Land Rover Lesson 2 Auto Trans Coolingine Rover Manual

							FUEL TANK ASSEMBLY
Tank breather pipe1
Fuel pump module assembly2
Vent pipe3
Pump module clamp4
Pump module collar5
Pump module seal6
FBH pump feed pipe (if fitted)7
Pipe - Fuel return8
Pipe - Fuel feed9
Cradle10
Fuel feed pipe connection11
Fuel return pipe connection12
Mounting bolt (6 off)13
FBH feed pipe connection (if fitted)14
Fuel filler hose15
Fuel tank16
Heat shield17
The fuel tank is located on the right hand side of the
vehicle, between the transmission and the right hand
chassis longitudinal. The tank is located on a mounting
cradle which secures the whole fuel tank assembly to
the vehicle. The tank has a useable capacity of 82.0
liters (18 gallons).
The cradle is attached to the chassis with six screws.
When the cradle is attached to the chassis, the tank is
positively secured via foam pads which bear against the
central chassis cross beam. A protective cover is fitted
to the front right hand corner of the tank and provides
additional protection.
Fuel Tank and LinesLesson 2 – Powertrain
357Technical Training (G421197) 
						

							The fuel tank is manufactured from moulded plastic
which is a minimum of 3 mm thick. The tank is a sealed
unit with the only internal access being via the pump
module flange aperture on the top of the tank.
The flange assembly comprises a pump module flange
which contains all external pipe and electrical
connections for the tank internal components, a collar
and a clamp. The flange is fitted with a seal which
locates in the tank aperture. An arrow on the flange must
be aligned between two moulded lines on the tank,
adjacent to the pump module flange aperture, to obtain
the correct orientation of the flange. The collar is located
over the flange and is secured with the clamp.
The flange has a six pin external connector which
provides for electrical connections for the level sensors
and the fuel pump. This connector is wired to three push
fit connectors on the underside of the flange. Two quick
release connectors provide for the connection of the fuel
feed and return pipes and the vent pipes. The fuel return
connection contains a non return valve which prevents
fuel escaping from the connection in the event of a
vehicle roll over and the pipe becoming detached. On
vehicles with a fuel burning heater, a third connection
provides the connection for the fuel feed supply to the
fuel burning heater.
A tank carrier assembly is attached inside the tank and
is used to locate the internal tank components. The
carrier provides location for the fuel pump module, the
front level sensor, the Roll Over Valves (ROVs) and
the front jet pump.
The fuel pump module contains a number of
components. The module comprises the fuel pump, the
rear fuel level sensor, the rear jet pump, the pump inlet
filter and the fuel pressure regulator which is mounted
in a manifold which is attached on the carrier. Only the
pump module assembly and the fuel level sensors are
available as serviceable components, the individual
assembly components are not available separately.
(G421197) Technical Training358
Lesson 2 – PowertrainFuel Tank and Lines 
						

							Fuel Tank Internal Components
Carrier assembly1
Front ROV corrugated tube2
Liquid Vapor Separator (LVS)3
Rear Roll Over Valve (ROV)4
Fuel pump module5
Rear fuel level sensor6
Tank breather corrugated tube7
Tank breather connection8
Front fuel level sensor9
Front ROV10
Front jet pump11
The TdV6 vent system is different to the system used
on the petrol models. The TdV6 vent system comprises:
•two Roll Over Valves (ROV)
•one Liquid Vapor Separator (LVS)
•breather spout.
The vent system is mounted on the fuel tank internal
carrier which is assembled outside of the tank and
inserted into the tank during the blow moulding process.
None of the internal tank venting components are
serviceable.
The rear ROV is mounted in the rear right hand corner
of the fuel tank. It is mounted directly onto the LVS
with a rubber grommet and secured with a clip.
Fuel Tank and LinesLesson 2 – Powertrain
359Technical Training (G421197) 
						

							The front ROV is located in the front left hand corner
of the tank. It is attached by a moulded clip to the main
beam of the carrier. The ROV is connected to the LVS
by a corrugated tube.
Both ROVs vent directly into the LVS. Any liquid fuel
is separated from the vapor in the LVS and drains back
into the tank via the front ROV.
The LVS vent outlet is connected to the underside of
the tank flange. The vent line is then routed from the
flange to atmosphere at the top of the filler neck. This
line allows for pressure and vacuum relief during normal
tank operation. It also allows air to enter the tank as fuel
is used.
The main purpose of the tank breather connection is to
control the fill volume of the tank. During filling, vapor
exits the fuel tank via the breather connection and the
breather tube to the filler neck. When the tank reaches
its full level, the liquid fuel closes off the breather
connection by filling it with fuel. The closure of the
breather connection causes the back pressure in the tank
to increase, which in turn causes the pump filling nozzle
to turn off.
Fuel Pump Module
The fuel pump is attached to the carrier and is located
at the bottom of the swirl pot. The pump and the fuel
level sensors are connected to the external electrical
connector via the connectors on the underside of the
fuel pump module flange.
The pump module has a rated flow of 70 liters/hour
(18.5 US gallons/hour) at a voltage of 12.3V and an
output pressure of 0.5 bar (7.25 lbf/in2).
The fuel pump is energised by the fuel pump relay which
is located in the battery junction box. The relay is
controlled by the engine control module and energises
the relay at all times when the ignition switch is in
ignition position II.
A filter is attached to pump inlet port at the bottom of
the pump. The filter has a winged section which is
located vertically at the side of the pump to ensure that
a portion of the filter is off the base of the swirl pot, to
prevent premature blocking of the filter. The filter has
two sections, a normal filter and a by-pass filter. The
normal filter is a 31 micron fine mesh filter with a
surface area of 70 cm2 (10.8 in2). The by-pass filter is
a 300 micron coarse mesh filter which is closed in
normal conditions and has a surface area of 4 cm2 (0.62
in2). In cold conditions, waxing of the fuel can occur
which can restrict fuel passing through the fine mesh
filter. If this occurs, the by-pass opens allowing fuel to
pass through the coarse mesh filter.
The top face of the fuel pump module has three pipe
connections. One connection is the fuel pump outlet
connection which feeds into the manifold. A second
connection allows fuel at pump outlet pressure to flow
back through the pump module housing from the
manifold to the rear jet pump. The third connection
allows fuel from the pressure regulator to return to the
swirlpot when the regulator has opened due to excessive
pump output pressure.
Fuel Level Sensors
The sensor is a MAgnetic Passive Position Sensor
(MAPPS) which provides a variable resistance to earth
for the output from the fuel gauge. The sensor is sealed
from the fuel preventing contamination of the contacts,
increasing reliability. The front and rear fuel level
sensors are connected to the external electrical connector
on the flange via the connectors on the underside of the
fuel pump module flange.
The front sensor is attached to the front of the carrier
and is accessible via the fuel pump flange aperture. The
rear sensor is attached to the side of the swirl pot and
is also accessible via the flange aperture.
(G421197) Technical Training360
Lesson 2 – PowertrainFuel Tank and Lines 
						

							The sensor comprises a series of 51 film resistors
mounted in an arc on a ceramic surface. The resistors
are wired in series with individual contacts. A soft
magnetic foil with 51 flexible contacts is mounted a
small distance above the film resistors. A magnet,
located below the ceramic surface, is attached to the
sender unit float arm. As the float arm moves the magnet
follows the same arc as the film resistors. The magnet
pulls the flexible contacts onto the opposite film resistor
contacts forming an electrical circuit.
Sensor Operating Principle
Magnetic foil1
Spacer2
Ceramic surface3
Magnet4
Resistance film5
The film resistors are arranged in a linear arc with
resistance ranging from 51.2 to 992.11 Ohms. The
electrical output signal is output proportional to the
amount of fuel in the tank and the position of the float
arm. The measured resistance is processed by the
instrument pack to implement an anti-slosh function.
This monitors the signal and updates the fuel gauge
pointer position at regular intervals, preventing constant
pointer movement caused by fuel movement in the tank
due to cornering or braking.
A warning lamp is incorporated in the instrument cluster
and illuminates when the fuel level is at or below 10
liters (2.64 US gallons).
The fuel level sender signal is converted into a CAN
message by the instrument pack as a direct interpretation
of the fuel tank contents in liters.
Front Fuel Level Sensor Resistance/Fuel Gauge Read
out Table
Nominal Gauge
Reading
Sender Unit Resist-
ance, Ohms
NOTE: These figures are with the vehicle on level
ground. Sensor readings will differ with varying
vehicle inclinations.
Empty51.2
Low fuel level illumina-
tion (17L)
67
Half full281
Full872
Rear Fuel Level Sensor Resistance/Fuel Gauge Read
out Table
Nominal Gauge
Reading
Sender Unit Resist-
ance, Ohms
NOTE: These figures are with the vehicle on level
ground. Sensor readings will differ with varying
vehicle inclinations.
Empty75
Low fuel level illumina-
tion (17L)
150
Half full267
Full768
Fuel Pressure Regulator
The fuel pressure regulator is located in the manifold
inside the fuel tank. The regulator controls the fuel
pressure in the feed pipe to the HP injection pump. If
Fuel Tank and LinesLesson 2 – Powertrain
361Technical Training (G421197) 
						

							the pump outlet pressure becomes too high, the regulator
controls the fuel pressure in the feed pipe by allowing
some fuel to return to the swirl pot.
The regulator is subject to pump output pressure and
controls the pressure of the fuel delivered to the HP
injection pump to a maximum of 0.5 bar (7.25 lbf/in2).
At pressures above this figure, the regulator opens,
decaying the pressure supplied to the HP injection pump
by allowing fuel to flow back into the swirl pot. The
primary reason for the regulator is to protect the HP fuel
injection pump from high fuel input pressures from the
LP fuel pump if a high voltage condition occurs.
Swirl Pot
The swirl pot is located at the rear of the fuel tank and
provides for the attachment or location of most of the
fuel pump assembly components.
The swirl pot acts as a fuel reserve, providing a constant
supply of fuel to the fuel pump irrespective of fuel
quantity or vehicle attitude. When the vehicle is level
the swirl pot contains approximately 400 cm3 (24.4 in3)
of fuel when the engine is running. The two jet pumps
ensure that fuel is constantly supplied to the swirl pot
to provide a sufficient fuel supply for the pump.
A one way valve is located in the base of the swirl pot.
The valve allows fuel from the tank to enter the swirl
pot, but prevents it from escaping.
Jet Pumps
The fuel system incorporates two jet pumps. The front
jet pump is located on the carrier near the front of the
fuel tank. The rear jet pump is located in the swirl pot
below the fuel pump. Both jet pumps operate on a
venturi effect created by fuel at pump output pressure
passing through the jet pump. This draws additional fuel
from the tank through ports in the jet pump body,
delivering additional fuel to the swirl pot.
The front jet pump is mainly used when the vehicle is
driving downhill. The jet pump is connected via a pipe
from the fuel manifold and receives fuel at pump output
pressure. Because of its location at the front of the tank,
it collects fuel from the front of the tank and transfers
it into the swirl pot, ensuring a constant supply of fuel
to the pump. The jet pump has a jet nozzle of 1 mm
diameter.
The rear jet pump operates at pump output pressure and
delivers some of the fuel from the rear of the tank back
into the swirl pot.
Roll Over Valves (ROVs)
Two ROVs are located on the carrier and are connected
via pipes to a liquid vapour separator. The separator,
which is also attached to the carrier, is connected via a
pipe to the tank breather outlet in the pump module
flange. The ROVs contain non-return valves which close
in the event of the vehicle overturning, preventing liquid
fuel escaping from the tank via the breather pipe.
(G421197) Technical Training362
Lesson 2 – PowertrainFuel Tank and Lines 
						

							FUEL FILTER
Screw M8 (2 off)1
Bracket2
Fuel feed to engine (HP injection pump)3
Fuel return from cooler4
Fuel return/air bleed to tank5
Water drain valve6
Filter canister7
Clamp bracket8
Fuel feed from pump module9
The fuel filter is located behind the fuel cooler, at the
rear of the engine and is protected by the engine
undertray. The fuel filter assembly comprises a bracket
and the filtration element which is contained within a
canister.
The filter canister is attached to a circular bracket which
is clamped around the filter canister with a bolt and nut.
The bracket is attached on the inside of the right hand
chassis rail with two screws. Removal of the fuel filter
requires loosening of the bolt and nut and removing the
filter canister from the circular bracket.
The filter element has a capacity of 500 cm3 (30.5 in3).
The filtration element can filter particulate matter larger
than 2 microns. A water drain plug is located on the
base of the filter. The filter can be purged of water by
partially unscrewing the filter element plug and allowing
fuel to drain into a suitable container. The plug must
tightened to a torque specified in the Service Repair
Manual.
Fuel Tank and LinesLesson 2 – Powertrain
363Technical Training (G421197) 
						

							FUEL FILLER
Bracket1
Screw M62
Rear differential breather pipe (Ref.)3
Filler cap lanyard4
Tank breather pipe5
Clamp - filler hose6
Vent pipe7
Filler cap8
Screw M89
Filler pipe10
Lower mounting bracket to EPB bracket11
The fuel filler head is positioned at the rear of the
vehicle, above the right hand rear wheel. The filler head
is covered by a moulded plastic cover which is
electrically locked when the vehicle is locked. The filler
cap is a conventional screw in type which is secured to
the vehicle with a lanyard.
NOTE: The fuel filler head plastic cover does not lock
on NAS vehicles.
The filler head is a stainless steel fabrication. Two
brackets provide for the attachment of the filler head to
the vehicle body and the chassis electronic park brake
bracket.
A connection on the rear of the filler head allows for
the connection of the fuel tank breather pipe from the
fuel tank breather stub. The fuel tank breather pipe has
a quick release fitting and connects to the breather pipe
from the fuel tank breather stub. The fuel filler vent pipe
from the tank is vented to atmosphere. The vent pipe
(G421197) Technical Training364
Lesson 2 – PowertrainFuel Tank and Lines 
						

							incorporates an insect trap at its termination near the
filler head. The fuel filler pipe locates in a short flexible
hose attached to the tank and is secured with two worm
drive clamps.
A smaller pipe, which is not associated with the fuel
system, is attached to the side of the fuel filler pipe. This
pipe connects to the rear differential and provides
breathing for the differential case. The pipe terminates
near the fuel filler head.
FUEL COOLER
Pipe - HP pump to cooler1
Pipe - cooler to fuel filter2
Coolant outlet3
Coolant inlet4
Fuel cooler5
Bracket6
The fuel cooler uses engine coolant, direct from the
lower part of the radiator, to cool fuel returning to the
tank from the HP injection pump.
The fuel cooler is located on the right hand side of the
chassis, at the rear of the engine, near to the starter
motor. A bracket, which is attached to the right hand
chassis rail, provides for the attachment of the cooler.
The bracket has two slots which accept two plastic pegs
which are attached to the cooler. A bolt is inserted
through a hole in the bracket and screws into a captive
nut on the cooler to positively secure the cooler to the
bracket.
The cooler has four quick fit connector pipes which
provide for the attachment of the fuel inlet hose from
the HP injection pump, the fuel outlet hose to the fuel
filter, the coolant inlet hose from the radiator and the
coolant outlet hose to the coolant thermostat housing.
The coolant pipes can be identified by their smaller
diameter.
Fuel Tank and LinesLesson 2 – Powertrain
365Technical Training (G421197) 
						

							On completing this lesson, you will be able to
•Describe the key design features
•Describe the special requirements for servicing
•Remove and refit the timing chains and counter balance shaft in accordance with service literature
•Understand the layout and function of the coolant circuit
•Understand which markets will use the engine
•Describe the key design features
•Describe the special requirements for servicing
•Remove and refit the timing chains in accordance with service literature
•Describe the layout and function of the coolant circuit
•Describe which markets will use the engine
•Describe the key design features
•Describe the special requirements for servicing
•Remove and refit the timing belts in accordance with service literature
•Describe the layout and function of the coolant circuit
•Describe which markets will use the engine
•Describe the layout and function of the cooling system
•Understand the special requirements for servicing
•Describe the layout and function of the cooling system
•Understand the special requirements for servicing
•Describe the layout and function of the cooling system
•Understand the special requirements for servicing
•Identify the fuel charging and control components for the 4.0 V6 petrol engine
•Explain the functionality of the fuel charging and control system
•Identify the fuel charging and control components for the 4.4 V8 petrol engine
•Explain the functionality of the fuel charging and control system
•You will be able to state which components are serviceable
•Describe the components of the low pressure fuel system
•Explain the control components of the high pressure pump and how the pump pressure is generated
•Explain the function of the piezo type injectors
•Explain any service requirements
ObjectivesLesson 2 – Powertrain
13Technical Training (G420493)