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For P/No: 04998 & 04999 only. 1. In the engine bay, disconnect the negative and positive battery terminals. 2. Remove the vehicle battery (1) by first removing any fasteners. 3. Locate the vehicle grommet behind the battery cavity area. 4. Pierce a hole in the vehicle grommet. Note: Do not connect the harness to the battery at this point. Issue Date 27-09-10 For P/No: 04997 only. 5. In the engine bay, locate the vehicle battery (1). 6. Route the body harness (2) down through to the chassis. Note: Do not connect the harness to the battery at this point. 7. Route the power input harness (1) from the engine bay down through to the chassis, following the path of the brake and fuel lines. For P/No: 04997 & 04999 only. 8. Following the diagram on the right, house the two power & ground input harness female terminals (4) into the mating connector (3). 9. Connect the power input harness connector (3) to the body harness mating connector. Issue Date 27-09-10 For P/No: 04998 only. 10. Following the diagram on the right, house the three power & ground input harness female terminals (4) into the mating connector (5). 11. Connect the power input harness connector (5) to the body harness mating connector. 12. Route the body harness (1) along the LHS chassis rail, following the path of the blue vehicle harness towards the rear of the vehicle. 13. Route the body harness (1) along the rear of the vehicle towbar towards the towbar mounting bracket. Issue Date 27-09-10
Australian Competition and Consumer Commission 23 Marcus Clarke Street, Canberra, Australian Capital Territory, 2601 © Commonwealth of Australia 2013 This work is copyright. In addition to any use permitted under the Copyright Act 1968, all material contained within this work is provided under a Creative Commons Attribution 3.0 Australia licence, with the exception of: • the Commonwealth Coat of Arms • the ACCC and AER logos • any illustration, diagram, photograph or graphic over which the Australian Competition and Consumer Commission does not hold copyright, but which may be part of or contained within this publication. The details of the relevant license conditions are available on the Creative Commons website, as is the full legal code for the CC BY 3.0 AU licence. Requests and inquiries concerning reproduction and rights should be addressed to the Director, Internal Communication and Publishing Services, ACCC, GPO Box 3131, Canberra ACT 2601, or firstname.lastname@example.org. Important notice The information in this publication is for general guidance only. It does not constitute legal or other professional advice, and should not be relied on as a statement of the law in any jurisdiction. Because it is intended only as a general guide, it may contain generalisations.
Throughout this article I will address many basics of your vehicle’s steering, suspension, driveline, tires, and wheels. I did not intend this to be a “how to” manual with step by step instructions. It will simply illustrate the concepts. I’ll start with the lift and explain what it did to your steering, suspension, and driveline one aspect at a time. NOTES ABOUT THE ILLUSTRATIONS: 1) most are “spring under” leaf spring suspension, 2) non-pertinent parts are omitted for clarity, 3) many examples are exaggerated for illustration, and 4) most concepts illustrated also apply to spring over and coil/link suspensions. To cover the differences, I added a separate coil and link suspensions topic. Ready? OK, let’s get started. You lifted your Jeep and now it wanders all over the road and it vibrates too. What happened? Well, you just changed a lot of the vehicle’s geometry (probably without knowing it). Here’s a diagram of a stock Jeep and the proper angles. Your caster angle should be between 4 and 8 degrees positive. This caster angle creates an effect called mechanical trail. It’s the force that makes your wheels return to center. The caster angle shown below is close to stock. The point that the steering axis (black line) intersects the ground to the point to where the rotational axis touches the ground forms the points to measure your caster angle. You can best measure the caster angle from the top of the upper ball joint.
1 TON FOLDING ENGINE STAND Model 47304 ASSEMBLY AND OPERATING INSTRUCTIONS ® 3491 Mission Oaks Blvd., Camarillo, CA 93011 Visit our Web site at http://www.harborfreight.com Copyright © 2002 by Harbor Freight Tools®. All rights reserved. No portion of this manual or any artwork contained herein may be reproduced in any shape or form without the express written consent of Harbor Freight Tools . For technical questions and replacement parts, please call 1-800-444-3353 Specifications Engine Stand Capacity Assembled Dimensions Folded Dimensions Engine Turn Capacity Main Post Height 1 Ton (2000 Lbs.) 42” L x 36” W x 34” H 17” L x 22-1/2” W x 40” H 360 Degrees 32-1/2” Save This Manual You will need the manual for the safety warnings and precautions, assembly instructions, operating and maintenance procedures, parts list and diagram. Keep your invoice with this manual. Write the invoice number on the inside of the front cover. Keep the manual and invoice in a safe and dry place for future reference. Safety Warnings and Precautions WARNING: When using product, basic safety precautions should always be followed to reduce the risk of personal injury and damage to equipment. Read all instructions before using this product! 1. Avoid working alone. If an accident happens, an assistant can bring help. 2. Keep work area clean. Cluttered areas invite injuries. 3. Observe work area conditions. Don’t expose to rain. Keep work area well lighted. 4. Keep children away. Children must never be allowed in the work area. Do not let them near the Stand. 5. Store idle equipment. When not in use, the Stand must be stored in a dry location to inhibit rust. Always lock up tools and keep out of reach of children. 6. Dress properly. Do not wear loose clothing or jewelry as they can be caught in moving parts. Protective, electrically nonconductive clothes and nonskid footwear are recommended when working. Wear restrictive hair covering to contain long hair. 7. Use eye and ear protection. Always wear ANSI approved impact safety goggles. 8. Do not overreach. Keep proper footing and balance at all times. Do not reach over or across electrical cables or frames. 9. Maintain Stand with care. Inspect Stand, and if damaged, have it repaired by an authorized technician. SKU 47304
www.tuneyourengine.com. 1994 - 1997 Mitsubishi 3000GT VR4 ECU Diagram. Connector A. Connector B Connector C. Connector D. Pin #. Name. Signal Type. Connector B Name Injector 1 Injector 3 Injector 5 Injector 2 Injector 4 Injector 6 Power Ground Air Intake Temperature Sensor O2 Sensor # 1 (Right Bank) O2 Sensor # 2 (Left Bank) Engine Coolant Temperature Sensor Throttle Position Sensor Atmospheric Pressure Sensor Vehicle Speed Sensor Volume Air Flow Sensor Power Ground Sensor Ground Connector C Connector D Signal Type Speed Speed Speed Speed Speed Speed Ground Analog Analog Analog Analog Analog Analog Speed Analog Ground GroundConnector B Name Injector 1 Injector 3 Injector 5 Injector 2 Injector 4 Injector 6 Power Ground Air Intake Temperature Sensor O2 Sensor # 1 (Right Bank) O2 Sensor # 2 (Left Bank) Engine Coolant Temperature Sensor Throttle Position Sensor Atmospheric Pressure Sensor Vehicle Speed Sensor Volume Air Flow Sensor Power Ground Sensor Ground Connector C Connector D Signal Type Speed Speed Speed Speed Speed Speed Ground Analog Analog Analog Analog Analog Analog Speed Analog Ground GroundConnector B Name Injector 1 Injector 3 Injector 5 Injector 2 Injector 4 Injector 6 Power Ground Air Intake Temperature Sensor O2 Sensor # 1 (Right Bank) O2 Sensor # 2 (Left Bank) Engine Coolant Temperature Sensor Throttle Position Sensor Atmospheric Pressure Sensor Vehicle Speed Sensor Volume Air Flow Sensor Power Ground Sensor Ground Connector C Connector D Signal Type Speed Speed Speed Speed Speed Speed Ground Analog Analog Analog Analog Analog Analog Speed Analog Ground Ground
Doc. Name: SBMPTN2013BIO999 Doc. Version : 2013-10 | 01. Contoh keberadaan satwa pada suatu habitat yang dijaga dengan baik sebagai upaya pelestarian ex situ adalah… (A) Orang utan di hutan Kalimantan. (B) Cendrawasih di hutan Papua. (C) Rusa di Kebun Raya Bogor. (D) Pesut diSungai Mahakam. (E) Anoa di Pulau Sulawesi 02. Komunitas mikroba yang melekat pada suatu substrat/benda sehingga dapat merusak substrat/benda tersebut disebut… (A) Biodegradator. (B) Bioaktivator. (C) Biokatalis. (D) Biodeposit. (E) Biofilm. 03. Bagian sistem pencernaan yang berperan dalam memecah polipeptida menjadi oligopeptida adalah… (A) Duodenum. (B) Usus besar. (C) Lambung. (D) Jejunum. (E) Ileum. 04. Asam absisat melindungi tanaman yang mengalami kekurangan air melalui mekanisme… (A) Peningkatan pembentukan kutikula. (B) Penurunan tekanan turgor sel penjaga. (C) Peningkatan kecepatan pembelahan sel. (D) Penurunan kecepatan pembentangan sel. (E) Penghambatan pemanjangan sel epidermis. halaman 1 05. Pernyataan yang salah mengenai fotofosforilisasi siklik dan non siklik adalah… (A) Pada fotofosforilisasi non siklik sumber elektron yang memasuki Fotosistem II adalah molekul air, pada fotofosforilisasi siklik, sumber dari elektron adalah Fotosistem I. (B) Pada fotofosforilisasi non siklik penerima elktron terakhir adalah NADP, pada fotofosforilisasi siklik, penerima elektron terakhir adalah Fotosistem I. (C) Hasil dari fotofosforilisasi non siklik adalah ATP, NADPH, dan O2, sedangkan hasil dari fotofosforilisasi siklikhanya ATP. (D) Fotofosforilisasi non siklik melibatkan Fotosistem I dan II, fotofosforilisasi siklik hanya melibatkan Fotosistem II. 06. Perhatikan diagram saluran kreb berikut! Tahap dimana berlangsung hidrasi adalah (A) 1 dan 4 (B) 1 dan 5 (C) 2 dan 6 (D) 3 dan 7 (E) 3 dan 8 Kunci dan pembahasan soal ini bisa dilihat di www.zenius.net dengan memasukkan kode 3117 ke menu search. Copyright © 2013 Zenius Education SBMPTN 2013 Biologi, Kode Soal doc. name: SBMPTN2013BIO999 halaman 2 doc. version : 2013-10 | 07. Perhatikan gambar tahapan mitosis berikut! 10. Grafik berikut menunjukan kinerja insulin sintetis. Tahap telofase, metaphase, anaphase dan profasen ditunjukan oleh urutan angka…
TABLE OF CONTENTS GMC Truck Owner's and Driver's Manual . . . . . . . . . . . . . . . . . . . . . . . . . . Maintenance Schedule, Emission Control Systems Required Maintenance and Warranty Information Pamphlets & Folders . . . . . . . GMC Truck Service Manuals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GMC Truck Maintenance Manuals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Light Duty Truck Repair Manuals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Truck Unit Repair (Overhaul) Manuals & Specific Component Manuals . GMC Motorhome and TransMode Publications . . . . . . . . . . . . . . . . . . . . . Miscellaneous Service Publications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Service Bulletins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GMC Truck Wiring Diagram Booklets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Publications From Component Manufacturers . . . . . . . . . . . . . . . . . . . . . GMC Binders and Divider Tabs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Training and Educational Aids . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . NOTE :...
Data Sheet AAT001-10E TMR Angle Sensor Key Features • Tunneling Magnetoresistance (TMR) Technology • Very High Output Signal Without Amplification • Wide Airgap Tolerance • Very High Resistance for Extremely Low Power • Sine and Cosine Outputs for Direction Detection • Ultraminiature TDFN6 Package Typical Applications • Rotary Encoders • Batttery-Powered Rotary Position Sensors • Motor Shaft Position Sensors Description The AAT001-10E angle sensor is a low power, high output magnetic sensor element able to provide rotational position measurements when a rotating magnetic field is applied to the sensor. Sine and cosine signals are available for a quadrature output. The sensor element has a resistance of approximately 1.25 MΩ and can be operated at typical battery voltages to conserve power. Outputs are proportional to the supply voltage and peak-to-peak output voltages are much larger than other sensor technologies. The part is packaged in NVE’s 2.5 mm x 2.5 mm x 0.8 mm TDFN6 surface-mount package. Operation Each of the four sensor elements contains two magnetic layers: a “pinned,” or fixed direction layer; and a movable-direction, or “free” layer. The diagram below illustrates the configuration, using arrows to represent the magnetic orientation of the layers:...
GP2D12 Optoelectronic Device FEATURES • Analog output • Effective Range: 10 to 80 cm • LED pulse cycle duration: 32 ms 1 2 3 • Typical response time: 39 ms • Typical start up delay: 44 ms • Average current consumption: 33 mA PIN SIGNAL NAME • Detection area diameter @ 80 cm: 6 cm 1 VO DESCRIPTION 2 GND The GP2D12 is a distance measuring sensor with integrated signal processing and analog voltage output. 3 VCC GP2D12-8 Figure 1. Pinout VCC GND PSD SIGNAL PROCESSING CIRCUIT VOLTAGE REGULATOR OSCILLATOR CIRCUIT LED DRIVE CIRCUIT OUTPUT CIRCUIT LED VO DISTANCE MEASURING IC GP2D12-4 Figure 2. Block Diagram 1 Data Sheet GP2D12 ELECTRICAL SPECIFICATIONS Absolute Maximum Ratings Ta = 25°C, VCC = 5 VDC PARAMETER SYMBOL RATING UNIT Supply Voltage VCC -0.3 to +7.0 V Output Terminal Voltage VO -0.3 to (VCC + 0.3) V Operating Temperature Topr -10 to +60 °C Storage Temperature Tstg -40 to +70 °C Operating Supply Voltage PARAMETER SYMBOL RATING UNIT Operating Supply Voltage VCC 4.5 to 5.5 V Electro-optical Characteristics Ta = 25°C, VCC = 5 VDC PARAMETER SYMBOL Measuring Distance Range ΔL Output Voltage VO CONDITIONS MIN. TYP. MAX. UNIT NOTES 10 80 cm 1, 2 0.25 L = 80 cm 0.4 0.55 V 1, 2 Output Voltage Difference ΔVO Output change at L change 1.75 (80 cm - 10 cm) 2.0 2.25 V 1, 2 Average Supply Current ICC L = 80 cm 33 50 mA 1, 2 - NOTES: 1. Measurements made with Kodak R-27 Gray Card, using the white side, (90% reflectivity). 2. L = Distance to reflective object. VCC (POWER SUPPLY) 38.3 ms ±9.6 ms DISTANCE MEASURMENT OPERATING 1st MEASUREMENT 2nd MEASUREMENT nth MEASUREMENT VO (OUTPUT) UNSTABLE OUTPUT 1st OUTPUT 2nd OUTPUT nth OUTPUT 5.0 ms MAX. GP2D12-5 Figure 3. Timing Diagram 2 Data Sheet GP2D12 RELIABILITY The reliability of requirements of this device are listed in Table 1. Table 1. Reliability TEST ITEMS TEST CONDITIONS FAILURE JUDGEMENT CRITERIA SAMPLES (n), DEFECTIVE (C) Temperature Cycling One cycle -40°C (30 min.) to +70°C in 30 minutes, repeated 25 times n = 11, C = 0 High Temperature and High Humidity Storage +40°C, 90% RH, 500h n = 11, C = 0 High Temperature Storage +70°C, 500h n = 11, C = 0 Low Temperature Storage -40°C, 500h Operational Life (High Temperature) +60°C, VCC = 5 V, 500h Mechanical Shock 100 m / s2, 6.0 ms 3 times / ±X, ±Y, ±Z direction n = 6, C = 0 Variable Frequency Vibration 10-to-55-to-10 Hz i n 1 minute Amplitude: 1.5 mm 2 h i n e a c h X, Y, Z direction n = 6, C = 0 Initial × 0.8 > VO VO > Initial × 1.2 n = 11, C = 0 n = 11, C = 0 NOTES: 1. Test conditions are according to Electro-optical Characteristics, shown on page 2. 2. At completion of the test, allow device to remain at nominal room temperature and humidity (non-condensing) for two hours. 3. Confidence level: 90%, Lot Tolerance Percent Defect (LTPD): 20% / 40%. MANUFACTURER’S INSPECTION Inspection Lot Inspection shall be carried out per each delivery lot. Inspection Method A single sampling plan, normal inspection level II based on ISO 2859 shall be adopted. Table 2. Quality Level DEFECT INSPECTION ITEM and TEST METHOD AQL (%) Major Defect Electro-optical characteristics defect 0.4 Minor Defect Defect to appearance or dimensions (crack, split, chip, scratch, stain)* 1.0 NOTE: *Any one of these that affects the Electro-optical Characteristics shall be considered a defect.
PING)))™ Ultrasonic Distance Sensor (#28015) The Parallax PING))) ultrasonic distance sensor provides precise, non-contact distance measurements from about 2 cm (0.8 inches) to 3 meters (3.3 yards). It is very easy to connect to BASIC Stamp® or Javelin Stamp microcontrollers, requiring only one I/O pin. The PING))) sensor works by transmitting an ultrasonic (well above human hearing range) burst and providing an output pulse that corresponds to the time required for the burst echo to return to the sensor. By measuring the echo pulse width the distance to target can easily be calculated. The PING))) sensor has a male 3-pin header used to supply power (5 VDC), ground, and signal. The header allows the sensor to be plugged into a solderless breadboard, or to be located remotely through the use of a standard servo extender cable (Parallax part #805-00002). Standard connections are show in the diagram to the right. Quick-Start Circuit This circuit allows you to quickly connect your PING))) sensor to a BASIC Stamp® 2 via the Board of Education® breadboard area. The PING))) module’s GND pin connects to Vss, the 5 V pin connects to Vdd, and the SIG pin connects to I/O pin P15. This circuit will work with the example program Ping_Demo.BS2 listed on page 7. Servo Cable and Port Cautions If you want to connect your PING))) sensor to a Board of Education using a servo extension cable, follow these steps: 1. When plugging the cable onto the PING))) sensor, connect Black to GND, Red to 5 V, and White to SIG. 2. Check to see if your Board of Education servo ports have a jumper, as shown at right. 3. If your Board of Education servo ports have a jumper, set it to Vdd as shown. 4. If your Board of Education servo ports do not have a jumper, do not use them with the PING))) sensor. These ports only provide Vin, not Vdd, and this may damage your PING))) sensor. Go to the next step. 5. Connect the servo cable directly to the breadboard with a 3-pin header. Then, use jumper wires to connect Black to Vss, Red to Vdd, and White to I/O pin P15. Board of Education Servo Port Jumper, Set to Vdd © Parallax, Inc. • PING)))TM Ultrasonic Distance Sensor (#28015) • v1.3 6/13/2006