C7.1 Industrial Engine Caterpillar

Fuel Injection

Usage:

C7.1 881

Introduction

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Illustration 1	g03889406
Typical example (1) In-line fuel filter (2) Electric transfer pump (3) Primary fuel filter (4) ECM that is fuel cooled. (5) Secondary fuel filter (6) Purge line (if equipped) (7) Fuel Injection Pump (8) Inlet pressure regulator (9) Fuel manifold (rail) (10) Pressure relief valve (11) Electronic unit injector (12) Fuel cooler (optional) (A) Fuel tank

Fuel is drawn from the fuel tank through an in-line fuel filter to an electric transfer pump. The fuel then flows to the 10 micron primary fuel filter/water separator.

The fuel may flow to a fuel cooled ECM. The fuel then flows to a 4 micron secondary fuel filter.

The fuel flows from the secondary fuel filter to a pressure regulator. A pressure regulator that is installed in the low-pressure fuel system controls the fuel pressure to the fuel injection pump. The pressure regulator regulates the fuel at an absolute pressure of 150 kPa (22 psi) when the engine is at idle speed.

From the pressure regulator, the fuel flows to the fuel injection pump. The fuel is pumped at an increased pressure of 200 MPa (29000 psi) to the fuel manifold (rail).

Fuel that has too high a pressure from the fuel manifold (rail) returns through the pressure relief valve to the return line. Fuel that is leak off from the electronic unit injectors flows to the return line. The fuel may then flow through an optional fuel cooler on the way back to the fuel tank.

High Pressure Fuel System

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Illustration 2	g02216334
Typical example (1) Fuel injection pump (2) Fuel temperature sensor (3) Suction control valve for the fuel injection pump (4) Pressure relief valve (5) Electronic unit injector (6) Fuel manifold (rail) (7) Fuel pressure sensor (8) Fuel transfer pump

The fuel injection pump (1) feeds fuel to the high-pressure fuel manifold (rail) (6) . The fuel is at a pressure of up to 200 MPa (29000 psi). A pressure sensor (7) in the high-pressure fuel manifold (rail) (6) monitors the fuel pressure in the high-pressure fuel manifold (rail) (6) . The ECM controls a suction control valve (3) in the fuel injection pump (1) in order to maintain the actual pressure in the high-pressure fuel manifold (6) at the desired level. The high-pressure fuel is continuously available at each injector. The ECM determines the correct time for activation of the correct electronic unit injector (5) which allows fuel to be injected into the cylinder. The leakoff fuel from each injector passes into a drilling which runs along the inside of the cylinder head. A pipe is connected to the rear of the cylinder head in order to return the leakoff fuel to the fuel tank.

Components of the Fuel Injection System

The fuel injection system has the following mechanical components:

In-line fuel filter
Primary filter/water separator
Electric transfer pump
Fuel transfer pump
Secondary fuel filter
Fuel injection pump
Fuel injectors
Fuel manifold
Pressure relief valve
Fuel pressure sensor
Fuel temperature sensor
Water in fuel sensor

The following list contains examples of both service and repair procedures after which you must prime the system:

A fuel filter is changed.
A low-pressure fuel line is replaced.
The fuel injection pump is replaced.
The ECM is replaced.
Draining water from the water separator.

For the correct procedure to prime the fuel system, refer to Systems Operation, Testing and Adjusting, "Fuel System - Prime".

Primary Filter/Water Separator

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Illustration 3	g02214535
Typical example

The primary filter/water separator (1) is located between the electric transfer pump and the secondary fuel filter. The primary filter/water separator (1) provides a 10 micron filtration level.

The primary filter/water separator can either be engine mounted or supplied loose. The primary filter/water separator is supplied with water in fuel sensor (2) .

Secondary Fuel Filter

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Illustration 4	g02214536
Typical example

The secondary fuel filter (1) is located after the primary fuel filter. The secondary fuel filter (1) provides a 4 micron filtration level.

Fuel Pump Assembly

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Illustration 5	g02216343
Typical example

The fuel pump assembly consists of a low-pressure transfer pump and a high-pressure fuel injection pump. The pump assembly is driven from a gear in the front timing case at engine speed. The fuel injection pump (1) has three plungers that are driven by a camshaft. The fuel injection pump (1) delivers a volume of fuel three times for each revolution. The stroke of the plungers is fixed.

The injector will use only part of the fuel that is delivered by each stroke of the pistons in the pump. The suction control valve (3) for the fuel injection pump (1) is controlled by the ECM. This valve maintains the fuel pressure in the fuel manifold (rail) at the correct level. A feature of the fuel injection pump (1) allows fuel to return to the tank continuously.

The fuel temperature sensor (2) measures the temperature of the fuel. The ECM receives the signal from the fuel temperature sensor (2) . The ECM calculates the volume of fuel.

The fuel injection pump has the following operation:

Generation of high-pressure fuel

The fuel output of the fuel injection pump is controlled by the ECM in response to changes in the demand of fuel pressure.

Shutoff

The engine shuts off by preventing the electronic unit injectors from injecting. The ECM then closes the suction control valve to prevent the pressure in the fuel manifold (rail) from increasing.

Control

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Illustration 6	g02210619
Typical example of the electrical control system for the fuel system (1) Electronic Control Module (ECM) (2) Throttle position sensor (3) Wastegate regulator (4) Fuel rail pressure sensor (5) Inlet manifold pressure sensor (6) Atmospheric pressure sensor (7) Coolant temperature sensor (8) Inlet manifold air temperature sensor (9) Secondary speed/timing sensor (10) Primary speed/timing sensor (11) Fuel injection pump (12) Suction control valve for the fuel injection pump (13) Fuel temperature sensor (14) Electronic unit injectors

The ECM determines the quantity, timing, and pressure of the fuel in order to be injected into the fuel injector.

The ECM uses input from the sensors on the engine. These sensors include the speed/timing sensors and the pressure sensors.

The ECM controls the timing and the flow of fuel by actuating the injector solenoid.

The amount of fuel is proportional to the duration of the signal to the injector solenoid.

The ECM controls the fuel pressure by increasing or decreasing the flow of fuel from the fuel injection pump.

Fuel Injectors

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Illustration 7	g02290433
Typical example (1) Electrical connections (2) Bolt (3) Clamp (4) Combustion washer (5) O-ring (6) Fuel inlet

Note: If a replacement electronic unit injector is installed, the correct injector code must be programmed into the electronic control module. Refer to Troubleshooting, "Injector Code - Calibrate" for more information. The code that is required is located at Position (X) . Record Code (X) before the electronic unit injector is installed.

The fuel injectors contain no serviceable parts apart from the O-ring seal and the combustion washer. The clamp and setscrew are serviced separately.

When the ECM sends a signal to the injector solenoid, a valve inside the injector opens. The valve allows the high-pressure fuel from the fuel manifold to enter the injector. Fuel is also diverted via the leak-off route to cool and lubricate injector. The pressure of the fuel pushes the needle valve and a spring. The difference in pressure around the needle valve becomes too great, causing the pressure to lift the needle and start injecting.

The timing and duration of injection is controlled by a solenoid valve in the injector. The valve has two positions. In the closed position, the valve closes the inlet to the injector. In this position, fuel above the injector needle is allowed to vent through the leakoff port.

In the open position, the valve opens the inlet to the injector. Simultaneously, the valve closes the leakoff port in order to allow high-pressure fuel to flow to the needle. When the solenoid valve is closed, some fuel escapes past the valve in order to vent through the leakoff port. A certain volume of fuel always flows from the leakoff port. If the volume of fuel increases beyond a critical level, the fuel injection pump will not be able to maintain pressure in the fuel manifold.

When the needle valve opens, fuel under high pressure will flow through nozzle orifices into the cylinder. The fuel is injected into the cylinder through the orifices in the nozzle as a fine spray.

When the signal to the injector ends, the valve closes. The fuel in the injector changes to a low pressure. When the pressure drops, the needle valve will close and the injection cycle stops.

The needle valve has a close fit with the inside of the nozzle, making a positive seal for the valve.

The electronic unit injectors can be instructed to inject fuel multiple times during the combustion process. A close pilot injection occurs before the main injection. The close pilot injection helps to reduce NOx and noise. The main injection period helps to increase the torque of the engine. The after injection period helps to reduce the amount of smoke that is produced.