Fuel
injection pumps play an important role in delivering fuel to the injectors at
the required pressure and timing. The injection sequence should be faster,
which requires the pump to be compact and light in weight. Distributor type
fuel injection pump fits the criteria of light weight and compact design. It
also goes by the name axial-piston distributor pump.
In the year
1962, Bosch introduced its first distributor type fuel injection pump and since
then it has been widely used in almost all types of vehicles. It houses a
compact governor and all together the pump’s size is pretty much smaller than
the inline fuel injection pumps. The pump and governor has been continuously
improved over a period of time to meet the low fuel consumption and low emission
demands.
For an
in-direct fuel injection, a distributor pump generates 350 bar of pressure.
Whereas, for a direct fuel injection system, it generates pressure in a range
of 900 bar to 1900 bar. The pressure generation depends on the speed of the
engine. They can be used in engines having 3 to 6 cylinders.
There are
two types of distributor pumps:
·
VE type pump: These are also known as axial piston
distributor type pumps. The piston compresses the fuel by moving in an axial
direction relative to the drive shaft.
·
VR type pump: It is also known as radial piston
type distributor pump. These have multiple pistons arranged in a radial
direction relative to the drive shaft motion. The pressure achieved in VR pumps
is higher than that of VE pumps.
This article
will concentrate on VE pumps alone. It relies on a single piston to distribute
fuel to all the cylinders of an engine.
The fuel
injection system consists of a fuel tank.
Fuel from the tank is supplied to the VE
type distributor fuel injection pump via a fuel filter. The fuel is supplied with the help of a pre-supply pump if the tank is located
at a lower position compared to the fuel injection pump. Fuel is pressurized in
the fuel injection pump and then delivered to the nozzles. In addition, there is a solenoid shut off valve to block the flow of fuel to the high
pressure fuel injection pump when the ignition is switched OFF. The fuel flow
is varied with the help of a mechanical governor.
A hydraulic timing device is used to vary the fuel injection timing.
FUEL SUPPLY STAGE:
In the fuel
supply stage, fuel is supplied from the tank to the fuel injection pump at the
required pressure. This stage comprises of the following components:
- Fuel
tank
- Pre-supply
pump in fuel tank (optional)
- Fuel
filter
- Fuel
lines (Low pressure)
- Vane
pump (Low pressure pump which is integrated in the high pressure pump)
- Pressure
Control Valve (PCV)
Fuel Tank:
It should be
corrosion resistant and should prevent leaking of fuel even if the pressure
goes beyond the operating pressure of at least 0.3 bar.
Fuel Lines:
The fuel
lines are made of flame resistant metal tubing. It should be strong enough to
prevent damage and should avoid leakage that can occur at twists and turns.
Fuel Filter:
It reduces
the level of contamination by removing solid particles. To ensure that the
solid particles not clog the filter, a separate storage is provided for the
removed particles.
Vane type pump (Low pressure pump):
It sucks the
fuel from the tank and supplies it to the high pressure distributor pump. For
each rotation, it supplies a constant amount of fuel to the high pressure pump.
As the speed increases, the amount of fuel supplied also increases.
Vane pump’s
impeller is mounted on the inside of the drive shaft through a key and keyway
arrangement. The drive shaft runs the impeller. Impeller is surrounded by an
eccentric ring which is mounted in the pump housing. An impeller has 4 floating
blades which float outwards against the eccentric ring.
As the drive
shaft rotates the impeller, the floating blades are pressed outside against the
eccentric ring as a result of centrifugal force. Fuel from the tank flows
through the inlet passage provided in the housing and is collected in the
chamber formed by the impeller, any 2 floating blades and eccentric ring. As
the shaft keeps rotating, the fuel in the chamber is transferred to a
constricted space. As a result of this, fuel is pressurized to a margin of 4
bar at idling speed and 10 bar at maximum speed of engine. The low pressure
fuel then escapes out through the spill port.
Due to the
shape of eccentric ring, the volume of the chamber in which the fuel is
collected is reduced when it rotates to the fuel discharge side. This
arrangement pressurizes the fuel.
Both the
fuel inlet side and fuel discharge side has kidney shaped cells. The inlet side
has the fuel inlet bore connected to the fuel inlet passage and the discharge
side has the spill port which supplies fuel to the high pressure pump.
Pressure Control Valve (PCV):
As the speed
of the drive shaft increases, the pressure generated by the vane pump also
increases. This pressure governs the functioning of the hydraulic timing
device. Therefore it is important that the pressure generated should not exceed
the optimum pressure.
A pressure
control valve is used to control the internal pressure. It consists of a spring
loaded valve. When the internal pressure is beyond a set value, then the valve
plunger is pushed against the force of the compression spring. As a result, the
return line is exposed and the fuel escapes through the return line. This
reduces the internal pressure. The return line is placed adjacent to the fuel
discharge side of the vane pump.
The fuel
that escaped through the return line is directed back to the fuel inlet side of
the vane pump through an internal passage. The opening pressure of the spring
loaded valve can be adjusted by varying the spring tension.
DISTRIBUTOR PUMP DESIGN:
The
distributor pump has a compact body in which various parts are integrated
together. A typical distributor pump is made of the following components:
- Vane
pump (Low pressure pump)
- High
pressure distributor pump
- Mechanical
governor
- Hydraulic
timing device
- Solenoid
shut off valve
HIGH PRESSURE DISTRIBUTOR PUMP:
The high
pressure pump has one plunger or piston that pressurizes the fuel and then
distributes it to individual cylinders through high pressure fuel lines and
nozzles. The fuel is delivered at the specified timing and quantity. The
distributor pump consists of the following components:
·
Distributor Plunger/Piston:
The rotational motion from the drive shaft is transferred to the plunger
via a roller ring assembly, cam plate and yoke assembly. So the entire unit
rotates at the same speed. The cam plate provides the reciprocating motion to
the plunger. A plunger has vertical grooves equal to the number of cylinders in
an engine. The vertical grooves act as fuel inlet passage to the barrel during
inlet stroke of the piston. The stroke movement of plunger is 2.2 to 3.5 mm
depending on the type of pump.
The plunger moves to Top Dead Centre (TDC) and compresses the fuel. Two
symmetrically arranged plunger return springs push the plunger back to Bottom
Dead Centre (BDC) after fuel compression has taken place. The plunger has a
fuel delivery line running through its length and this line is connected to the
distributor port and spill ports.
Cam plate has cam profiles which help in plunger reciprocation. The
number of cam profiles is equal to the number of cylinders in an engine. The design
of cam profiles affects the injection pressure and the injection duration.
The plunger and barrel are precisely fitted into the distributor body.
The plunger also has a control collar which covers and uncovers the spill port
to vary fuel quantity. The barrel has distributor slots in its inner
circumference which supply fuel to the respective injectors via delivery valve.
The distributor body also has a electric shut off valve to block the supply of
fuel to the barrel when engine is switched OFF.
FUEL METERING INSIDE THE DISTRIBUTOR
BODY:
The
distributor body generates the pressure required for fuel injection. There are
several phases of plunger stroke for precise fuel metering to take place.
When the piston moves from top dead centre (TDC) to bottom dead centre
(BDC), one of the vertical grooves match with the fuel inlet passage and thus
the fuel enters the plunger barrel.
As the plunger keeps rotating, it closes the inlet passage. Now the
piston starts moving from BDC to TDC and some amount of fuel flows back to the
inner chamber of the pump through a slot provided at the top of plunger (also
known as pre-stroke groove). Pre-stroke is necessary to prevent slow rise in
injection pressure.
As the plunger moves further up towards TDC, the pre-stroke groove is
closed and the injection pressure increases rapidly due to compression. The
fuel is delivered to the delivery slot and then supplied to the delivery valve.
The delivery valve lifts from its seat and allows the fuel to escape to the
injector.
The effective stroke is complete when the spill port at the bottom of the
plunger is exposed. This allows the fuel to escape to the pump’s internal
chamber and thus the pressure inside the barrel is releases and there is no
more fuel delivery to the injector.
VARIABLE SPEED GOVERNORS:
Variable
speed governors are used to control the engine speeds from start to
intermediate speed range and also controls it at high speeds. Speed variation
is achieved by varying the fuel quantity.
Design:
The design
is pretty much different compared to the one in Inline Fuel injection pumps. It
consists of a flyweight housing with 4 flyweights. The flyweight housing has a
gear at the bottom which is meshed with the drive shaft. It is mounted in its
position with the help of a governor shaft. As the flyweights rotate, the
movement is transferred to the sliding sleeve which slides up against the
starting lever of the governor.
The governor
mechanism consists of a starting lever, control lever and tensioning lever. At
the end of the starting lever is a ball pin which engages with the control
collar of the distributor plunger. A starting spring is attached to the top of
the starting lever. There is an idle speed spring attached to the retaining
stud at the top of the tensioning lever. A governor spring is attached to the
retaining stud on one end, whereas the other end is connected to the rotational
speed control lever via a linkage. The rotational speed control lever is linked
to the accelerator pedal.
The governor
spring tension and the flyweight force transfer the movement to the ball pin.
The movement of the ball pin moves the control collar to vary the quantity of
fuel delivered to the injectors.
The fuel
quantity varies at different speeds. This is done with the help of a variable
speed governor.
·
Starting speed:
When the engine is not running, the distributor pump doesn’t supply the
fuel to the injectors and the flyweights and sliding sleeve of the governor
rests at base position. At this point, the starting spring pushes the starting
lever into its position and the movement is transferred to control collar which
is brought to starting position. The effective stroke of plunger during
position is higher. This allows maximum fuel to be delivered to the engine for
starting. For starting the engine, the rotational speed control lever is
pressed against the maximum speed screw.
·
Idle speed:
The starting lever force is overcome by a slight increase in engine
speed. As the speed starts increasing, the flyweights’ radial movement results
in the axial movement of the sliding sleeve which presses the starting lever
against the force of starting spring. This results in the movement of control
collar bringing it to idle speed position. The effective stroke is minimum for
idling speed and this results in lesser fuel delivery to the injectors. The
accelerator pedal is released and the rotational speed control lever rests
against the idling speed screw.
The idle speed spring mounted in the retaining stud maintains a state of
equilibrium with the flyweights’ force and maintains the starting lever in its
position. This allows a steady amount of fuel to be delivered to the injector.
·
Operation under load:
When the accelerator pedal is pressed, the rotational speed control lever
assumes a position between idle speed screw and maximum speed screw. When the
speed of the engine goes beyond the idling speed, the starting spring and the
idling speed spring are fully compressed and have no control over the movement fuel
flow in this range.
The governor spring has the control over this speed range. When the
accelerator pedal is pressed, the rotational speed control lever moves from its
idle speed position to a position corresponding to the speed. This compresses
the governor spring and the governor spring force exceeds the flyweights’
centrifugal force. As a result, the starting lever rotates and transfers the
movement to the control collar. The effective stroke is increased and more fuel
is delivered to the engine, thereby increasing the speed.
When the accelerator pedal is fully pressed (Wide open throttle), more
amount of fuel is delivered as a result of governor spring’s control over the
starting lever. As the speed increases, the flyweights’ centrifugal force
increases and the sliding sleeve moves to oppose the spring force. The control
collar remains in its wide open throttle position until the opposing forces
between flyweights and governor spring achieve equilibrium.
If the speed of the engine further increases, the flyweights’ centrifugal
force overcomes the governor spring force and reduces the effective stroke of
plunger, thereby leading to speed reduction. Further increase of speed will
lead to fuel being cut off
·
Engine Overrunning:
One of the features of a variable speed governor is to prevent
overrunning of engines while descending a slope or a hill. The engine is driven
by vehicle’s inertia. At this point the sliding sleeve presses against the
starting lever and tensioning lever. The starting lever rotates in its axis to
transfer the movement to control collar, wherein the collar brings the
effective stroke to minimum or zero (in case engine is switched OFF).