µm. As a result, particle contaminants as small as 4 µm can cause scoring and scratching of internal pump and injector surfaces and of injector nozzles.Water in the fuel causes cavitation, corrosion of fuel system parts, and provides an environment where microbial growth in the fuel can flourish. Other sources of fuel contamination are soaps, gels, or other compounds that may result from undesirable chemical interactions in the fuels. Gels and other insoluble compounds can also form in biodiesel fuel at low temperatures or if biodiesel is stored for extended periods. An indication of microbial contamination, detrimental fuel additives interactions, or cold temperature gel is very rapid filter plugging of bulk fuel filters or machine fuel filters.To reduce downtime due to contamination, follow these fuel maintenance guidelines in addition to the recommendations given in the "Contamination Control" Chapter in this Special Publication:
Use high-quality fuels per recommended and required specifications (refer to the “Fuel” chapter in this Special Publication).
Do not add new engine oil, waste engine oil or any oil product to the fuel unless the engine is designed and certified to burn diesel engine oil (for example Caterpillar ORS designed for large engines). Engine oils may raise the sulfur level of the fuel and may cause fouling of the fuel system and loss of performance. Engine oils in fuels can also reduce the maintenance intervals of aftertreatment devices in Tier 4 machines.
Use recommended Cat filtration products, including Cat Advanced Efficiency Fuel
Follow all applicable industry standards and all applicable governmental, environmental, and safety guidelines, practices, regulations, and mandates.Note: These general recommendations and guidelines concerning maintenance and care of fuel and fuel storage systems are not intended to be all inclusive. Discuss proper fuel safety and health, handling, and maintenance practices with your fuel supplier. Use of these general recommendations and guidelines does not lessen the engine owners and/or fuel supplier responsibility to follow all industry standard practices for fuel storage and for fuel handling.Note: Where recommendations for draining water and/or sediment and/or debris are stated, dispose of this waste according to all applicable regulations and mandates.Note: Caterpillar filters are designed and built to provide optimal performance and protection of the fuel system components.Clean fuels, as detailed below, are strongly recommended to allow optimal performance and durability of the fuel systems and to reduce power loss, failures, and related down time of engines.Fuels of “ISO 18/16/13” cleanliness levels or cleaner as dispensed into the engine or machine fuel tank should be used. Reduced power, failures and related downtime can result if clean fuels are not used. Fuels of “ISO 18/16/13” are particularly important for new fuel system designs such as Common Rail injection systems and unit injection systems. These new injection system designs utilize higher fuel pressures and are designed with tight clearances between moving parts to meet required stringent emissions regulations. Peak injection pressures in current fuel injection systems may exceed 30,000 psi. Clearances in these systems are less than 5 µm. As a result, particle contaminants as small as 4 µm can cause scoring and scratching of internal pump and injector surfaces and of injector nozzles.Water in the fuel causes cavitation, corrosion of fuel system parts, and provides an environment where microbial growth in the fuel can flourish. Other sources of fuel contamination are soaps, gels, or other compounds that may result from undesirable chemical interactions in the fuels. Gels and other insoluble compounds can also form in biodiesel fuel at low temperatures or if biodiesel is stored for extended periods. An indication of microbial contamination, detrimental fuel additives interactions, or cold temperature gel is very rapid filter plugging of bulk fuel filters or machine fuel filters.To reduce downtime due to contamination, follow these fuel maintenance guidelines in addition to the recommendations given in the "Contamination Control" Chapter in this Special Publication:
Use high-quality fuels per recommended and required specifications (refer to the “Fuel” chapter in this Special Publication).
Do not add new engine oil, waste engine oil or any oil product to the fuel unless the engine is designed and certified to burn diesel engine oil (for example Caterpillar ORS designed for large engines). Engine oils may raise the sulfur level of the fuel and may cause fouling of the fuel system and loss of performance. Engine oils in fuels can also reduce the maintenance intervals of aftertreatment devices in Tier 4 machines.
Use recommended Cat filtration products, including Cat Advanced Efficiency Fuel