BENDIX BW1422 Manuale utente

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Compressori d'aria
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Manuale utente

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1
®
SD-01-335
Bendix
®
TU-FLO
®
700 Air Compressor
COMPRESSOR NAMEPLATE
SER
NO.
BW
NO.
MANUFACTURED BY
BENDIX
TU-FLO 700
Two methods are employed for cooling the Tu-Flo
®
700
compressor during operation. The cylinder head is
connected to the engine’s cooling system, while the cylinder
has external fins for efficient air cooling.
All Tu-Flo
®
700 compressors utilize the engine’s pressurized
oil system to lubricate the internal moving parts. A nameplate
is attached to the crankcase to identify the compressor.
The nameplate displays a Bendix piece number or in some
cases an engine or vehicle manufacturer’s piece number,
along with a serial number.
DESCRIPTION
The function of the air compressor is to provide and main-
tain air under pressure to operate devices in the air brake
and/or auxiliary air systems
The Tu-Flo
®
700 compressor is a two cylinder, single stage,
reciprocating compressor with a rated displacement of 15.5
cubic feet of air per minute at 1250 R.P.M. The Tu-Flo
®
700
compressor is constructed from three major assemblies,
the head, the cylinder block and the crankcase.
The head houses the discharge valving and is installed on
the upper portion of the cylinder block. The cylinder block
contains the cylinder bores and inlet valves and is mounted
to the crankcase. The crankcase houses the crankshaft
and main bearings.
Various mounting and drive configurations, required by the
numerous vehicle engine designs, are available. Two
governor mounting pads are located on either side of the
cylinder block to provide convenient governor mounting.
EXTERIOR
BENDIX
®
TU-FLO
®
700 AIR COMPRESSOR
(CROSS SECTION)
CRANKCASE
DISCHARGE
CAP NUT
PISTON
PISTON
RINGS
CRANKSHAFT
CONNECTING
ROD
DISCHARGE
VALVE
SPRING
INLET
VALVE
SPRING
INLET
VALVE
DISCHARGE
VALVE
DISCHARGE
VALVE SEAT
UNLOADER
MECHANISM
2
OPERATION
The compressor is driven by the vehicle engine and is
operating continuously while the engine is running. Actual
compression of air is controlled by the compressor unloading
mechanism and the governor. The governor is generally
mounted on the compressor and maintains the brake system
air pressure to a preset maximum and minimum pressure
level.
INTAKE AND COMPRESSION OF AIR (LOADED)
During the down stroke of the piston, a slight vacuum is
created between the ton of the piston and the head, causing
the flat circular inlet valve to move up and off its seat. (Note
the flat square discharge valve remains on its seat.)
Atmospheric air is drawn through the air strainer by the open
inlet valve and into the cylinder (see Fig. 2). As the piston
begins its upward stroke, the air that was drawn into the
cylinder on the down stroke is being compressed. Air
pressure on top of the inlet valve plus the force of its spring,
returns the inlet valve to its seat. The piston continues the
upward stroke and compressed air then flows by the open
discharge valve, into the discharge line and on to the
reservoirs (see Fig. 3). As the piston reaches the top of its
stroke and starts down, the discharge valve spring and air
pressure in the discharge line returns the discharge valve to
its seat. This prevents the compressed air in the discharge
line from returning to the cylinder bore as the intake and
compression cycle is repeated.
NON-COMPRESSION OF AIR (UNLOADED)
When air pressure in the reservoir reaches the cut-out setting
of the governor, the governor allows air to pass from the
reservoir into the cavity beneath the unloader pistons. This
lifts the unloader pistons and plungers. The plungers move
up and hold the inlet valves off their seats (see Figure 4).
With the inlet valves held off their seats by the unloader
pistons and plungers, air is pumped back and forth between
the two cylinders. When air is used from the reservoir and
the pressure drops to the cut-in setting of the governor, the
governor closes and exhausts the air from beneath the
unloader pistons. The unloader saddle spring forces the
saddle, pistons and plungers down and the inlet valves return
to their seats. Compression is then resumed.
COMPRESSOR & THE AIR BRAKE SYSTEM
GENERAL
The compressor is part of the total air brake system, more
specifically, the charging portion of the air brake system. As
a component in the overall system its condition, duty cycle,
proper installation and operation will directly affect other
components in the system.
Powered by the vehicle engine, the air compressor builds
the air pressure for the air brake system. The air compressor
is typically cooled by the engine coolant system, lubricated
by the engine oil supply and has its inlet connected to the
engine induction system.
As the atmospheric air is compressed, all the water vapor
originally in the air is carried along into the air system, as
well as a small amount of the lubricating oil as vapor. If an
air dryer is not used to remove these contaminants prior to
entering the air system, the majority, but not all, will condense
in the reservoirs. The quantity of contaminants that reach
the air system depends on several factors including
MACK
MACK
"FOXHEAD"
CUMMINS
DETROIT
DIESEL
VARIOUS COMPRESSOR MOUNTINGS
3
installation, maintenance and contaminant handling devices
in the system. These contaminants must either be eliminated
prior to entering the air system or after they enter.
DUTY CYCLE
The duty cycle is the ratio of time the compressor spends
building air to the total engine running time. Air compressors
are designed to build air (run "loaded") up to 25% of the
time. Higher duty cycles cause conditions that affect air
brake charging system performance which may require
additional maintenance. Factors that add to the duty cycle
are: air suspension, additional air accessories, use of an
undersized compressor, frequent stops, excessive leakage
from fittings, connections, lines, chambers or valves, etc.
Refer to Table A in the Troubleshooting section for a guide to
various duty cycles and the consideration that must be given
to maintenance of other components.
COMPRESSOR INSTALLATION
While the original compressor installation is usually
completed by the vehicle manufacturer, conditions of
operation and maintenance may require additional
consideration. The following presents base guidelines.
DISCHARGE LINE
The discharge line allows the air, water-vapor and oil-vapor
mixture to cool between the compressor and air dryer or
reservoir. The typical size of a vehicle's discharge line, (see
column 2 of Table A in the Troubleshooting section) assumes
a compressor with a normal (less than 25%) duty cycle,
operating in a temperate climate. See Bendix and/or other
air dryer manufacturer guidelines as needed.
The discharge line must maintain a constant slope down
from the compressor to the air dryer inlet fitting or reservoir
to avoid low points where ice may form and block the flow. If,
instead, ice blockages occur at the air dryer or reservoir
inlet, insulation may be added here, or if the inlet fitting is a
typical 90 degree fitting, it may be changed to a straight or
45 degree fitting. Shorter discharge line lengths or insulation
may be required in cold climates.
While not all compressors and charging systems are
equipped with a discharge line safety valve this component
is recommended. The discharge line safety valve is installed
in the cylinder head (Tu-Flo
®
550/750) or close to the
compressor discharge port and protects against over
pressurizing the compressor in the event of a discharge line
freezeup.
FIGURE 1A - SYSTEM DRAWING
Air Dryer
Reservoir Drain
Service Reservoir
(Supply Reservoir)
Compressor
Governor
(Governor plus Synchro valve
for the Bendix
®
DuraFlo
596
Compressor)
Discharge
Line
Optional “Ping” Tank
Optional Bendix
®
PuraGuard
®
QC
Oil Coalescing Filter
The Air Brake Charging System supplies the
compressed air for the braking system as well as other air
accessories for the vehicle. The system usually consists
of an air compressor, governor, discharge line, air dryer,
and service reservoir.
FIGURE 1B - DISCHARGE LINE SAFETY VALVE
HOLE
THREAD
4
DISCHARGE LINE TEMPERATURE
When the temperature of the compressed air that enters
the air dryer is within the normal range, the air dryer can
remove most of the charging system oil. If the temperature
of the compressed air is above the normal range, oil as oil-
vapor is able to pass through the air dryer and into the air
system. Larger diameter discharge lines and/or longer
discharge line lengths can help reduce the temperature.
The air dryer contains a filter that collects oil droplets, and a
desiccant bed that removes almost all of the remaining water
vapor. The compressed air is then passed to the air brake
service (supply) reservoir. The oil droplets and the water
collected are automatically purged when the governor
reaches its "cut-out" setting.
For vehicles with accessories that are sensitive to small
amounts of oil, we recommend installation of a Bendix
®
PuraGuard
®
QC
oil coalescing filter, designed to minimize
the amount of oil present.
LUBRICATION
Since all Tu-Flo
®
700 compressors are connected to the
engine’s pressurized oil system, a continuous flow of oil is
provided to the compressor, which is eventually returned to
the engine. Oil is fed into the compressor in various ways,
for example: through the rear end cover, the drive end of the
crankshaft or through the front flange adapter. An oil passage
in the crankshaft conducts pressurized oil to the precision
sleeve main bearings and to the connecting rod bearings.
Splash lubrication of the cylinder bores, connecting rod wrist
pin bushings, and the ball type main bearings, on some
models, is obtained as oil is forced out around the crankshaft
journals by engine oil pressure.
Check the exterior of the compressor for the presence of oil
seepage and refer to the TROUBLESHOOTING section for
appropriate tests and corrective action.
OIL PASSING
All reciprocating compressors currently manufactured will
pass a minimal amount of oil. Air dryers will remove the
majority of oil prior to entrance into the air brake system.
For particularly oil sensitive systems the Bendix
®
PuraGuard
®
QC
oil coalescing filter can be used in conjunction with a
Bendix air dryer.
If compressor oil passing is suspected, refer to the
TROUBLESHOOTING section and TABLE A for the
symptoms and corrective action to be taken. In addition,
Bendix has developed the "Bendix Air System Inspection
Cup" or BASIC test to help substantiate suspected excessive
oil passing. The steps to be followed when using the BASIC
test are presented in APPENDIX A at the end of the
TROUBLESHOOTING section.
FIGURE 2 - INTAKE
INTAKE
STRAINER
STROKE
TO RESERVOIR
INLET VALVE
UNLOADER
PLUNGER
TO GOVERNOR
INTAKE
STRAINER
STROKE
TO RESERVOIR
TO GOVERNOR
PISTON
DISCHARGE
VALVE
UNLOADER
PLUNGER
STROKE
INLET VALVE
TO RESERVOIR
UNLOADER
PLUNGER
INTAKE
STRAINER
TO GOVERNOR
PISTON
DISCHARGE
VALVE
DISCHARGE
VALVE
INLET VALVE
FIGURE 3 - COMPRESSION
FIGURE 4 - UNLOADING
PISTON
5
DRY ELEMENT—PLEATED PAPER AIR
STRAINER
Every 20,000 miles or 800 operating hours:
Remove the spring clips from either side of mounting baffle
and remove the cover. Replace the pleated paper filter and
remount the cleaned cover making sure the filter is in
position. Be sure to replace the air strainer gasket if the
entire air strainer is removed from the compressor intake.
(Note: Some compressors are fitted with compressor intake
adapters which allow the compressor intake to be connected
to the engine air cleaner.) In this case, the compressor
receives a supply of clean air from the engine air cleaner.
When the engine air filter is changed, the compressor intake
adapter should be checked. If it is loose, remove the intake
adapter, clean the strainer plate, if applicable, and replace
the intake adapter gasket, and reinstall the adapter securely.
Check line connections both at the compressor intake
adapter and at the engine air cleaner. Inspect the connecting
line for ruptures and replace it if necessary.
COOLING
Air flowing through the engine compartment from the action
of the engine’s fan and the movement of the vehicle assists
in cooling the crankcase. Coolant flowing from the engine’s
cooling system through connecting lines enters the
compressor and flows through the internal passages in the
cylinder block and head and back to the engine. Proper
cooling is important in maintaining discharge air temperatures
below the 400°F recommended maximum.
PREVENTIVE MAINTENANCE
Regularly scheduled maintenance is the single most
important factor in maintaining the air brake charging system.
Refer to Table A in the Troubleshooting section for a guide to
various considerations that must be given to the maintenance
of the compressor and other related charging system
components.
Important Note: Review the warranty policy before
performing any intrusive maintenance procedures. An
extended warranty may be voided if intrusive maintenance
is performed during this period.
Every month, 300 operating hours or after each 10,000 miles,
depending on the operating conditions, experience and the
type of strainer used, service the air strainer.
POLYURETHANE SPONGE STRAINER
Every 5000 miles or 150 operating hours:
Remove and wash all of the parts. The strainer element
should be cleaned or replaced. If the element is cleaned, it
should be washed in a commercial solvent or a detergent
and water solution. The element should be saturated in clean
engine oil, then squeezed dry before replacing it in the
strainer. Be sure to replace the air strainer gasket if the
entire air strainer is removed from the compressor intake.
FIGURE 5 - POLYURETHANE SPONGE STRAINER
FIGURE 6 - PAPER AIR STRAINER DRY ELEMENT-
PLEATED
FIGURE 7 - COMPRESSOR INTAKE ADAPTER
6
Every 6 months, 1800 operating hours or after each
50,000 miles:
Remove the discharge head fittings and inspect the
compressor discharge port and discharge line for excessive
carbon deposits. If excessive buildup is noted in either, the
discharge line must be cleaned or replaced and the
compressor checked more thoroughly, paying special
attention to the air induction system, oil supply and return
system, and proper cooling. If necessary, repair or replace
the compressor. Check for proper belt and pulley alignment
and belt tension. Adjust if necessary, paying special attention
not to over tighten the belt tension. Check for noisy
compressor operation, which could indicate a worn drive
gear coupling or a loose pulley. Adjust and/or replace as
necessary. Check all compressor mounting bolts and
retighten evenly if necessary. Check for leakage and proper
unloader mechanism operation. Replace if defective in any
way.
Every 24 months, 7200 operating hours or after each
200,000 miles:
Perform a thorough inspection as indicated below and
depending upon the results of this inspection or experience,
disassemble the compressor, clean and inspect all parts
thoroughly, repair or replace all worn or damaged parts using
only genuine Bendix replacements or replace the
compressor with a genuine Bendix remanufactured unit.
Important: Should it be necessary to drain the engine cooling
system to prevent damage from freezing, the cylinder head
of the compressor must also be drained.
GENERAL SERVICE CHECKS
INSPECTION
It is of the utmost importance that the compressor receives
a clean supply of air. The air strainer must be properly
installed and kept clean. If the compressor intake is connected
to the engine air cleaner, supercharger, etc., these
connections must be properly installed and maintained.
Check the compressor mountings to be sure they are secure.
Check the drive for proper alignment, belt tension, etc.
Inspect the oil supply and return lines. Be sure these lines
are properly installed and that the compressor is getting the
proper supply of oil, and just as important, that the oil is
returning to the engine. Check the coolant lines to and from
the compressor and see that the cooling fins on the
crankcase are not clogged with dirt, grease, etc. Check the
unloader mechanism for proper and prompt operation.
OPERATING TESTS
Vehicles manufactured after the effective date of FMVSS
121, with the minimum required reservoir volume, must have
a compressor capable of raising air system pressure from
85-100 P.S.I. in 25 seconds or less. This test is performed
with the engine operating at maximum governed speed. The
vehicle manufacturer must certify this performance on new
vehicles with appropriate allowances for air systems with
greater than the minimum required reservoir volume.
AIR LEAKAGE TESTS
Leakage past the discharge valves can be detected by
removing the discharge line, applying shop air back through
the discharge port and listening for escaping air. Also, the
discharge valves and the unloader pistons can be checked
for leakage by building up the air system until the governor
cuts out, then stopping the engine. With the engine stopped,
listen for escaping air at the compressor intake. To pinpoint
leakage if noted, apply a small quantity of oil around the
unloader pistons. If there is no noticeable leakage at the
unloader pistons, the discharge valves may be leaking. If
the compressor does not function as described above, or
leakage is excessive, it is recommended that it be returned
to the nearest authorized Bendix Distributor for a factory
remanufactured compressor. If this is not possible, the
compressor can be repaired using genuine Bendix
replacement parts, in which case, the following information
should prove helpful.
REMOVING AND DISASSEMBLY
REMOVING
These instructions are general and are intended to be a
guide, in some cases additional preparations and precautions
are necessary. Chock the wheels of the vehicle and drain
the air pressure from all the reservoirs in the system. Drain
the engine cooling system and the cylinder head of the
compressor. Disconnect all air, water and oil lines leading
to and from the compressor. Remove the drive gear(s) or
pulley from the compressor crankshaft using a gear puller.
Inspect the pulley or gear and associated parts for visible
wear or damage. Since these parts are precision fitted, they
must be replaced if they are worn or damaged.
DISASSEMBLY
GENERAL
Remove road dirt and grease from the exterior of the
compressor with a cleaning solvent. Before the compressor
is disassembled, the following items should be marked to
show their relationship when the compressor is assembled.
Mark both the front and rear end cover in relation to the
crankcase. Mark the drive end of the crankshaft in relation
to the front end cover and the crankcase. Mark the cylinder
head in relation to the block and the block in relation to the
crankcase. Mark the base plate or base adapter in relation
to the crankcase.
7
A convenient method to indicate the above relationship is to
use a metal scribe to mark the parts with numbers or lines.
Do not use a marking method that can be wiped off or
obliterated during rebuilding, such as chalk. Remove all
compressor attachments such as governors, air strainers
or inlet fittings, discharge fittings and pipe plugs.
CYLINDER HEAD
Remove the six cylinder head cap screws (1) and tap the
head with a soft mallet to break the gasket seal. Remove
the inlet valve springs (2) and spring inserts (35) from the
head and inlet valves (3) from their guides in the block.
Remove inlet valve guides (4) from around the inlet valve
seats (34) on the block taking care not to damage seats.
Scrape off any gasket material (5) from the cylinder head
and block. Unscrew the discharge valve seats (6) from the
head and remove the discharge valves (7) and springs (8).
Inspect the discharge valve seats (2) for nicks, cracks, and
excessive wear and replace if necessary. The discharge valve
cap/nut stops (9) should be inspected for wear and replaced
if excessive peening has occurred. To determine if excessive
peening has occurred, measure the discharge valve travel.
Discharge valve travel must not exceed .046 inches. If
discharge valve travel is excessive, replace the cap nut/stop
assembly, discharge valve and spring.
Discard the inlet valves (3) and springs (2), the discharge
valves (7), springs (8) and the discharge valve seats (6) if
defective.
CRANKCASE BASE PLATE OR ADAPTER
Remove the cap screws securing the base plate or base
adapter. Tap with soft mallet to break the gasket seal (11).
Scrape off any gasket material from crankcase and plate or
adapter.
CONNECTING ROD ASSEMBLIES
(Note: Before removing the connecting rods, mark each
connecting rod and its cap. Each connecting rod is matched
to its own cap for proper bearing fit, and these parts must
not be interchanged.) Remove the connecting rod bolts (13)
and bearing caps (14). Push the piston (15) with the
connecting rods (16) attached out the top of the cylinders of
the cylinder block. Replace the bearing caps (14) on their
respective connecting rods. Remove the piston rings from
the pistons. If the pistons are to be removed from the
connecting rods, remove the teflon plugs (36) and press the
wrist pins (37) from the pistons and connecting rods.
FIGURE 8 - TU-FLO
®
700 AIR COMPRESSOR (THRU DRIVE) EXPLODED VIEW
34
35
36
28
REAR COVER
20
18
20
19
18
19
6
7
8
9
1
5
2
3
4
CYLINDER BLOCK
16
17
CRANKSHAFT
14
13
26
FLANGE
ADAPTER
21
24
25
29
30
REAR COVER
GASKET
31
32
11
27 22
26
10
12
CYLINDER HEAD
37
33
23
34
35
15
36
37
CRANKCASE
8
If the pistons are removed from the rod, inspect the bronze
wrist pin bushing. Press out and replace the bushing if it is
excessively worn. (See inspection of parts) Discard the piston
rings (18-20) and the connecting rod journal bearings (17).
Discard the wrist pin bushings (21) if they were removed.
CYLINDER BLOCK
If the compressor is fitted with an air strainer, inlet elbow or
governor remove the same.
Remove cap screws (23) securing cylinder block to the
crankcase; separate the crankcase and cylinder block and
scrape off any gasket material.
Remove the unloader spring (34), spring saddle (35), and
spring seat (36) from the inlet cavity of the crankcase, using
long nose pliers. With the use of shop air blow the unloader
plungers (37) and guides (33) out of the cylinder block.
The inlet valve seats can be removed if worn or damaged
and are being replaced. Unloader bore bushings should be
inspected but not removed unless they are damaged. If
bushings are to be replaced, they can be removed by running
a 1/8" pipe threaded rod and pulling the bushing straight up
and out. Do not use "easy out" for removing the bushings.
CRANKCASE
Remove the key (22) or keys from the crankshaft and any
burrs on the crankshaft where the key or keys were removed.
(Note: Through drive compressors may have a crankshaft
key at both ends.) Remove the four cap screws (23) securing
front or drive-end end cover or flange adapter. Remove the
end cover, taking care not to damage the crankshaft oil seal
(27) or front main bearing (26), if any. Remove the o-ring (24)
from around the front end cover. Remove the four cap screws
(30) securing the rear end cover and remove the rear end
cover taking care not to damage the rear main bearing (29),
if any. Remove the o-ring (31) from around the end cover. If
the compressor has ball type main bearings, press the
crankshaft and ball bearings from the crankcase, then press
the ball bearings from the crankshaft.
CLEANING OF PARTS
GENERAL
All parts should be cleaned in a good commercial grade
solvent and dried prior to inspection.
CYLINDER HEAD
Remove all the carbon deposits from the discharge cavities
and all the rust and scale from the cooling cavities of the
cylinder head body. Scrape all the foreign matter from the
body surfaces and use shop air pressure to blow the dirt
particles from all the cavities.
CYLINDER BLOCK
Clean the carbon and dirt from the inlet and unloader
passages. Use shop air pressure to blow the carbon and
dirt deposits from the unloader passages.
OIL PASSAGES
Thoroughly clean all oil passages through the crankshaft,
crankcase, end covers, and base plate or base adapter.
Inspect the passages with a wire to be sure. Blow the
loosened foreign matter out with air pressure.
INSPECTION OF PARTS
CYLINDER HEAD BODY
Inspect the cylinder head for cracks or damage. Apply shop
air pressure to one of the coolant ports with all others
plugged, and check for leakage by applying a soap solution
to the exterior of the body. If leakage is detected, replace
the head.
END COVERS
Check for cracks and external damage. If the crankshaft
main bearings are installed in the end cover, check for
excessive wear and flat spots and replace them if necessary.
If the compressor has an oil seal in the end cover, it should
be removed by pressing it out of the end cover.
CRANKCASE
Check all crankcase surfaces for cracks and damage. On
compressors where ball bearing main bearings are used the
difference between the O.D. of the outer race and the I.D. Of
the crankcase hole should be .0000 in. to .0015 in. loose.
This is to maintain the correct press fit. The crankcase must
be replaced if the fit is too loose.
On compressors fitted with precision, sleeve main bearings,
the difference between the O.D. of the crankshaft journal
and the main bearing I.D. must not exceed .0065 in. If the
clearance is greater than .0065 in., the end cover or main
bearing must be replaced.
CYLINDER BLOCK
Check the unloader bore bushings to be sure they are not
worn, rusted, or damaged. If these bushings are to be
replaced, they can be removed by running a 1/8 in. pipe
thread tap into the bushing, and inserting a 1/8 in. pipe
threaded rod and pulling the bushing straight up and out. Do
not use an easy-out for removing these bushings. If the inlet
valve seats are worn or damaged, so they cannot be
reclaimed by facing, they should be replaced. Cylinder bores
should be checked with inside micrometers or calipers (see
Figure 9). Cylinder bores which are scored or out of round
by more than .001 in. or tapered more than .002 in. should
9
CRANKSHAFT
Check the crankshaft threads, keyways, tapered ends and
all machined and ground surfaces for wear, scores, or
damage. Standard crankshaft journals are 1.1250 in.- 1.1242
in. in diameter. If the crankshaft journals are excessively
scored or worn or out of round and cannot be reground, the
crankshaft must be replaced. Connecting rod bearing inserts
are available in .010 in., .020 in. and .030 in. undersizes for
compressors with reground crankshafts. Main bearing
journals must be maintained so the ball bearings are a snug
fit or so that no more than .0065 in. clearance exists between
the precision sleeve main bearing and the main bearing
journals on the crankshaft. In crankshafts fitted with oil seal
rings, the oil seal ring groove or grooves must not be worn.
The ring groove walls must have a good finish and they must
be square. Check to be sure the oil passages are open
through the crankshaft.
CONNECTING ROD BEARINGS
Used bearing inserts must be replaced. Connecting rod caps
are not interchangeable. The locking slots of the connecting
rod and cap should be positioned adjacent to each other.
Clearance between the connecting journal and the
connecting rod bearing must not be less than .0003 in. or
more than .0021 in. after rebuilding.
be rebored or honed oversize. Oversized pistons and piston
rings are available in .010 in., .020 in. and .030 in. oversizes.
Cylinder bores must be smooth, straight, and round.
Clearance between the cast iron pistons and cylinder bores
should be between .002 in. minimum and .004 in. maximum.
FIGURE 9 - MEASURING CYLINDER BORES
FIGURE 10 - CORRECT GROOVE CLEARANCE
.002"
.010"
END GAP
.000
.006
OIL RING
.002
.004
OIL RING
STANDARD
PISTON
RING
OIL RING
PISTON
RINGS
PISTON
RING
EXPANDER
RING
PISTONS
Check the pistons for scores, cracks, or enlarged ring
grooves; replace the pistons if any of these conditions are
found. Measure each piston with a micrometer in relation to
the cylinder bore diameter to be sure the diametral clearance
is between .002 in. minimum and .004 in. maximum.
Check the fit of the wrist pins to the pistons and connecting
rod bushings. The wrist pin should be a light press fit in the
piston. If the wrist pin is a loose fit, the piston and pin
assembly should be replaced. Check the fit of the wrist pin
in the connecting rod bushing by rocking the piston. This
clearance should not exceed .0007 in. Replace the wrist pin
bushings if excessive clearance is found. Wrist pin bushings
should be reamed to between .5314 in. and .5317 in. after
being pressed into the connecting rods.
Check the fit of the piston rings in the piston ring grooves.
Check the ring gap with the rings installed in the cylinder
bores. Refer to Figure 10 for correct gap and groove
clearances.
10
REPAIRS
DISCHARGE VALVES, VALVE STOPS AND
SEATS
If the discharge valve seats merely show signs of slight wear,
they can be dressed by using a lapping stone, grinding
compound and grinding tool. Install the new discharge valve
springs and valves. Screw in the discharge valve seats.
Discharge valve travel should be between .030 in. to .046 in.
To test for leakage by the discharge valves, apply 100 pounds
of air pressure through the cylinder head discharge port and
apply a soap solution to the discharge valves and seats. A
slight leakage in the form of soap bubbles is permissible. If
excessive leakage is found, leave the air pressure applied
and with the use of a fiber or hardwood dowel and a hammer,
tap the discharge valves off their seats several times. This
will help the valves to seat and should reduce the leakage.
With the air pressure still applied at the discharge port of
the cylinder head, check for leakage around the discharge
valve cap nut on the top of the cylinder head casting. No
leakage is permitted.
INLET VALVES AND SEATS
Inlet valves and springs should be replaced, if the inlet valve
seats show signs of slight nicks or scratches. They can be
redressed with a fine piece of emery cloth or by lapping with
a lapping stone, grinding compound and grinding tool. If the
seats are damaged to the extent that they cannot be
reclaimed, they must be replaced. The dimension from the
top of the cylinder block to the inlet valve seat should not
exceed .113 in. nor be less than .101 in.
ASSEMBLY
General Note: All torques specified in this manual are
assembly torques and can be expected to fall off after
assembly is accomplished. Do not retorque after initial
assembly torques fall.
To convert inch pounds of torque to foot pounds of torque,
divide inch pounds by 12.
inch pounds ÷ 12 = foot pounds
To convert foot pounds of torque to inch pounds of torque,
multiply foot pounds by 12.
foot pounds x 12 = inch pounds
INSTALLING THE CRANKSHAFT
Press new sleeve bearings in the end cover and crankcase.
Ensure that the slot in the bearings line up with the oil
passages in the end cover or crankcase. If you have a model
with no oil passage present in the crankcase, press the
sleeve bearing into the crankcase with the slot located 90
degrees from vertical.
Install the front thrust washer with the tang inserted in the
slot toward the flange. Insert the crankshaft and the rear
thrust washer with the tang toward the rear of the compressor.
Place the oil seal ring on the boss of the rear end cover and
install the end cover making sure not to pinch the seal ring.
Ensure the tang of the thrust washer is inserted in the slot
of the end cover. Fasten the end cover to the crankcase with
the four cover cap screws. Torque the cap screws to 175-
225 inch pounds in a cross pattern. Note: For cast iron
flange adapters, torque the four 7/16 in. cap screws to 38-
45 foot pounds. For die cast aluminum end covers, torque
the four 7/16 in. cap screws to 25-30 foot pounds. All end
covers using 5/16 in. cap screws or stud and nuts are torqued
to 15-18 foot pounds. For through drive compressors with a
cast iron end cover, torque the four 7/16 in. cap screws to
25-30 foot pounds.
PISTONS AND CONNECTING RODS
If new wrist pin bushings are to be used, they should be
pressed into the connecting rods so that the oil hole in the
bushing lines up with the one in the rod. The new bushings
should then be reamed or honed to provide between .0001
in. (.00254 mm) and .0006 in. (.01524 mm) clearance on
the wrist pin. Position the connecting rod in the piston and
press in the wrist pin.
Pistons installed in compressors manufactured prior to
November, 1976, will have the wrist pin secured in the piston
by a lock wire extending through matching holes in wrist pin
and piston boss, anchored in a hole in the side wall of the
piston. If the original pistons are used the wrist pin must be
pressed in so the hole in the wrist pin aligns with that of the
FIGURE 11 FIGURE 12
DISCHARGE VALVE,
VALVE STOP
AND SEAT
INLET VALVE
AND SEAT
6
8
7
2
3
4
10
11
piston and secure same by inserting the new lockwire
through the hole in piston and wrist pin and lock the wire by
snapping the short 90 section into the lockwire hole in the
bottom of the piston.
Compressors built after November, 1976, will have the wrist
pin secured by Teflon buttons in either end of the wrist pin,
allowing the wrist pin to float. The Teflon buttons pc. no.
292392 may be used with either new or old wrist pins. The
later design pistons have two rings above the wrist pin and
one below. Install the piston rings in the correct location
with the ring pipmarks up. Stagger the position of the ring
gaps. Prelubricate the piston, piston rings, wrist pins and
connecting rod.
CYLINDER BLOCK
Align gasket (12), crankcase and cylinder block and secure
with cap screws (23). Torque to 15-19 foot pounds.
UNLOADER
A new unloader kit should used when rebuilding. (Figure
13). (Piece Number 279615). The unloader pistons in the kit
are prelubricated with a special lubricant piece number
239379 and need no additional lubrication. Install the unloader
pistons (28) in their bores being careful not to cut the
o-rings. Position the unloader plungers (37) in their guides
(38) and slip them in and over the tops of the pistons. Install
the unloader spring seat (36) in the cylinder block inlet cavity;
a small hole is drilled in the cylinder block for this purpose.
Position the saddle (35) between the unloader piston guides
(38), so its forks are centered on the guides. Install the
unloader spring (34), making sure it seats over the spring
seats both in the block and on the saddle. Position and
install the inlet valve guides (38), then drop the inlet valves in
their guides. The inlet valves should be a loose sliding fit in
the guides.
36
34
38
35
28
FIGURE 13 - UNLOADER MECHANISM
37
CYLINDER HEAD
Install the inlet valve springs in the cylinder head by applying
a turning motion to the spring after it is in the head. The
turning motion should dig the spring wire into the spring
seat in the bottom of the spring bore in the head. Should
this procedure fail after repeated attempts, use a very small
quantity of grease to hold them in place, just enough to
keep the springs from falling out. Place the cylinder head
gasket on the cylinder block. Carefully align the cylinder
head assembly on the block and install the cap screws,
tightening them evenly to a torque of 15-19 foot pounds.
BASE PLATE OR BASE ADAPTER
Position the base plate or base adapter gasket on the
crankcase and install the base plate or base adapter as
marked before disassembly. Tighten the six cap screws
securing the cast iron base adapter evenly to a torque of 38-
45 foot pounds, and 12-16 foot pounds for base plate or
aluminum cover.
TESTING REBUILT COMPRESSOR
In order to properly test a compressor under operating
conditions, a test rack for correct mounting, cooling,
lubricating, and driving the compressor is necessary. Such
tests are not compulsory if the unit has been carefully rebuilt
by an experienced person. A compressor efficiency or build-
up test can be run which is not too difficult. An engine
lubricated compressor must be connected to an oil supply
line of at least 15 P.S.I. pressure during the test and an oil
return line must be installed to keep the crankcase drained.
Connect to the compressor discharge port, a reservoir with
a volume of 1500 cubic inches, including the volume of
connecting line. With the compressor operating at 2100
R.P.M., the time required to raise the reservoir(s) pressure
from 85 P.S.I. to 100 P.S.I. should not exceed 7 seconds.
During this test, the compressor should be checked for
gasket leakage and noisy operation, as well as unloader
operation and leakage.
INSPECTION OF REBUILT UNIT
Check to be sure that covers, plugs, or masking tape are
used to protect all ports if compressor is not to be installed
immediately. Fit the end of all crankshafts with keys, nuts,
and cotter pins as required and then protect the ends against
damage by wrapping with masking tape or friction tape. The
open bottom of a vertical engine lubricated compressors
should be protected against the entrance of dirt during
handling or storage, by installing a temporary cover over the
base.
12
COMPRESSOR TROUBLESHOOTING
IMPORTANT: The troubleshooting contained in this section
considers the compressor as an integrated component of
the overall air brake charging system and assumes that an
air dryer is in use. The troubleshooting presented will cover
not only the compressor itself, but also other charging system
devices as they relate to the compressor.
WARNING! PLEASE READ AND FOLLOW
THESE INSTRUCTIONS TO AVOID
PERSONAL INJURY OR DEATH:
When working on or around a vehicle, the following
general precautions should be observed at all times.
1. Park the vehicle on a level surface, apply the
parking brakes, and always block the wheels.
Always wear safety glasses.
2. Stop the engine and remove ignition key when
working under or around the vehicle. When
working in the engine compartment, the engine
should be shut off and the ignition key should be
removed. Where circumstances require that the
engine be in operation, EXTREME CAUTION should
be used to prevent personal injury resulting from
contact with moving, rotating, leaking, heated or
electrically charged components.
3. Do not attempt to install, remove, disassemble or
assemble a component until you have read and
thoroughly understand the recommended
procedures. Use only the proper tools and observe
all precautions pertaining to use of those tools.
4. If the work is being performed on the vehicle’s air
brake system, or any auxiliary pressurized air
systems, make certain to drain the air pressure
from all reservoirs before beginning ANY work on
the vehicle. If the vehicle is equipped with an
AD-IS
air dryer system or a dryer reservoir module,
be sure to drain the purge reservoir.
5. Following the vehicle manufacturer’s
recommended procedures, deactivate the electrical
system in a manner that safely removes all electrical
power from the vehicle.
6. Never exceed manufacturer’s recommended
pressures.
7. Never connect or disconnect a hose or line
containing pressure; it may whip. Never remove a
component or plug unless you are certain all
system pressure has been depleted.
8. Use only genuine Bendix
®
replacement parts,
components and kits. Replacement hardware,
tubing, hose, fittings, etc. must be of equivalent
size, type and strength as original equipment and
be designed specifically for such applications and
systems.
9. Components with stripped threads or damaged
parts should be replaced rather than repaired. Do
not attempt repairs requiring machining or welding
unless specifically stated and approved by the
vehicle and component manufacturer.
10. Prior to returning the vehicle to service, make
certain all components and systems are restored to
their proper operating condition.
11. For vehicles with Antilock Traction Control (ATC),
the ATC function must be disabled (ATC indicator
lamp should be ON) prior to performing any vehicle
maintenance where one or more wheels on a
drive axle are lifted off the ground and moving.
TABULATED DATA
Number of cylinders ............................ 2
Bore size ............................................ 2.75 in.
Stroke ................................................. 1.81 in.
Piston displacement at 1250 RPM ...... 15.5 cu. ft.
Maximum recommended RPM
(naturally aspirated)............................. 3000
Minimum coolant flow at maximum
RPM ................................................... 2.5 gal./min.
Recommended minimum
discharge line size .............................. 5/8 in. OD
Copper Tube
Recommended minimum oil
return line size .................................... 5/8 in. OD Tubing
Recommended minimum oil
supply line size ................................... 1/4 in. OD Tubing
Recommended minimum unloader
line size .............................................. 1/4 in. OD Tubing
Recommended minimum coolant
line size .............................................. 1/2 in. OD Tubing
Recommended maximum inlet
air temperature .................................... 250°F
Recommended maximum
discharge air temperature .................... 40F
Minimum pressure required
to unload ............................................. 60 PSI
*This guide is only for vehicles that use desiccant air dryers.
The guide consists of an introduction to air brake charging system
components, a table showing recommended vehicle maintenance
schedules, and a troubleshooting symptom and remedy section with tests
to diagnose most charging system problems.
Advanced Troubleshooting Guide
for Air Brake Compressors
*
This troubleshooting guide obsoletes and supersedes all previous published
troubleshooting information relative to Bendix air compressors.
Air brake charging system:
Slow build (9.0) . . . . . . . . . . . . . . . . . 21 - 22
Doesn’t build air (10.0) . . . . . . . . . . . . . . . 23
Air dryer:
Doesn’t purge (14.0) . . . . . . . . . . . . . . . . . 24
Safety valve releases air (12.0). . . . . . . . . 24
Compressor:
Constantly cycles (15.0) . . . . . . . . . . . . . . 24
Leaks air (16.0) . . . . . . . . . . . . . . . . . . . . . 25
Safety valve releases air (11.0) . . . . . . . . . 23
Noisy (18.0) . . . . . . . . . . . . . . . . . . . . . . . . 25
Reservoir:
Safety valve releases air (13.0). . . . . . . . . 24
INDEX
Air
Coolant
Engine
Oil
Compressor leaks coolant (17.0) . . . . . . . . . . 25
Oil consumption (6.0) . . . . . . . . . . . . . . . . . . . 21
Oil Test Card results (1.0) . . . . . . . . . . . . . . . . 16
Oil is present:
On the outside of the compressor (2.0). . . 17
At the air dryer purge/exhaust
or surrounding area (3.0) . . . . . . . . . . . 17
In the supply reservoir (4.0). . . . . . . . 18 - 20
At the valves (5.0) . . . . . . . . . . . . . . . . . . . 20
At air dryer cartridge (7.0) . . . . . . . . . . . . . 21
In the ping tank or compressor
discharge aftercooler (8.0) . . . . . . . . . . 21
Symptom Page Number
(1) Oil Leakage at Head Gasket . . .26
(2) System Leakage . . . . . . . . . . . .26
(3) Compressor Discharge and
Air Dryer Inlet Temperature . . . .26
(4) Governor Malfunction . . . . . . . .27
(5) Governor Control Line . . . . . . . .27
(6) Compressor Unloader . . . . . . . .27
BASIC Test Information . . . . . . 28-30
Test Procedures
Maintenance Schedule and
Usage Guidelines (Table A) . . 15
Symptom Page Number
Maintenance & Usage Guidelines
13
14
Introduction to the Air Brake Charging System
Powered by the vehicle engine, the air compressor
builds the air pressure for the air brake system. The
air compressor is typically cooled by the engine coolant
system and lubricated by the engine oil supply.
The compressor's unloader mechanism and governor
(along with a synchro valve for the Bendix
®
DuraFlo
596
air compressor) control the brake system air
pressure between a preset maximum and minimum
pressure level by monitoring the pressure in the service
(or “supply”) reservoir. When the air pressure becomes
greater than that of the preset “cut-out”, the governor
controls the unloader mechanism of the compressor
to stop the compressor from building air and also
causes the air dryer to purge. As the service reservoir
air pressure drops to the “cut-in” setting of the governor,
the governor returns the compressor back to building
air and the air dryer to air drying mode.
As the atmospheric air is compressed, all the water
vapor originally in the air is carried along into the air
system, as well as a small amount of the lubricating oil
as vapor.
The duty cycle is the ratio of time the compressor
spends building air to the total engine running time.
Air compressors are designed to build air (run “loaded”)
up to 25% of the time. Higher duty cycles cause
conditions that affect air brake charging system
performance which may require additional
maintenance. Factors that add to the duty cycle are:
air suspension, additional air accessories, use of an
undersized compressor, frequent stops, excessive
leakage from fittings, connections, lines, chambers or
valves, etc.
The discharge line allows the air, water-vapor and
oil-vapor mixture to cool between the compressor and
air dryer. The typical size of a vehicle's discharge line,
(see column 2 of Table A on page 15) assumes a
compressor with a normal (less than 25%) duty cycle,
operating in a temperate climate. See Bendix and/or
other air dryer manufacturer guidelines as needed.
When the temperature of the compressed air that enters
the air dryer is within the normal range, the air dryer can
remove most of the charging system oil. If the
temperature of the compressed air is above the normal
range, oil as oil-vapor is able to pass through the air
dryer and into the air system. Larger diameter discharge
lines and/or longer discharge line lengths can help reduce
the temperature.
The discharge line must maintain a constant slope
down from the compressor to the air dryer inlet fitting
to avoid low points where ice may form and block the
flow. If, instead, ice blockages occur at the air dryer
inlet, insulation may be added here, or if the inlet fitting
is a typical 90 degree fitting, it may be changed to a
straight or 45 degree fitting. For more information on
how to help prevent discharge line freeze-ups, see
Bendix Bulletins TCH-08-21 and TCH-08-22 (see
pages 31-33). Shorter discharge line lengths or
insulation may be required in cold climates.
The air dryer contains a filter that collects oil droplets,
and a desiccant bed that removes almost all of the
remaining water vapor. The compressed air is then
passed to the air brake service (supply) reservoir. The
oil droplets and the water collected are automatically
purged when the governor reaches its “cut-out” setting.
For vehicles with accessories that are sensitive to small
amounts of oil, we recommended installation of a
Bendix
®
PuraGuard
®
system filter, designed to minimize
the amount of oil present.
Air Dryer
Reservoir Drain
Service Reservoir
(Supply Reservoir)
Compressor
Governor
(Governor plus Synchro valve
for the Bendix
®
DuraFlo
596
Compressor)
Discharge
Line
Optional “Ping” Tank
Optional Bendix
®
PuraGuard
®
System Filter or PuraGuard
®
QC
Oil Coalescing Filter
The Air Brake Charging System supplies the
compressed air for the braking system as well as other
air accessories for the vehicle. The system usually
consists of an air compressor, governor, discharge line,
air dryer, and service reservoir.
15
Compressor with up to 25% duty cycle
Footnotes:
1 With increased air demand the air dryer cartridge needs to be replaced more often.
2 Use the drain valves to slowly drain all reservoirs to zero psi.
3 Allow the oil/water mixture to fully settle before measuring oil quantity.
4 To counter above normal temperatures at the air dryer inlet, (and resultant oil-vapor passing
upstream in the air system) replace the discharge line with one of a larger diameter and/
or longer length. This helps reduce the air's temperature. If sufficient cooling occurs, the
oil-vapor condenses and can be removed by the air dryer. Discharge line upgrades are not
covered under warranty. Note: To help prevent discharge line freeze-ups, shorter discharge
line lengths or insulation may be required in cold climates. (See Bendix Bulletins TCH-08-21
and TCH-08-22, included in Appendix B, for more information.)
5 For certain vehicles/applications, where turbo-charged inlet air is used, a smaller size
compressor may be permissible.
Recom- Recom- Acceptable
Typical Discharge mended mended Reservoir
Compressors Line Air Dryer Reservoir Oil Contents
3
No. of Spec'd Cartridge Drain at Regular
Axles Replacement
1
Schedule
2
Drain Interval
High Air Use
Low Air Use
e.g. Double/triple trailer, open
highway coach/RV, (most)
pick-up & delivery, yard or
terminal jockey, off-highway,
construction, loggers, concrete
mixer, dump truck, fire truck.
e.g. Line haul single trailer
w/o air suspension, air over
hydraulic brakes.
e.g. Line haul single trailer
with air suspension,
school bus.
e.g. City transit bus, refuse,
bulk unloaders, low boys,
urban region coach, central
tire inflation.
5
or
less
5
or
less
8
or
less
12
or
less
Table A: Maintenance Schedule and Usage Guidelines
Recom-
mended
Every
Month -
Max of
every 90
days
Every
Month
Every 3
Years
Every 2
Years
Every
Year
I.D.
Vehicle Used for:
Column 1
Column 2 Column 3 Column 4 Column 5
Regularly scheduled maintenance is the single most important factor in maintaining the air brake charging system.
Note: Compressor and/or air dryer
upgrades are recommended in cases
where duty cycle is greater than the
normal range (for the examples
above).
For Bendix
®
Tu-Flo
®
550 and 750
compressors, unloader service is
recommended every 250,000 miles.
Length
6 ft.
1/2 in.
9 ft.1/2 in.
12 ft.
1/2 in.
5/8 in.
12 ft.
BASIC test
acceptable
range:
5 oil units
per month.
See
appendix
A.
For oil carry-over
control
4
suggested
upgrades:
3/4 in. 15 ft.
For oil carry-over
control
4
suggested
upgrades:
5/8 in. 15 ft.
For oil carry-over
control
4
suggested
upgrades:
5/8 in. 9 ft.
For oil carry-over
control
4
suggested
upgrades:
5/8 in. 12 ft.
Compressor with less than 15% duty
cycle
Compressor with up to 25% duty cycle
Compressor with up to 25% duty cycle
Bendix
®
BA-921
air compressor
Bendix
®
Tu-Flo
®
550 air compressor
Bendix
®
Tu-Flo
®
750 air compressor
Bendix
®
BA-922
, or DuraFlo
596
air compressor
BASIC test
acceptable
range:
3 oil units
per month.
See
appendix
A.
For the
BASIC
Test Kit:
Order
Bendix
P/N
5013711
16
ü
Air Brake Charging System Troubleshooting
How to use this guide:
1.0 Oil Test Card
Results
Not a valid test.
Discontinue using this test.
Do not use this card test to diagnose
compressor "oil passing" issues. They are
subjective and error prone. Use only the
Bendix Air System Inspection Cup (BASIC) test
and the methods described in this guide for
advanced troubleshooting.
The Bendix
®
BASIC test should be the
definitive method for judging excessive oil
fouling/oil passing. (See Appendix A, on
page 28 for a flowchart and expanded
explanation of the checklist used when
conducting the BASIC test.)
Symptom: What it may indicate: What you should do:
Find the symptom(s) that you see, then move to the right to
find the possible causes (“What it may indicate”) and
remedies (“What you should do”).
Review the warranty policy before performing any intrusive
compressor maintenance. Unloader or cylinder head gasket
replacement and resealing of the bottom cover plate are
usually permitted under warranty. Follow all standard safety
procedures when performing any maintenance.
Look for:
Normal - Charging system is working within
normal range.
Check - Charging system needs further
investigation.
û
Bendix
®
BASIC Test
WARNING! Please READ and follow these instructions to
avoid personal injury or death:
When working on or around a vehicle, the following general
precautions should be observed at all times.
1. Park the vehicle on a level surface, apply the parking
brakes, and always block the wheels. Always wear safety
glasses.
2. Stop the engine and remove ignition key when working
under or around the vehicle. When working in the engine
compartment, the engine should be shut off and the ignition
key should be removed. Where circumstances require that
the engine be in operation, EXTREME CAUTION should
be used to prevent personal injury resulting from contact
with moving, rotating, leaking, heated or electrically charged
components.
3. Do not attempt to install, remove, disassemble or assemble
a component until you have read and thoroughly
understand the recommended procedures. Use only the
proper tools and observe all precautions pertaining to use
of those tools.
4. If the work is being performed on the vehicle’s air brake
system, or any auxiliary pressurized air systems, make
certain to drain the air pressure from all reservoirs before
beginning ANY work on the vehicle. If the vehicle is
equipped with an AD-IS
air dryer system or a dryer
reservoir module, be sure to drain the purge reservoir.
5. Following the vehicle manufacturer’s recommended
procedures, deactivate the electrical system in a manner
that safely removes all electrical power from the vehicle.
6. Never exceed manufacturer’s recommended pressures.
7. Never connect or disconnect a hose or line containing
pressure; it may whip. Never remove a component or plug
unless you are certain all system pressure has been
depleted.
8. Use only genuine Bendix
®
replacement parts, components
and kits. Replacement hardware, tubing, hose, fittings, etc.
must be of equivalent size, type and strength as original
equipment and be designed specifically for such
applications and systems.
9. Components with stripped threads or damaged parts
should be replaced rather than repaired. Do not attempt
repairs requiring machining or welding unless specifically
stated and approved by the vehicle and component
manufacturer.
10.Prior to returning the vehicle to service, make certain all
components and systems are restored to their proper
operating condition.
11. For vehicles with Antilock Traction Control (ATC), the ATC
function must be disabled (ATC indicator lamp should be
ON) prior to performing any vehicle maintenance where
one or more wheels on a drive axle are lifted off the ground
and moving.
Symptom: What it may indicate: What you should do:
17
2.2 Oil leaking
from compressor:
(a)Excessive leak at head gasket.
(b)Leak at bottom cover plate.
(c)Leak at internal rear flange gasket.
(d)Leak through crankcase.
(e)(If unable to tell source of leak.)
ð Go to Test 1 on page 26.
ð Reseal bottom cover plate using RTV
silicone sealant.
ð Replace compressor.
ð Replace compressor.
ð Clean compressor and check periodically.
Air brake charging system functioning
normally.
ð Air dryers remove water and oil from the
air brake charging system.
Check that regular maintenance is being
performed. Return the vehicle to service.
An optional kit (Bendix piece number
5011327 for the Bendix
®
AD-IS
or AD-IP
air dryers, or 5003838 for the Bendix
®
AD-9
air dryer) is available to redirect the
air dryer exhaust.
3.0 Oil at air dryer
purge/exhaust or
surrounding area
(c)
2.0 Oil on the
Outside of the
Compressor
Find the source and repair. Return the vehicle
to service.
ð Repair or replace as necessary. If the
mounting bolt torques are low, replace the
gasket.
ð Replace the fitting gasket. Inspect inlet
hose and replace as necessary.
ð Replace gasket or fitting as necessary to
ensure good seal.
ð Inspect and repair as necessary.
Engine and/or other accessories
leaking onto compressor.
(a)Leak at the front or rear (fuel
pump, etc.) mounting flange.
(b)Leak at air inlet fitting.
(c)Leak at air discharge fitting.
(d)Loose/broken oil line fittings.
2.1 Oil leaking at
compressor / engine
connections:
(a)
ð
ð
Head
gasket
and rear
flange
gasket
locations.
(c)
18
4.0 Oil in Supply or
Service Reservoir
(air dryer installed)
(If a maintained Bendix
®
PuraGuard
®
system filter
or Bendix
®
PuraGuard
®
QC
oil coalescing filter
is installed, call
1-800-AIR-BRAKE
(1-800-247-2725) and
speak to a Tech Team
member.)
(a)If air brake charging system
maintenance has not been
performed.
That is, reservoir(s) have not been
drained per the schedule in Table
A on page 15, Column 4 and/or the
air dryer maintenance has not
been performed as in Column 3.
(b)If the vehicle maintenance has
been performed as recom-
mended in Table A on page 15,
some oil in the reservoirs is normal.
ð Drain all air tanks and check vehicle at next
service interval using the Bendix
®
BASIC
test. See Table A on page 15, column 3
and 4, for recommended service schedule.
ð Drain all air tanks into Bendix
®
BASIC test
cup (Bendix Air System Inspection Cup).
If less than one unit of reservoir contents
is found, the vehicle can be returned to
service. Note: If more than one oil unit
of water (or a cloudy emulsion mixture)
is present, change the vehicle's air
dryer, check for air system leakage (Test
2, on page 26), stop inspection and
check again at the next service interval.
See the BASIC test kit for full details.
If less than one "oil unit" of water (or water/
cloudy emulsion mixture) is present, use
the BASIC cup chart on the label of the
cup to determine if the amount of oil found
is within the acceptable level.
ðIf within the normal range, return the
vehicle to service. For vehicles with
accessories that are sensitive to small
amounts of oil, consider a Bendix
®
PuraGuard
®
QC
oil coalescing filter.
ð If outside the normal range go to
Symptom 4.0(c).
Also see the Table A on page 15, column
3 for recommended air dryer cartridge
replacement schedule.
Maintenance
(a)
ð Go to
Test 2 on page 26.
ð See Table A, column 1, on page 15 for
recommended compressor sizes.
ð If the compressor is "too small" for
the vehicle's role (for example, where a
vehicle's use has changed or service
conditions exceed the original vehicle or
engine OE spec's) then upgrade the
compressor. Note: The costs incurred (e.g.
installing a larger capacity compressor,
etc.) are not covered under original
compressor warranty.
ð If the compressor is correct for the
vehicle, go to Symptom 4.0 (e).
Duty cycle too high
Symptom: What it may indicate: What you should do:
See Table A, on page 15,
for maintenance
schedule information.
Drain
all air tanks (reservoirs)
into the Bendix
®
BASIC test
cup. (Bendix kit P/N 5013711).
The duty cycle is the ratio of time the compressor spends
building air to total engine running time. Air compressors
are designed to build air (to "run loaded") up to 25% of the
time. Higher duty cycles cause conditions that affect air
brake charging system performance which may require
additional maintenance. Factors that add to the duty cycle
are: air suspension, additional air accessories, use of an
undersized compressor, frequent stops, excessive leakage
from fittings, connections, lines, chambers or valves, etc.
(c)Air brake system leakage.
(d)Compressor may be undersized for
the application.
Symptom: What it may indicate: What you should do:
19
(e)Air compressor discharge and/or
air dryer inlet temperature too high.
(f) Insufficient coolant flow.
(g)Restricted discharge line.
ð Check temperature as outlined in Test 3
on page 26. If temperatures are normal
go to 4.0(h).
ð Inspect coolant line. Replace as necessary
(I.D. is 1/2").
ð Inspect the coolant lines for kinks and
restrictions and fittings for restrictions.
Replace as necessary.
ð Verify coolant lines go from engine block
to compressor and back to the water pump.
Repair as necessary.
ð If discharge line is restricted or more than
1/16" carbon build up is found, replace the
discharge line. See Table A, column 2, on
page 15 for recommended size. Replace
as necessary.
ð The discharge line must maintain a
constant slope down from the compressor
to the air dryer inlet fitting to avoid low
points where ice may form and block the
flow. If, instead, ice blockages occur at the
air dryer inlet, insulation may be added
here, or if the inlet fitting is a typical 90
degree fitting, it may be changed to a
straight or 45 degree fitting. For more
information on how to help prevent discharge
line freeze-ups, see Bendix Bulletins
TCH-08-21 and TCH-08-22 (Appendix B).
Shorter discharge line lengths or insulation
may be required in cold climates.
Temperature
Other
ð Check compressor air inlet line for
restrictions, brittleness, soft or sagging
hose conditions etc. Repair as necessary.
Inlet line size is 3/4 ID. Maximum
restriction requirement for compressors is
25 inches of water.
ð Check the engine air filter and service if
necessary (if possible, check the air filter
usage indicator).
(h)Restricted air inlet (not enough air
to compressor).
(g)
(h)
4.0 Oil in Supply
or Service
Reservoir*
(air dryer installed)
(continued)
(f)
(e)
(g)
Kinked discharge line shown.
Partly
collapsed
inlet line
shown.
Testing the temperature
at the discharge fitting.
Inspecting the coolant hoses.
*If a maintained Bendix
®
PuraGuard
®
system filter or Bendix
®
PuraGuard
®
QC
oil coalescing
filter is installed, call 1-800-AIR-BRAKE (1-800-247-2725) and speak to a Tech Team
member.
Symptom: What it may indicate: What you should do:
20
(i) Poorly filtered inlet air (poor air
quality to compressor).
(j) Governor malfunction or setting.
(k)Compressor malfunction.
4.0 Oil in Supply
or Service
Reservoir*
(air dryer installed)
(continued)
ð Check for leaking, damaged or defective
compressor air inlet components (e.g.
induction line, fittings, gaskets, filter bodies,
etc.). Repair inlet components as needed.
Note: Dirt ingestion will damage
compressor and is not covered under
warranty.
ð Go to Test 4 on page 27.
ð If you found excessive oil present in the
service reservoir in step 4.0 (b) above and
you did not find any issues in steps 4.0 (c)
through 4.0 (j) above, the compressor may
be passing oil.
Replace compressor. If still under
warranty, follow normal warranty process.
Note: After replacing a compressor,
residual oil may take a considerable period
of time to be flushed from the air brake
system.
Other (cont.)
Inspect the
engine air
cleaner.
** SAE J2024 outlines tests all air brake system pneumatic
components need to be able to pass, including minimum
levels of tolerance to contamination.
5.0 Oil present at
valves (e.g. at
exhaust, or seen
during servicing).
Air brake system valves are required
to tolerate a light coating of oil.
ð A small amount of oil does not affect SAE
J2024** compliant valves.
ð Check that regular maintenance is being
performed and that the amount of oil in the
air tanks (reservoirs) is within the
acceptable range shown on the Bendix
®
BASIC test cup (see also column 5 of Table
A on page 15). Return the vehicle to
service.
For oil-sensitive systems, see page 14.
Genuine
Bendix
valves are
all SAE
J2024
compliant.
*If a maintained Bendix
®
PuraGuard
®
system filter or Bendix
®
PuraGuard
®
QC
oil coalescing
filter is installed, call 1-800-AIR-BRAKE (1-800-247-2725) and speak to a Tech Team
member.
Crankcase Flooding
Consider installing a compressor bottom drain kit
(where available) in cases of chronic oil passing
where all other operating conditions have been
investigated. Bendix compressors are designed to
have a 'dry' sump and the presence of excess oil in
the crankcase can lead to oil carryover.
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BENDIX BW1422 Manuale utente

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