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2001-2002 GL1800 A ABS Speed Sensor Wire Clamp Location INSPECTION/ REPAIR PROCEDURES

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Filed Under (Honda) by admin on 29-01-2011

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1. If the VIN is within the preceeding range, inspect the front ABS speed sensor wire clamp according to the following illustrations. 2001-2002 GL1800A ABS Speed Sensor Wire Clamp Location INCORRECT Installation CORRECT Installation Service Bulletin American Honda Motor Co., Inc. 2001-2002 GL1800 ABS Speed Sensor Wire Clamp Location 0112 GL1800 #9*GL1800 #9*0112*2001-2002 GL1800 ABS Speed Sensor Wire Clamp Location*GL1800, ABS Speed Sensor Wire Clamp Location*Motorcycle*1800 2 of 2 ©2001 American Honda Motor Co., Inc. – All Rights Reserved GL1800 #9 DECEMBER 2001 IDENTIFICATION There is no identification mark associated with this Service Bulletin. PARTS INFORMATION There is no parts information associated with this Service Bulletin. WARRANTY INFORMATION The normal warranty claim submission requirements apply. Submit one warranty claim per VIN with the following information only: Inspected and REPAIRED Template: GL#9 Hours: 0.2 hours Parts: None If the clamp is installed correctly on top of the speed sensor, no further action is necessary. 3. If the clamp is installed incorrectly under the speed sensor, remove and reinstall the clamp and speed sensor correctly. Torque the bolts,. Torque: 12 N • m (1.2 kgf • m, 9 lbf • ft) If the speed sensor wire clamp for the front ABS speed sensor is installed incorrectly, the ABS speed sensor air gap may be out of specification. This does not affect ABS speed sensor operation, but the clamp should be installed correctly. Inspect and repair all affected units using the Inspection/Repair procedures listed below. Inspect all unsold units and customer units brought in for service. AFFECTED UNITS 2001-2002 GL1800A units as follows: MODEL 2001 GL1800A All units 2002 GL1800A 1HFSC474*2A100001 – 1HFSC474*2A101643 * = denotes check digit Any unit in the above VIN range may be affected and should be inspected according to the procedures in this Service Bulletin. All units outside of the above VIN range do not require inspection. CUSTOMER NOTIFICATION There is no customer notification associated with this Service Bulletin.

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A Comparison of Stopping Distance Performance for Motorcycles Equipped with ABS, CBS and Conventional Hydraulic Brake Systems

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Filed Under (Tips and Review) by admin on 09-02-2012

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Surface Tests On the ABS-equipped motorcycles, the operator was tasked with braking sufficiently to assure the operation of the ABS. The measured stopping distance values were corrected to compare data from the speeds of 48 km/h and 128 km/h, except for the BMW F650 data, which was corrected to 48 km/h and 117 km/h, the latter figure limited by that model’s top speed of 157 km/h (i.e. 75% of 157 km/h). In the ABS-enabled mode, for each load/speed/brake combination, the stopping distances were very consistent from one run to another. In this mode, the braking force was applied in a controlled and consistent manner by the ABS mechanism. With the exception of having to react to the possibility of the rear wheel becoming airborne under high deceleration, the rider did not require significant experience or special skill in order to achieve a high level of performance. In the ABS-disabled mode, the stopping distances were less consistent because the rider while modulating the brake force, had to deal with many additional variables at the same time. Up to six runs were allowed for the rider to become familiar with the motorcycle’s behavior and to obtain the best stopping distance. Test results from non-ABS motorcycles were noticeably more sensitive to rider performance variability. The data in Table 2 include the best stopping distances obtained without ABS, compared to the average braking performance obtained with ABS. The average results were favored for presenting the performance with ABS because the best results could be more representative of threshold braking, whereby the ABS operated for only a portion of the entire test. Despite being compared to the best stopping distances without ABS, the average results with ABS provided an overall reduction in stopping distance of 5%. The stopping distance reduction was more significant when the motorcycle was loaded (averaging 7%). The greatest stopping distance reduction (averaging 17%) was observed when only the rear foot pedal was applied to stop the motorcycle from 128 km/h

2008 Kawasaki ZG1400 Concours ABS Front 3-Line Kit and FK003D625R Single Line Rear INSTALLATION INSTRUCTIONS

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Filed Under (Kawasaki) by admin on 29-01-2011

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Step 1: Identify the key components that complete our front brake line kit: You should have three (3) hoses, one (1) double banjo bolt, and two (2) single banjo bolts There are also a total of nine (9) washers and (3) brass conic inversors. Seven (7) washers and two (2) inversors will be used; the rest are spares. If you have purchased a rear kit as well, locate the following additional pieces: One (1) hose with bracket and c-clip attached, one (1) single banjo bolt, two (2) brass inversors and three (3) washers. You will use one (1) “olive” conic inversor and two (2) washers, the rest are spares. Step 2: To ensure no paint damage from a brake fluid spill, completely cover the front end of the bike. This process can be messy, and brake fluid WILL drip! Step 3: After drying out the OEM brake system, uninstall stock hoses. On the front brake line kit, we are replacing three hoses and their respective blocks (see pictures 1-2 for blocks) . For the rear, we are replacing one hose from the master cylinder to the ABS hard line. Take note of how the stock system was routed, in case you need to reinstall it. Step 4: Locate Line A – This will travel from the master cylinder to the ABS Junction. (See picture 3) You will use a single banjo bolt and two washers at the master cylinder, and an “olive” inversor to thread female end to hard pipe for incoming ABS (right side). * We have replaced the block at the upper triple clamp with a c-clip; please use your stock bolt to thread this in. (See picture 4) Locate Line B – This will travel from the ABS Junction to the right caliper. First, thread the female end to the hard pipe for outgoing ABS (left side). There will be a bolt from the OEM blocks at ABS Junction; please use this to thread c-clips into frame as shown in picture 5 . There is another bolt/OEM block located at the lower triple clamp; please use this to thread the c-clip in as seen in picture 6. Locate Line C – This will cross over the front fender using OEM holders, from right caliper to left caliper. Thread caliper banjos from Line B and C using the following sequence: double banjo hex, washer, 40- degree banjo from Line C, washer, 20-degree banjo from Line B, washer, caliper. Please see pictures 7 and 8 for reference. Thread single banjo bolt into left caliper, using two washers and 40-degree banjo. If applicable, locate rear Line D – this will travel from the rear master cylinder to the hard line for ABS. Thread the hard pipe into female end using a “olive” inversor, and attach bracket to swingarm as seen in picture 9 . Use the bolt from the holder for ABS hose, and sit our bracket on top of the OEM holder. Using the bolt from the OEM ABS hose holder in location shown in picture 10 , attach the c-clip on top of holder and tighten. Finally, thread 30-degree banjo in caliper using the following sequence: single banjo hex, washer, banjo, washer, caliper

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Ignition Upgrade Module for 2004-up Carbureted Harley Davidson Motorcycles Owner's Manual

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Filed Under (Harley Davidson) by admin on 25-11-2010

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1. Disconnect the negative battery cable. 2. Grasp the sides of the electrical caddy (located next the ignition coil) and pull outward to remove. 3. Remove the relay and fuse panels from the electrical caddy. a. Insert a small screwdriver into the slot under each fuse and relay panel. b. Using a screwdriver, disengage the panel from the electrical caddy. 4. Disconnect the main fuse connector from the electrical caddy a. Remove the main fuse from the connector b. Insert small screwdrivers into the slots on each side of the main fuse c. Depress the tabs of the main fuse connector to disengage it from the electrical caddy
Thunder Heart Performance Corp. 615-672-8811 www.thunder-heart.com 2 EI5075.doc 5. Depress the tab located on the electrical caddy securing the TSM/TSSM. Pull it from the electrical caddy. Disconnect the TSM/TSSM connector. 6. Slide the data link connector towards the front of the motorcycle to disengage it from the electrical caddy. 7. Disconnect the ignition control module connector. 8. Disconnect the ignition coil connector and spark plug cables from the coil. 9. Remove the electrical caddy fasteners (3 total). 10. Remove the wiring from the electrical caddy. 11. Remove the fasteners securing the factory ignition control module from the electrical caddy. 12. Installation of the Digital Ignition Module is the reverse of removal. 2.2 Touring Models 1. Disconnect the negative battery cable. 2. Remove the right saddlebag. 3. Gently pull the side cover from the frame downtubes (no tools required). 4. Depress the external latches and use a rocking motion to remove the electrical connector from the ignition control module. 5. Remove the two socket screws to detach the ignition control module from the electrical bracket. 6. To install the Digital Ignition Module, install and tighten the socket screws to 50-60 in-lbs . The remainder of installation is the reverse of removal. 2.3 Softail Models 1. Remove the seat. 2. Disconnect the negative battery cable. 3. Remove the two screws to free the ignition control module from the mounting bracket. 4. Depress the external latches and use a rocking motion to remove the electrical connector from the ignition control module. 5. To install the Digital Ignition Module, install and tighten the socket screws to 15-21 in-lbs . The remainder of installation is the reverse of removal

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Victory LED Brake Light Module Installation

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Filed Under (Victory) by admin on 31-10-2010

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Brake Module Installation: Locate the Auto Cancel Module (ACM) under the seat on the right side of the battery box area. Select a suitable location to mount this product near the ACM module. Disconnect negative terminal on battery before installation.. Do not attached attach the product at this time. Setup: Set dip switches according to the chart below. Switch Settings: 1 2 3 4 Result OFF OFF OFF OFF 3 Flashes-Solid-Repeat ON OFF OFF OFF 3 Strobes-Solid-Repeat OFF ON OFF OFF 3 Strobes -Solid ON ON OFF OFF 3 Flashes – Solid OFF OFF ON OFF Variable Flash Rate – Use Pot to adjust flash rate Route and connect the wires as follows: Refer to block diagram on page 2. Locate the White with Pink Tracer wire leading into the ACM module. Cut this wire approximately 2-3 inches from the ACM module. A: Red: Input: Connect this wire to the cut White/Pink wire leading away from the ACM module using supplied posi-tap. (See enclosed instructions for Posi-Tap) B: Yellow: Output: Connect this wire to the cut White/Pink leading into the ACM module using supplied posi-tap. C: Black: Ground: Connect this wire to a good bare metal contact or negative terminal of battery using supplied terminal ring, crimp terminal ring onto black wire, heat terminal ring to form with heat gun or hair dryer until heat shrink, shrinks. Attach the unit to your vehicle using supplied 3M tape or tie wraps. Reconnect negative terminal to battery. Operation: Apply power and check that LED(s) operate correctly in both running light and brake light mode. Caution! This product is designed for use on DC motorcycle applications with negative ground only! This product is not recommended or approved for any other application. Warning! This product is intended to drive high output LEDs ONLY. Do not connect this product’s output to any other type lamp. Maximum output current is 2 amps. Overloading, improper use or improper operation of this product will void the warranty and many damage the product. Warning! Consult your owners’ manual or the vehicle manufacture before installing this or any other electronic product

2011 HONDA CBF1000/ CBF1000 ABS Specifications

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Filed Under (Honda) by admin on 18-02-2011

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Press information for 2011 CBF1000 / CBF1000 ABS 7 Specifications – CBF1000 (ED-type) ENGINE Type Liquid-cooled 4-stroke DOHC inline-4 Displacement 998cm3 Bore  Stroke 75  56.5mm Compression Ratio 11.2 : 1 Max. Power Output 79kW/9,000r/min -1 (95/1/EC) Max. Torque 96Nm/6,500r/min -1 (95/1/EC) Idling Speed 1,200min -1 Oil Capacity 3.6 litres FUEL SYSTEM Carburation PGM-FI Throttle Bore 36mm Aircleaner Dry, cartridge-type paper filter Fuel Tank Capacity 20 litres Fuel Consumption 18,4 km/l (WMTC Mode #) ELECTRICAL SYSTEM Ignition System Computer-controlled digital transistorised with electronic advance
Press information for 2011 CBF1000 / CBF1000 ABS 8 Ignition Timing 5° BTDC (idle) ~ 45° BTDC (7,500min -1 ) Sparkplug Type IMR8C-9HES Starter Electric Battery Capacity 12V/8.6AH ACG Output 350W/5,000 rpm Headlights 12V, 55W  1 (low) / 55W  1 (high) DRIVETRAIN Clutch Wet, multiplate with coil springs Clutch Operation Hydraulic Transmission Type 6-speed Primary Reduction 1.6 Gear Ratios 1 2.6 2 1.83 3 1.5 4 1.32 5 1.17 6 1.07 Final Reduction 2.687 (43/16) Final Drive #530 O-ring sealed chain FRAME Type Mono-backbone; cast aluminium
Press information for 2011 CBF1000 / CBF1000 ABS 9 CHASSIS Dimensions (LWH) 2,210  780  1,220mm Wheelbase 1,495mm Caster Angle 26° Trail 110mm Turning Radius 2.9m Seat Height 795mm ±15mm Ground Clearance 135mm Kerb Weight *245kg (F: 120kg; R: 125kg) Max. Carrying Capacity 195kg Loaded Weight *440kg SUSPENSION Type Front 41mm free valve-type telescopic fork & adjustable spring; 120mm stroke Rear Gas-charged HMAS damper & adjustable spring and rebound; 120mm axle stroke WHEELS Type Front Hollow-section 6-spoke cast aluminium Rear Hollow-section 6-spoke cast aluminium Rim Size Front 17M/C  MT3.5 Rear 17M/C  MT5
Press information for 2011 CBF1000 / CBF1000 ABS 10 Tyre Size Front 120/70 ZR17M/C (58W) Rear 160/60 ZR17M/C (69W) Tyre Pressure Front 250kPa Rear 290kPa (290kPa with passenger) BRAKES Type Front 296  4.5mm dual hydraulic disc with 2- piston calipers, floating rotors, sintered metal pads (*3-piston calipers and Combined ABS) Rear 240  5.0mm hydraulic disc with 1-piston caliper, sintered metal pads (*and Combined ABS) *C-ABS version All specifications are provisional and subject to change without notice

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Harley-Davidson Softail, Touring, Dyna, Sportster and V-Rod, SELF LEARNING MODULE INSTALLATION MANUAL

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Filed Under (Harley Davidson) by admin on 17-04-2012

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STEP 1 – BATTERY CONNECTION Locate the battery and disconnect the negative battery cable. Mount the module in the open area in front of the battery with 2-tie straps or velcro straps, directing the harness from the module towards the 6 o’clock position. STEP 2 – THROTTLE POSITION SENSOR (TPS): Remove the air cleaner assembly and unplug the TPS sensor connector at the TPS sensor. The harness includes (2) TPS connectors which should be routed under the gas tank into the factory wire loom to the TPS sensor. The TPS sensor is located on the left side of the throttle body. Plug the (2) TPS connectors from the module in between the TPS sensor and to the factory TPS connector. STEP 3 – O2 SENSOR: Systems equipped with factory O2 sensors Rear: Unplug the Rear O2 sensor connector from the factory harness, which is located at the Rear exhaust pipe. Route the module’s harness which includes (2) O2 sensor connectors and connect one connector to the Rear O2 sensor and connect the other connector to the main factory O2 sensor connector. Front: Unplug the Front O2 sensor connector from the factory harness, which is located at the Front exhaust pipe. Route the module’s harness which includes (2) O2 sensor connectors, and connect one connector to the Front O2 sensor and connect the other connector to the main factory O2 sensor connector. Systems not equipped with factory O2 sensors NOTE: Many aftermarket exhaust systems are now equipped with plugged O2 sensor bungs which can be removed to accept an aftermarket O2 sensor. Typically these bungs already have a thread size of 18 mm x 1.5 mm. Exhaust systems not equipped with O2 sensor bungs need to have the supplied 18 mm x 1.5 mm thread size bung welded to the exhaust pipe in order to install an O2 sensor. The O2 sensor bung should be installed 3 to 6 inches away from the rear cylinder exhaust port and in front of the exhaust torque tube pipe area. The module prefers to receive information from the O2 sensor from an area that is NOT contaminated from atmospheric air. This air may enter through the tail pipe of an unrestricted or un-baffled exhaust pipe. The bung should not be installed in the “5 to 7 o’clock” area. If mounted in this area the O2 sensor can be damaged. The moisture from the gases exiting from the rear cylinder exhaust port will harm the ceramic shell element of the O2 sensor.

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DIAGNOSTIC TESTER CONTROLLER AREA NETWORK (CAN) INTERFACE MODULE

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Filed Under (Toyota Manuals) by admin on 30-10-2011

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Remove the original DLC3 Cable and store it in the Diagnostic Tester storage case. 2. Connect the CAN Interface Module to the DLC Cable. 3. Use the Diagnostic Tester with the CAN Module installed for all DLC3/J1962 based vehicle communication. 4. If you experience problems with the Diagnostic Tester or CAN Interface Module, please contact Toyota Special Service Tool Customer Support at 1-800-933-8335. NOTE: There is no need to remove the CAN Interface Module when working with non-CAN systems or older software versions (Version 10.1a or earlier). The Diagnostic Tester will communicate with all DLC3/J1962 based systems with the CAN Interface Module installed. For DLC1 and DLC2 communication you must continue to use the Vehicle Interface Module (VIM)

HARLEY DAVIDSON IGNITION MODULE INSTALLATION MANUAL

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Filed Under (Harley Davidson) by admin on 23-03-2012

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Step 1: Apply a thin coat of silicone grease to the bottom of the module before mounting the module to its plate in the distributor. Step 2: Slide the three wires from the MODULE, through the grommet, to outside the distributor housing. Put the three wires from the MODULE in the TERMINAL PIN HOUSING: GREEN WIRE in hole #1, BROWN WIRE in hole #2, RED WIRE in hole #3. Plug the three wire harness (PN 29349, not supplied with this kit) into the TERMINAL PIN HOUSING. RED WIRE: Power/voltage for the MODULE. Connect to coil (+) terminal. GREEN WIRE: Ignition trigger. Connect to coil (-) terminal. BROWN WIRE: Ground for the MODULE. Connect to ENGINE BLOCK GROUND. Clean away any grease, oil, and paint from the mounting surface before the connection is made.

Integral ABS and ASC – new Riding Dynamic Control Systems for BMW Motorcycles

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Filed Under (BMW) by admin on 16-11-2010

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Entering its next generation, BMW Motorrad Integral ABS is taking a quantum leap in the process of evolution, advancing from a stand-alone solution acting only on the brakes into a fully networked all-round system. Offering the new generation of Integral ABS, BMW Motorrad provides the foundation for additional dynamic riding control systems with a reduction in technical requirements and features. And following the customer’s wishes, this new generation also opens up the option in future for further-reaching rider assistance functions. The first step in this direction is BMW Motorrad ASC Automatic Stability Control available as of 2007. This system serving to control drive spin on a production motorcycles is being introduced as an optional extra on the touring models in the BMW K and Boxer Series. Once again, therefore, BMW is acting as the pioneer in the introduction of advanced safety technologies on the motorcycle. This further enhances the leadership which BMW Motorrad has shown in the area of active safety for more than 15 years. Choosing the right development partner for both systems, BMW Motorrad obviously had to focus on that partner’s specific competence in control technology and the networking of functions within the vehicle. In recent years, major car suppliers have become aware of the technical challenges presented by the motorcycle with its specific riding dynamics and the growing potential for motorcycle control systems in the market. The decisive point in preselection of the development partner was the willingness and ability to develop specialised solutions suitable for use on BMW motorcycles. So taking this into account, joint development of the new generation of ABS brake technology started together with Continental-Teves in early 2003. Integral ABS. BMW Motorrad’s new Integral ABS technology has been developed separately from the previous system and the entire layout of the system has been newly conceived from the ground up. Capitalising on progress in technology in both hydraulics and electronics, the development engineers have succeeded in simplifying the architecture of the system while at the same time enhancing its functions to an even higher standard. The result is supreme stopping power and very short stopping distances even without electrical power assistance on the brakes.

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