Diesel Injection Pump SERVICE MANUAL FORD Puma Common Rail System Functional Parts OPERATION February, 2006 00400090E
2006 DENSO CORPORATION All Rights Reserved. This book may not be reproduced or copied, in whole or in part, without the written permission of the publisher.
Table of Contents Table of Contents Operation Section 1. ACCESSORY INFORMATION 1.1 Outline................................................................................ 1-1 1.2 Functional Parts List..................................................................... 1-1 2. SUPPLY PUMP 2.1 Outline................................................................................ 1-2 2.2 Construction........................................................................... 1-3 2.3 Operation.............................................................................. 1-5 3. RAIL 3.1 Outline................................................................................ 1-6 4. INJECTOR 4.1 Outline................................................................................ 1-7 4.2 Construction........................................................................... 1-7 4.3 Operation............................................................................. 1-10 5. SUPPLY PUMP COMPONENT PARTS 5.1 Feed Pump........................................................................... 1-11 5.2 SCV (Suction Control Valve).............................................................. 1-11 5.3 Fuel temperature sensor................................................................. 1-13 6. RAIL COMPONENT PARTS 6.1 Rail Pressure Sensor................................................................... 1-14 6.2 Pressure Limiter....................................................................... 1-14
Operation Section 1 1 1. ACCESSORY INFORMATION 1.1 Outline This publication details the common rail system for the FORD Puma. This common rail system includes the following DENSO functional parts: supply pump, rail and injectors. Only the functional parts are described here. 1.2 Functional Parts List Parts Name DENSO Part Number Manufacturer Parts Number Remarks Supply pump HU294000-040# 6C1Q-9B395-AB For 2.2L HU294000-041# 6C1Q-9B395-BB For 2.4L Fuel temperature sensor 179730-010# SCV (Suction Control Valve) SM294200-010# Rail HU095440-073# 6C1Q-9D280-AB Rail Pressure Sensor HU294390-001# Pressure Limiter HU095420-033# Injector HU095000-580# 6C1Q-9K546-AB For low output HU095000-581# 6C1Q-9K546-BA For high output
1 2 Operation Section 2. SUPPLY PUMP 2.1 Outline The supply pump consists primarily of the pump body (camshaft (eccentric cam), ring cam, and plungers), SCV (Suction Control Valve), fuel temperature sensor, and feed pump. The two plungers are positioned vertically on the outer ring cam for compactness. to Rail Overflow to Fuel Tank to Rail SCV Fuel Temperature Sensor from Fuel Tank Overflow to Fuel Tank Fuel Temperature Sensor SCV from Fuel Tank Q001030E The engine drives the supply pump at a ratio of 1:2. The supply pump has a built-in feed pump (trochoid type), and draws the fuel from the fuel tank, sending it to the plunger chamber. The internal camshaft drives the two plungers, and they pressurize the fuel sent to the plunger chamber and send it to the rail. The quantity of fuel supplied to the rail is controlled by the SCV, using signals from the engine ECU. The SCV is a normally open type (the SCV opens during de-energization). Injector Rail Discharge Valve Intake Valve Plunger Intake Pressure Feed Pressure High Pressure Return Return Spring Fuel Overflow Return SCV Camshaft Filter Fuel Inlet Regulating Valve Feed Pump Fuel Tank Intake Fuel Filter Q001019E
Operation Section 1 3 (1) Supply Pump Internal Fuel Flow Fuel drawn from the fuel tank passes through the route in the supply pump as illustrated, and is fed into the rail. Regulating Valve Supply Pump Interior Feed Pump SCV (Suction Control Valve) Discharge Valve Rail Overflow Intake Valve Pumping Portion (Plunger) Fuel Tank Q000394E 2.2 Construction The eccentric cam is formed on the camshaft and is attached to the ring cam. Ring Cam Camshaft Eccentric Cam Q000395E As the camshaft rotates, the eccentric cam rotates eccentrically, and the ring cam moves up and down while rotating. Plunger Eccentric cam Drive shaft Ring cam QD0727E
1 4 Operation Section The plunger and the suction valve are mounted on top of the ring cam. The feed pump is connected to the rear of the camshaft. Plunger A Ring cam Feed pump Plunger B QD0728E
Operation Section 1 5 2.3 Operation As shown in the illustration below, the rotation of the eccentric cam causes the ring cam to push Plunger A upwards. Due to the spring force, Plunger B is pulled in the opposite direction to Plunger A. As a result, Plunger B draws in fuel while Plunger A pumps it to the rail. Suction valve Delivery valve Plunger A Eccentric cam Ring cam SCV Plunger B Plunger A: complete compression Plunger B: complete intake Plunger A: begin intake Plunger B: begin compression Plunger A: begin compression Plunger B: begin intake Plunger A: complete intake Plunger B: complete compression QD0707E
1 6 Operation Section 3. RAIL 3.1 Outline The rail stores pressurized fuel that has been delivered from the supply pump and distributes it to each cylinder injector. A pressure sensor and a pressure limiter are adopted in the rail. The pressure sensor detects the fuel pressure in the rail and sends a signal to the ECU. The ECU controls the supply pump SCV and the fuel pressure in the rail based on this signal. To Injector High-Pressure Fuel Inlet Rail Pressure Sensor Pressure Limiter Q001054E
Operation Section 1 7 4. INJECTOR 4.1 Outline A compact, energy-saving solenoid-control type TWV (Two-Way Valve) injector has been adopted. 4.2 Construction 16 Base 16 Characters Sample Upper Side Solenoid Valve Pressurized Fuel (from Rail) QR Codes Sample Control Chamber Leak Passage Command Piston Seat Pressurized Fuel Nozzle Spring Pressure Pin Multiple Hole Filter Filter Orifice Dimensions: φ0.045x2025 Nozzle Needle Q001020E
1 8 Operation Section (1) Injector with QR Codes QR Code Location (1) (2) QR Codes ( 9.9mm) Sample (2) (1) ID Codes (16 base 16 characters) Base 16 characters nothing fuel injection quantity correction information for market service use. Sample Upper Side Q001055E QR Code Correction Points Injection volume Q QR code Sample Pressure parameters Actuating pulse TQ Actuating pulse width TQ Q001056E
Operation Section 1 9 (2) Service Instructions When replacing the injectors or the engine ECU, it is necessary to record the ID codes in the ECU using a diagnosis tool (available from the car manufacturer). < CAUTION > If the ID codes for the installed injectors are not registered correctly, engine failure such as rough idling and noise will result. Replacing the Injector "As no correction resistance used, the fuel injection correction data cannot be detected electrically" Replaced injector Engine ECU * Injector ID code must be registered with the engine ECU Q001057E Replacing the Engine ECU "As no correction resistance used, the fuel injection correction data cannot be detected electrically" Vehicle injectors Replaced engine ECU * Injector ID code must be registered with the engine ECU Q001058E
1 10 Operation Section 4.3 Operation The TWV (Two-Way Valve) solenoid valve opens and closes the outlet orifice passage to control both the pressure in the control chamber, and the start and end of injection. Solenoid TWV Outlet Orifice Actuating Current To Fuel Tank Actuating Current Actuating Current Inlet Orifice Control Chamber Rail Command Piston Nozzle Control Chamber Pressure Control Chamber Pressure Control Chamber Pressure Injection Rate Injection Rate Injection Rate No Injection Injection End of Injection Q001059E (1) No injection When no current is supplied to the solenoid, the TWV (solenoid valve) is pushed downward by the spring, closing the outlet orifice. This equalizes the control chamber pressure forcing the command piston down, and the pressure forcing the nozzle needle up. A state of no injection results because the nozzle needle closes due to the nozzle spring force and the difference in areas to which pressure is being applied. (2) Injection When current is initially applied to the solenoid, the attraction of the solenoid pulls the TWV (solenoid valve) up, opening the outlet orifice and allowing fuel to flow out of the control chamber. After the fuel flows out, pressure in the control chamber decreases, pulling the command piston up. This causes the nozzle needle to rise and injection to start. (3) Injection Ends When current continues to be applied to the solenoid, the nozzle reaches its maximum lift where the injection rate is also at the maximum level. When current to the solenoid is turned OFF, the TWV (solenoid valve) falls and closes the orifice. Fuel then flows into the control chamber via the inlet orifice, increasing pressure and causing the nozzle needle to close immediately and injection to stop.
Operation Section 1 11 5. SUPPLY PUMP COMPONENT PARTS 5.1 Feed Pump The trochoid type feed pump integrated into the supply pump, draws fuel from the fuel tank and feeds it to the two plungers via the fuel filter and the SCV (Suction Control Valve). The feed pump is driven by the camshaft. With the rotation of the inner rotor, the feed pump draws fuel from its suction port and pumps it out through the discharge port. This is done in accordance with the space that increases and decreases with the movement of the outer and inner rotors. Outer Rotor To Pump Chamber Quantity Decrease Quantity Decrease (Fuel Discharge) Inner Rotor Intake Port From Fuel Tank Discharge Port Quantity Increase Quantity Increase (Fuel Intake) QD0708E 5.2 SCV (Suction Control Valve) A linear solenoid type valve has been adopted. The ECU controls the duty ratio (the duration in which current is applied to the SCV), in order to control the quantity of fuel that is supplied to the high-pressure plunger. The supply pump drive load decreases because intake fuel quantity is controlled to achieve the target rail pressure. When current flows to the SCV, the internal armature moves in accordance with the duty ratio. The fuel quantity is regulated by the cylinder, which moves in connection with the armature to block the fuel passage. With the SCV OFF, the return spring pushes the cylinder, completely opening the fuel passage and supplying fuel to the plungers. (Full quantity intake => full quantity discharge.) When the SCV is ON, the return spring contracts and closes the fuel passage. By turning the SCV ON/OFF, fuel is supplied in an amount corresponding to the drive duty ratio and then discharged by the plungers. Valve body Needle valve Return Spring Q001060E
1 12 Operation Section (1) When the SCV Energized Duration (Duty ON Time) is Short Short duty ON => large valve opening => maximum intake quantity Feed Pump Needle valve Large Opening Q001061E (2) When the SCV Energized Duration (Duty ON Time) is Long Long duty ON => small valve opening => minimum intake quantity Feed Pump Needle valve Small Opening Q001062E
Operation Section 1 13 (3) Relationship Between the Drive Signal and Current (Magnetomotive Force) Drive Signal and Current (Magnetomotive Force) Relational Diagram Actuating Voltage Low Suction Quantity ON OFF High Suction Quantity Current Average Current Difference QD0710E 5.3 Fuel temperature sensor The fuel temperature sensor is used in rail pressure and injection quantity control. This sensor is installed on the fuel intake side and utilizes the characteristics of a thermistor in which the electric resistance changes with the temperature in order to detect the fuel temperature. Thermistor Initial Resistance Value Characteristics Temperature ( C) Resistance Value (kω) -30 (25.4) -20 +1.29 15.04-1.20-10 (9.16) 0 (5.74) 10 (3.70) 20 30 2.45 +0.14-0.13 (1.66) 40 (1.15) 50 (0.811) 60 (0.584) 70 (0.428) 80 0.318±0.008 90 (0.240) 100 (0.1836) 110 0.1417±0.0018 120 (0.1108) Q001063E
1 14 Operation Section 6. RAIL COMPONENT PARTS 6.1 Rail Pressure Sensor This sensor detects fuel pressure in the rail and sends a signal to the engine ECU. It is a semi-conductor piezo resistance type pressure sensor that utilizes the characteristic whereby electrical resistance changes when pressure is applied to a metal diaphragm. 4.2 A-VCC = 5V A-VCC PFUEL A-GND PFUEL (V) 3.56 2.6 1.32 1.0 0 0 20 100 160 200 Rail Pressure (MPa) Q001064E 6.2 Pressure Limiter When pressure in the rail is abnormally high, the pressure limiter opens the valve to relieve the pressure. It reopens when pressure in the rail drops to approximately 200 MPa, and resumes operation when pressure drops to below the specified level. Fuel leaked by the pressure limiter returns to the fuel tank. Opening pressure: 200 ± 9MPa Housing Valve Guide Valve Rail Side Spring Valve Body Q001065E
Published : February 2006 Edited and published by: DENSO CORPORATION Service Department 1-1 Showa-cho, Kariya, Aichi Prefecture, Japan