TECHNICAL TRAINING PROGRAM - PRE-STUDY MANUAL - e-STUDIO900/1050 Toshiba America Business Solutions
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WARNING The Pre-Training Manual contains information regarding service techniques, procedures, processes and spare parts of office equipment distributed by Toshiba Corporation. Users of this manual should be either service trained or certified by successfully completing a Toshiba Technical Training Program. Untrained and uncertified users utilizing information contained in this pre-training manual to repair or modify Toshiba equipment risk personal injury, damage to property or loss of warranty protection.
LEGEND PRODUCT CODE B070 B071 LCT B511 Finisher B478 Cover Int.
INTRODUCTION The Pre-Training Manual for the 900/1050 has been designed to give the Service Technician an overview of these products prior to attending the training program. This manual starts with the basic fundamentals utilized in the machine and reviews the entire copy process and accessories. It is the aim of the Service Education and Development Division to give the Service Technician as much hands-on experience as possible while attending training.
FLOWCHART FOR PRE-TRAINING MANUAL Technician is scheduled for school. Service Manager gives Technician Pre-Training Manual. (download) Technician completes pre-training. Once completing the training, the student completes the on-line exam. After the exam is passed the student receives immediate results. Service manager receives results. Student reviews the material and does further preparation. Student attends instructor led 5-day training program.
CONTENTS SECTION 1 OVERALL INFORMATION SECTION 2 DETAILED DESCRIPTIONS SECTION 3 SERVICE TABLES SECTION 4 INSTALLATION SECTION 5 LARGE CAPACITY TRAY SECTION 6 SR860 BOOKLET FINISHER with PUNCH UNIT SECTION 7 SR840 3,000-SHEET FINISHER with PUNCH UNIT SECTION 8 COVER INTERPOSER TRAY TYPE 1075 SECTION 9 MULTI BYPASS TRAY TYPE 2105
IMPORTANT SAFETY NOTICES PREVENTION OF PHYSICAL INJURY 1. Before disassembling or assembling parts of the copier and peripherals, make sure that the copier power cord is unplugged. 2. The wall outlet should be near the copier and easily accessible. 3. Note that some components of the copier and the paper tray unit are supplied with electrical voltage even if the main power switch is turned off. 4.
SAFETY AND ECOLOGICAL NOTES FOR DISPOSAL 1. Do not incinerate toner bottles or used toner. Toner dust may ignite suddenly when exposed to an open flame. 2. Dispose of used toner, developer, and organic photoconductors in accordance with local regulations. (These are non-toxic supplies.) 3. Dispose of replaced parts in accordance with local regulations. 4. When keeping used lithium batteries in order to dispose of them later, do not put more than 100 batteries per sealed box.
CONVENTIONS IN THIS MANUAL This manual uses several symbols. Symbol What it means Refer to section number See Core Tech Manual for details Screw Connector E-ring Clip ring NA North America EUR/A Europe/Asia LEF (Long Edge Feed) SEF (Short Edge Feed) LEFSEF.
SECTION 1 OVERALL INFORMATION
1. OVERALL MACHINE INFORMATION 1.1 SPECIFICATIONS 1.1.1 COPIER ENGINE Configuration: Copy Process: Originals: Original Size: Original Alignment: Paper Weight: Paper Size: Reproduction Ratios: Console Dry electrostatic transfer system Sheet/Book/Object Max.: A3/11" x 17" Min.: A5, 51/2" x 81/2" (with ADF) Rear left corner (for platen mode, ADF mode) Tray 1~3: 52 to 163 g/m2 Bond: 16 to 40 lb. Tray 6 (LCT): Cover: 50 to 60 lb. Index: 90 lb. Tray 4~5 (LCT): 52 to 216 g/m2 Tray 7 (Bypass): Bond: 16 to 40 lb.
Zoom: Copy Speed: 25 ~ 400% (allows manual adjustment in 1% steps vertically, horizontally) Copying with image stored in 900 90 ppm 1050 900/1050 Resolution Gradation: Warm-up Time: First Copy Time 75 ppm memory with A4/LT LEF feeding from the same tray. When using ADF 1-to-1 with A4/LT LEF magnification feeding from the same tray. Scanning Printing 256 levels 600 dpi 1200 dpi Scanning (8 bits/pixel) Printing (1 bit/pixel, 9 values): Less than 360 s from Off mode at 23°C (73.
Space Requirements: Copier (w x d) 1202 x 858.5 mm (47.3" x 33.8") Full System*1 (w x d) Max. Min. 2528 x 858.5 mm 99" x 33.7" 2804 x 858.5 mm 110.4" x 33.7" Finisher + Bypass with bypass tray extended for A3 SEF Finisher + Bypass with bypass tray extended for A4 LEF. Full System: Mainframe + ADF + Finisher B478 + LCT B511 + Cover Interposer Tray B470 + Bypass Tray B512 Power Consumption: North America Version (Unit: W) Mainframe Only 900 1050 2.20 K 2.20 K 0.65 K 0.65 K 2.70 K 2.80 K 2.80 K 2.
1.1.
1.2 MACHINE CONFIGURATION 10 7 2 1 6 3 5 4 B070I413.WMF No. 1 2 3 4 5 6 7 8 9 10 *1 Item Mainframe Bypass Tray LCT A3/DLT Tray Kit*1 3000 Sheet Finisher 3000 Sheet Booklet Finisher Punch Unit Output Jogger Unit Cover Interposer Tray Punch Unit Copier Connection Kit Machine Comments Code eStudio900/1050 900 (90 cpm), 1050 (105 cpm). MY1024 MP4501 KF9000 Replace Tray 1 (tandem tray) inside. MJ1026 N/A N/A KK9000 MJ7002 MJ6006 GE1130 Attached to Finisher Attached to Finisher.
1.3 COMPONENT LAYOUT 1.3.1 COPIER ENGINE 1 2 3 4 5 6 7 8 32 33 9 31 30 10 29 11 12 28 13 27 14 26 15 25 16 24 17 23 22 21 20 19 18 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. Laser Diode Board fθ Lenses Sensor Board Unit Exposure Lamp Cleaning Brush Lamp Regulator Cleaning Blade Charge Corona Unit Color LCD Drum Development Unit Registration Roller LCT Relay Roller Transfer Belt Unit Relay Roller Pick-up Roller 17. Vertical Transport Rollers B070/B071 18. 19. 20.
1.3.2 ADF Overview 1 2 3 4 5 6 7 8 9 B070D869.WMF 15 14 13 12 11 10 1. Entrance Sensor 9. Feed-out Roller 2. Separation Roller 10. Exit Junction Gate 3. Feed Belt 11. Inverter Roller 4. Pick-up Roller 12. Exit Sensor 5. Original Tray 13. Transport Belt 6. Inverter Junction Gate 14. Registration Sensor 7. Inverter Guide Roller 15. Width Sensors (x3) 8.
1.4 PAPER PATH 2 1 12 11 10 3 9 8 7 6 5 4 B070D871.WMF 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
1.5 COPY PROCESS 1 B070D872.WMF 2 10 3 4 9 5 8 7 6 B070D873.WMF 1. EXPOSURE A xenon lamp exposes the original. Light reflected from the original passes to the CCD, where it is converted into an analog data signal. This data is converted to a digital signal, processed, and stored in the memory. At the time of printing, the data is retrieved and sent to the laser diode. For multi-copy runs, the original is scanned once only and stored to the hard disk. 2.
3. LASER EXPOSURE The processed data from the scanned original is retrieved from the hard disk and transferred to the drum by four laser beams, which form an electrostatic latent image on the drum surface. The amount of charge remaining as a latent image on the drum depends on the laser beam intensity, which is controlled by the laser diode board (LDB). 4. DRUM POTENTIAL SENSOR The drum potential sensor detects the electric potential on the drum to correct various process control elements. 5.
SECTION 2 DETAILED DESCRIPTIONS
2. DETAILED SECTION DESCRIPTIONS 2.1 DOCUMENT FEEDER 2.1.1 PICK-UP ROLLER RELEASE [F] [E] [B] [C] [A] [D] B070D916.WMF When the original set sensor is off (no original on the original tray), the pick-up roller stays in the up position. When the original set sensor turns on (or when the trailing edge of a page passes the entrance sensor while pages remain on the original tray), the pick-up motor [A] turns on. The cam [B] rotates away from the pick-up roller release lever [C].
2.1.2 BOTTOM PLATE LIFT [F] [E] [B] [A] [D] [C] [B] [F] B070D917.WMF When an original is placed on the original tray, the original set sensor [A] turns on, the pick-up roller [B] drops on to the original, and the bottom plate position sensor [C] turns off. Then the bottom plate motor [D] turns on and lifts the bottom plate [E] by raising the lift lever [F] until the bottom plate position sensor turns on.
2.1.3 PICK-UP AND SEPARATION [D] [A] [B] [E] [C] [A] [B] B070D918.WMF [C] B070D919.WMF The original separation system is a Feed and Reverse Roller (FRR) system. The pickup roller [A], feed belt [B], and separation roller [C] are driven by the feed-in motor [D]. To drive this mechanism, the feed-in motor [D] and feed-in clutch [E] turn on.
2.1.4 ORIGINAL FEED [D] [B] [A] [C] B070D920.WMF When the leading edge of the original turns the entrance sensor [A] on, the feed-in clutch [B] turns off and the drive for the feed belt is released. The original is fed by the transport rollers [C]. At the same time, the pick-up motor starts again and the pick-up roller [D] is lifted up. When the pick-up roller HP sensor turns on, the pick-up motor stops (see Pick-up Roller Release).
2.1.5 ORIGINAL SIZE DETECTION [B] [C] [G] [D] [F] [A] [E] The ADF detects the original size by combining the readings of original length sensor [A], and original width sensors-1 [B], -2 [C], and -3 [D]. Original Length The original length sensor and the disk [E] (connected to the transport roller) generate a pulse signal. The CPU counts pulses, starting when the leading edge of the original turns on the registration sensor [F], until the trailing edge of the original turns off the entrance sensor [G].
2.1.6 ORIGINAL TRANSPORT [B] [A] [C] B070D923.WMF [E] [D] 3.5 mm B070D924.WMF The transport belt [A] is driven by the transport belt motor [B]. The transport belt motor starts when the copier sends an original feed-in signal. The pressure rollers inside the transport belt maintain the correct pressure between belt and original. The pressure roller [C] closest to the left original scale is made of rubber for the stronger pressure needed for thick originals. The other rollers are sponge rollers.
2.1.7 ORIGINAL SKEW CORRECTION [A] 7 mm B070D925.WMF [B] The transport belt motor remains energized to carry the original to the right about 7 mm past the left scale [A]. Then the motor stops and reverses to feed the original 12 mm to the left against the left scale to correct skew. This forces the original to hit the left scale, which aligns the trailing edge to minimize original skew on the exposure glass. If thin original mode is selected, the original is not forced back against the left scale.
2.1.8 ORIGINAL INVERSION AND FEED-OUT General Operation [A] B070D926.WMF When the scanner reaches the return position, the copier CPU sends the feed-out signal to the ADF. When the ADF receives the feed-out signal, the transport belt motor and feed-out motor [A] turn on. The original is then fed out to the exit tray or fed back to the exposure glass after reversing in the inverter section. This ADF has two exit trays.
Original Inversion [F] [B] [E] [G] [D] [A] [C] B070D927.WMF When the ADF receives the original invert signal from the copier, the transport belt motor, feed-out motor, exit gate solenoid [A], and inverter gate solenoid [B] turn on and the original is fed back to the exposure glass through the inverter roller [C], exit gate [D], inverter guide roller [E], inverter gate [F], and inverter roller.
Original Exit (Single-Sided Original Mode) [B] [A] [C] B070D928.WMF The exit gate solenoid [A] remains off, the exit gate [B] remains closed, and the original is fed out to the right exit tray. The speed of the motor is reduced about 30 mm from the trailing edge of the original to ensure the originals stack neatly on the exit tray. This timing is determined by the length of the original, and the time since the exit sensor [C] detected the leading edge.
Original Exit (Double-Sided Original Mode) [C] [E] [A] [B] [D] B070D929.WMF The exit gate solenoid [A] turns on and the exit gate [B] opens. The inverter gate solenoid [C] remains off, and the original is fed out to the upper tray. The transport belt motor turns off when the trailing edge of the original passes the exit sensor [D]. To stack the originals neatly on the upper tray, the feed-out motor speed is reduced shortly after the trailing edge of the original turns off the inverter sensor [E].
2.2 SCANNING 2.2.1 OVERVIEW 1 2 3 4 6 5 7 8 9 10 13 12 B070D001.WMF 11 1. Scanner Motor 10. LCDC (LCD Control Board) 2. White Plate (on exposure glass) 11. CCD (Charge Coupled Device) 3. 2nd Mirror 12. Original Length Sensor (APS) 4. Exposure Lamp (Xenon) 13. Scanner Lens 5. Exposure Glass 14. 3rd Mirror 6. 1st Mirror 15. Original Width Sensors 1, 2, 3 (APS) 7. Lamp Regulator 16. Scanner HP Sensor 8. SBU Cooling Fan 17. Optics Anti-condensation Heater (option) 9.
2.2.2 SCANNER DRIVE [C] [D] [E] [B] [A] [F] [G] B070D003.WMF The scanner motor is a dc servo motor. The 1st and 2nd scanners [A, B] are driven by the scanner motor [C] through the timing belt [D], scanner drive pulley [E], scanner drive shaft [F], and two scanner wires [G]. The MCU (Motor Control Unit) board controls the scanner motor. The exposure lamp scans a sheet with 100% magnification at 515 mm/s and returns to the scan position for the next scan at 2500 mm/s.
2.2.3 ORIGINAL SIZE DETECTION [F] [G] [A] B070D052.WMF [B] [C] [D] [E] B070D535.WMF There are three reflective sensors at three locations in the optics cavity for original size detection. The original width sensor [A] detects the original width, and the original length sensor 1 [B] and original length sensor 2 [C] detect the original length. These are the APS (Auto Paper Select) sensors.
NOTE: The Europe/Asia model has one length sensor (L1), but the North American model has two length sensors (L1, L2) Original Size A4/A3 Version A3 B4 F4 A4 SEF B5 SEF A5 SEF A4 LEF B5 LEF A5 LEF LT/DLT Version 11" x 17" 10" x 14" 81/2" x 14" (8" x 13") 81/2" x 11" — 51/2" x 81/2" 11" x 81/2" — 81/2" x 51/2" Length Sensor 2 1 H H H H H H H H L L L L L L L L L L SP4301 Display Width Sensor 1 2 H H H H L L H H H H H L L L L H H 3 H 00011111 00011110 00011100 00001100 00001000 00000000 00000111 00
2.3 IMAGE PROCESSING 2.3.1 IMAGE PROCESSING STEPS AND RELATED SP MODES The following tables describe the image processing path and the related SP modes used for each image processing mode. The user can adjust many of the image processing parameters with a UP mode (Copy/Document Server Features> General Features> Original Mode Quality Level), using fixed settings such as Sharp, Normal, and Soft.
2.3.2 IMAGE PROCESSING OVERVIEW CCD SBU PCI BUS BCU IPU Controller Polygon Motor LDB HDD Key Data flow OPC Signal flow B070D934.WMF SBU: Photoelectric conversion, Odd/even allocation, Amplification, A/D Conversion (analog to digital), Light intensity detection (scanning) BCU: Engine control, Scanner control, SBU settings, IPU settings, LDB settings IPU: Shading correction, Image Processing, Main/Sub scan magnification, Video path switching, Image Compression/ Decompression.
2.3.3 IMAGE PROCESSING FLOW Image processing is done by the IPU (Image Processing Unit), following the steps shown below. Overall image processing for this machine is designed to: • Target edges with filters to improve the angles of text characters and reduce the occurrence of moiré filled areas. • Improve the evenness of granular areas in images Corrects the dispersion of the scanning lens and CCD.
PTM 2-19 B070/B071
2.3.4 IMAGE PROCESSING MODES The user can select one of the following five modes with the User Tools screen: Text, Text/Photo, Photo, Pale, Generation. Each mode has four different settings (described below). Each mode has a Custom Setting that can be customized with SP modes to meet special requirements that cannot be covered by the standard settings. NOTE: To see these settings in the User Tools mode, press the User Tools key, press “Copier/Document Server Functions”, then press “Copy Quality”.
Custom Setting Strong Background Dropout Medium Weak PTM Stores SP command settings. Drops out the blue background color of tab sheets or other paper. Drops out the green background color of tab sheets or other paper. Drops out the orange background color of tab sheets or other paper.
2.3.5 IMAGE QUALITY SP ADJUSTMENTS Adjustments are easier with this machine, because the parameters have been grouped and no longer have to be adjusted one by one. In this section, we will cover the custom settings for each of the 5 original modes: These custom settings are: • Image Quality • Line Width Correction Settings adjustable for each original mode will also be covered (these do not just affect the custom settings; they also affect all sub original modes, such as sharp text).
Custom Setting: Photo Mode (Dithering) Image Quality Item Photo 25~55% 55.5~75% 75.5~160% 160.5~400 % Range Default 0~6 3 Print Photo SP No. SP4903 005 SP4903 006 SP4903 007 SP4903 008 Used for coarse, dithered tone photographs such as newsprint. If the value is increased, the photo becomes sharper, but blurring could occur in the sub scan direction. If the value is decreased, blurring in the sub scan direction is less obvious but outlines become fuzzy.
Custom Setting: Pale Mode Image Quality Item Pale 25~55% 55.5~75% 75.5~160% 160.5~400 % Range Default 0~10 5 Normal SP No. SP4903 017 SP4903 018 SP4903 019 SP4903 020 If the value is increased, low density areas become sharper, but the background could become dirtier. If the value is decreased, the background disappears but the density of low density areas becomes low. Custom Setting: Generation Mode Image Quality Item Generatio n 25~55% 55.5~75% 75.5~160% 160.
Custom Settings for Each Mode: Line Width Correction Custom Setting: Text Mode Line Width Correction Selection Line Width Correction Item Main Scan Sub Scan Range Default 0~8 2 0~1 0~1 1 1 Content 0 (Thin) - 4 (Off) - 8 (Thick) 0:OFF 1:ON 0:OFF 1:ON SP No. SP4903 080 SP4903 081 SP4903 082 If the value is made smaller, the line width correction becomes thinner, and if the value is made larger, the line width correction becomes thicker. To switch this feature off, select “4”.
Custom Setting: Pale Mode Line Correction Selection Line Width Correction Item Main Scan Sub Scan Range Default 0~8 4 0~1 0~1 1 1 Content 0 (Thin) - 4 (Off) - 8 (Thick) 0:OFF 1:ON 0:OFF 1:ON SP No. SP4903 089 SP4903 090 SP4903 091 See the remarks for ‘Custom Setting: Text Mode Line Width Correction’ above. If the above settings do not make the lines thin enough, use SP4904 023 (Image Quality Exposure: Thin Line – Pale Mode). Normally, SP4904 023 is set to 0 (OFF).
Settings Adjustable for Each Original Mode Independent Dot Erase Item Text Photo Text/Photo Pale Generation Copy Range 0~14 Default 8 0 0 0 8 SP No. SP4903 060 SP4903 061 SP4903 062 SP4903 063 SP4903 064 Independent dot erase removes isolated black pixels. As this setting is increased, the greater the number of eliminated isolated pixels. Setting to zero switches this function off. Background Erase Item Text Photo Text/Photo Pale Generation Copy Range Default 0~255 0 (Off) SP No.
2.3.6 RELATION BETWEEN THE SP AND UP SETTINGS The tables below illustrate the relationship between the UP and SP settings for each of the 5 original modes. The scale across the top of the table is the range of settings for the SP modes. The settings in the gray areas indicate the UP settings overlaid on the SP scale of the table. Words that are not shaded within the tables, such as ‘softer’, indicate how the image changes if you change the SP setting is a certain direction.
Text/Photo Mode 2 3 4 Photo Priority 25% ~55% 1 55.5 ~ 75% 75.5 ~ 160% 160.5 ~ 400% 5 6 7 8 9 10 SP No. SP4903 013 Text Priority 0 Normal Setting SP4903 014 SP4903 015 SP4903 016 Pale Mode Setting 0 1 2 3 4 5 6 7 8 9 10 SP4903 017 75.5 ~ 160% SP4903 018 Sharp Soft 55.5 ~ 75% Normal 25% ~55% SP No. SP4903 019 SP4903 020 160.5 ~ 400% Generation Copy Setting 0 1 2 3 4 5 6 7 8 9 SP No. SP4903 021 75.5 ~ 160% Sharp Soft 55.
2.4 LASER EXPOSURE 2.4.1 OVERVIEW 1 2 3 4 5 6 7 12 11 8 10 B070D101.WMF 9 1. LD Unit 7. 2nd Mirror 2. Polygon Mirror Motor Control Board 8. Drum 3. Polygon Mirror Motor 9. Toner Shield Glass 4. F-Theta Lens 1 10. 1st Mirror 5. F-Theta Lens 2 11. Laser Synchronization Detector 6. BTL Lens 12.
2.4.2 LASER EXPOSURE MECHANISM [D] [A] [B] [C] B070D102.WMF The LD unit consists of two 4-channel LDA’s (Laser Diode Arrays) and two collimating lenses. Each LDA produces 4 beams [A]. Each collimating lens [B] is a fixed lens, seated in a V-groove and held in place by a spring and a screw. Four beams from each LDA [C] pass through the collimating lenses, though the apertures [D], then strike the polygonal mirror.
2.4.3 LD SAFETY SWITCHES Inter Lock S W LD B +5V PSU FA N P O LYG O N +24V +LD 5V IP U D A TA 0 D A TA 0 XAPC0 LD D D A TA 0 1k LD 0 510 XAPC 0 5k D A TA 1 D A TA 1 XA PC 1 D A TA 2 D A TA 2 D A TA 3 D A TA 3 D A TA 1 1k LD 1 XA PC 1 D A TA 2 D A TA 3 BGAVD2 D A TA 4 D A TA 4 XA PC 4 D A TA 5 D A TA 5 XA PC 5 D A TA 6 D A TA 6 D A TA 7 D A TA 7 D A TA 4 LD 4 1k 510 XA PC 4 5k D A TA 5 LD 5 1k XA PC 5 D A TA 6 D A TA 7 LD 5V 6.8k LD O FF LD O FF 10k B070D998.
2.4.4 MULTI-BEAM LINE EXPOSURE [A] B070D212.WMF The LD unit contains two laser diode arrays (LDA) [A], each with one 4-channel array, allowing the LD unit to produce a total of eight beams. This multi-beam exposure mechanism has the following advantages: • Reduces the number of rotations required of the polygon mirror motor. • Reduces the amount of noise generated by the polygon mirror motor because it is rotating at lower speed. • Reduces the need for LD unit replacement.
2.4.5 POLYGON MIRROR MOTOR The polygon mirror reflects the laser beam onto the OPC drum to expose the image line by line in the main scan direction. The polygon mirror motor rotates at a constant speed, even while the copier is in standby mode, but shuts off when the copier enters the energy conservation mode. The polygon mirror motor has no brake mechanism, so it requires about 3 minutes to stop rotating.
2.4.6 1200-DPI RESOLUTION Sub Scan 0 1-22 4 LDA 0 LDA 1-0 7 5 3 1 4 6 21.2 µm (1200 dpi) 42.3 µm (600 dpi) 22.3 mm 1 LDA 2-0 Main Scan B070D210.WMF 5 LDA 2-2 2 LDA 1-1 6 LDA 1-3 3 LDA 2-1 7 LDA 2-3 The original is scanned at 600 dpi, then the 600 dpi output is boosted to 1200 dpi 1-bit data during image processing in the IPU. This machine can produce an image at 1200 dpi by writing each dot twice, possibly with two different values, depending on the results of image processing.
2.4.7 OPTICAL PATH [D] [C] [B] [E] [A] [F] [G] [H] [I] [J] [K] B070D101.WMF The output path from the laser diode to the drum is shown above. The LD unit [A] outputs eight laser beams to the polygonal mirror [B] (six mirror surfaces) through the cylindrical lens [C] and the 1st mirror [D]. Each surface of the polygon mirror reflects eight full main scan lines. The laser beams go to the F-theta lens 1 [E], F-theta lens 2 [F], BTL (barrel toroidal lens) [G], and mirror [H].
2.5 DRUM UNIT 2.5.1 PROCESS CONTROL Drum potential gradually changes for the following reasons: • Dirty optics, exposure glass • Dirty charge corona casing, grid plate • Deterioration of drum sensitivity What Happens at Power On Here is a description of what happens while the fusing temperature is below 100°C immediately after the main power switch is switched on (process control must also be enabled with SP3901 001, or this will not happen).
2.5.2 DRUM UNIT COMPONENTS 8 9 1 7 2 6 5 B070D865.WMF 4 3 The drum unit consists of the components shown in the above illustration. An organic photoconductor drum (diameter: 100 mm) is used for this model. 1. 2. 3. 4. 5. PTM OPC Drum Drum Potential Sensor Pick-off Pawl Image Density Sensor Toner Collection Coil 6. 7. 8. 9.
2.5.3 DRUM DRIVE [C] [A] [B] [D] B070D202.WMF The drive from the drum motor [A] is transmitted to the drum and the cleaning unit through timing belts, gears, the drum drive shaft [B], and the cleaning unit coupling [C]. The drum motor has a drive controller, which outputs a motor lock signal when the rotation speed is out of the specified range. The drum speed for the B070 (90 cpm) is 450 mm/s and for the B071 (105 cpm) 500 mm/s.
2.5.4 DRUM CHARGE Overview [A] B070D203.WMF This copier uses a double corona wire Scorotron system to charge the drum. Because of the high speed of this copier, two corona wires are needed to give a sufficient, uniform negative charge to the drum surface. The stainless steel grid plate makes the corona charge uniform and controls the amount of negative charge on the drum surface by applying a negative voltage to the grid.
Charge Corona Wire Cleaning [D] [A] [A] [B] [C] B070D558.WMF Air flowing around the charge corona wire may deposit toner particles on the corona wires. These particles may interfere with charging and cause low density bands on copies. The wire cleaner pads [A] automatically clean the wires to prevent such a problem. The wire cleaner is driven by a dc motor [B]. Normally the wire cleaner [C] is at the front end (the home position).
2.5.5 DRUM CLEANING Overview [C] [A] [B] [A] [A] [D] B070D866.WMF [B] [E] [B] B070D867.WMF This copier uses a counter blade system to clean the drum. In a counter blade system, the drum cleaning blade [A] is angled against drum rotation. The counter blade system has the following advantages: • Less wearing of the cleaning blade edge • High cleaning efficiency Due to the high efficiency of this cleaning system, the pre-cleaning corona and cleaning bias are not used for this copier.
2.5.6 CLEANING UNIT DRIVE [B] [A] [D] [C] B070D206.WMF Drive from the drum motor is transmitted to the cleaning unit drive gear via the timing belt [A] and the cleaning unit coupling [B]. This coupling drives the cleaning brush [C] directly. The cleaning brush then transmits the drive to the gear at the front, which drives the toner collection coil gear [D].
Cleaning Blade Pressure and Side-to-Side Movement [C] [D] [B] [A] B070D868.WMF The spring [A] always pushes the cleaning blade against the drum. The cleaning blade pressure can be manually released by pushing up the release lever [B]. To prevent cleaning blade deformation during transportation, the release lever must be locked in the pressure release (upper) position. The guide roller [C] at the rear end of the cleaning blade holder touches the cam gear [D], which moves the blade from side to side.
2.5.7 OTHERS Air Flow Around the Drum [E] [G [B] [C] [A] B070D208.WMF [D] [F] The drum cooling fan [A] draws cool air through the filter [B] and sends it to the center of the drum [C], then over the charge corona unit [D]. Holes in the flanges on both ends of the drum allow air to pass through the drum to cool it.
Drum Pick-off Pawls [A] [B] [C] B070D559.WMF [D] If the paper does not separate from the drum after image transfer, the drum pick-off pawls strip the paper from the drum. Pressure from small springs [A] press the pick-off pawls [B] against the surface of the drum. The shaft [C] and the cam [D] move the pick-off pawls from side to side to ensure that they never remain at the same location (this prevents wear on the drum).
Drum Quenching [A] B070D209.WMF In preparation for the next copy cycle, light from the quenching lamp [A] neutralizes any charge remaining on the drum. The quenching lamp consists of an array of 16 red LEDs extending across the full width of the drum.
2.6 DEVELOPMENT 2.6.1 OVERVIEW 6 7 8 1 2 3 9 4 10 13 5 B070D301.WMF 11 12 1. 2. 3. 4. 5. 6. 7. B070D302.WMF Hopper Filter Hopper Center Filter Toner Hopper Sensor Agitator Toner Supply Roller Upper Development Roller Doctor Blade 8. 9. 10. 11. 12. 13. Separator Toner Transport Coil Development Agitator TD Sensor Paddle Roller Lower Development Roller This copier uses a double roller development system and a dual component development process with toner particles 6.
2.6.2 DEVELOPMENT MECHANISM [E] [F] [G] [C] [H] [A] [D] B070D303.WMF Toner and developer are mixed in the toner agitator[B] by the cross-mixing roller [A]. The paddle roller [B] picks up the developer and sends it to the upper development roller [C]. Internal permanent magnets in the development rollers attract the developer to the development roller sleeve. Developer from the upper development roller sleeve is also attracted to the lower development roller [D].
2.6.3 DRIVE [C] [D] [F] [B] [E] [A] B070D304.WMF The gears in the development unit are driven by the development drive gear [A] when the development motor [B] (a dc servomotor) turns. The gears in the toner hopper are driven by the toner supply roller drive gear [C] when the toner supply roller clutch [D] activates. A one-way clutch on the paddle roller knob [F] prevents counter-clockwise rotation of the paddle roller.
2.6.4 CROSSMIXING [C] [B] [E] [F] [A] [D] [C] B070D303.WMF [E] [B] [F] [A] [D] B070D571.WMF This copier uses a standard cross-mixing mechanism to keep the toner and developer evenly mixed. It also helps agitate the developer to prevent developer clumps from forming and helps create the triboelectric charge. The developer on the turning development rollers [A] is split into two parts by the doctor blade [B].
2.6.5 DEVELOPMENT BIAS [A] [B] [C] [D] B070D305.WMF The CBG (Charge Bias Grid) power pack [A] applies the negative development bias (550V) to both the lower sleeve roller and upper sleeve roller through the receptacles [B] and the sleeve roller shafts [C]. The development bias prevents toner from being attracted to the non-image areas on the drum where there is residual voltage. In addition, the development bias changes with the image density setting chosen for the copy job by the user.
2.7 TONER SUPPLY AND RECYCLING [G] 2.7.1 OVERVIEW [C] [F] [B] [E] [A] [D] Toner is supplied from a toner bank [A] on the left side of the machine and separated from the development unit. The toner bank holds two bottles, but only one bottle operates at a time. A toner bottle motor turns the bottle [B], causing toner to leave the bottle and drop into the toner entrance tank [C]. The toner transport coil in the toner transport tube [D] transports toner to the toner supply cylinder [E].
2.7.2 TONER BANK Toner Bottle Switching Mechanism [D] [C] [B] [A] [E] B070D901.WMF When the upper toner bottle [A] is supplying toner, the upper bottle cap motor [B] pulls out the toner bottle cap. The upper bottle cap sensor [C] detects the actuator [D] of the toner bottle opening rod, then the motor shuts off to close the cap again.
Toner Near-end, Toner End, Bottle Replacement [B] [A] B070D911.WMF [D] [C] B070D909.WMF Each toner bottle [A] has an independent toner bottle motor [B]. An empty toner bottle can be replaced during printing. The toner near-end sensor detects toner as it falls from the toner bottle into the toner entrance tank [C]. If the toner near end sensor [D] detects that no toner has come out of the toner bottle, the toner bottle enters the toner near-end condition.
Meanwhile, the machine indicates that the first bottle is empty. When the user takes out the old bottle, and puts in a new one, this is detected by the toner bottle sensor. ( ”Toner Bottle Sensors”,2-57) However, this bottle is not tested until the second bottle is empty. NOTE: If an empty bottle is not replaced, and the other bottle becomes empty (no toner detected 10 consecutive times, as described above), 200 more copies can be made.
Toner Bottle Sensors [A] [C] B070D912.WMF [D] [B] B070D913.WMF [E] [F] B070D914.WMF When placing a toner bottle in the toner bank, the toner bottle pushes the lock arm [A] downwards. Then the lock arm catches the toner bottle and also pushes down lever [B]. This causes toner bottle sensor [C] to detect that a bottle has been installed (the actuator leaves the toner bottle sensor while the bottle is being inserted in the holder).
2.7.3 SUPPLYING TONER TO THE DEVELOPMENT UNIT [H] [B] [I] [A] [G] [D] [F] B070D902.WMF [C] [E] B070D906.WMF The toner bottle motor turns the toner bottle [A], causing toner to leave the bottle and drop into the toner entrance tank [B]. NOTE: Recycled toner in the tube from the drum cleaning unit also enters the toner entrance tank, and is mixed with fresh toner from the toner bottle. The toner transport coil [C] in the toner transport tube transports toner to the toner supply cylinder [D].
If the toner hopper sensor (in the toner hopper - Toner Hopper) detects an insufficient amount of toner in the hopper, the toner bank mechanism is started up. If there is sufficient toner in the toner entrance tank (detected by the toner near end sensor in the toner bank), the toner supply coil clutch turns on for 2 seconds. The toner supply pump motor turns on for 7 seconds at the same time as the toner supply coil clutch.
2.7.4 TONER HOPPER Toner Supply [G] [C] [E] [A] [F] [B] [D] [G] [F] A294D306.WMF When the toner supply roller clutch [A] (inside the development motor unit [B]) turns on, the agitator [C] mixes the toner transported by the air tube [G] from the toner bank (the toner from the toner bank is new toner mixed with recycled toner). Then it moves the toner from front to rear and sends it to the toner supply roller. Toner is caught in the grooves in the toner supply roller [F].
Toner Hopper Empty Detection [A] [B] A294D307.WMF The toner hopper sensor [A] detects whether there is enough toner in the toner hopper. The toner hopper sensor checks for toner once when the toner supply roller clutch turns on. When there is only a small amount of toner inside the toner hopper and pressure on the toner hopper sensor becomes low, the toner hopper sensor outputs a pulse signal (once per copy).
2.7.5 TONER RECYCLING AND WASTE TONER COLLECTION Overview [C] [B] [A] B070D903.WMF To recycle used toner for re-use, the toner recycling coil in the tube [A] transports the toner collected by the drum cleaning to the toner entrance tank for recycling. To collect waste toner that will no longer be used, the toner collection coil in the tube [B] transports the toner collected by the transfer belt unit to the waste toner collection bottle.
Toner Recycling The toner recycling coil in the tube [A] transports the toner collected by the drum [E] [F] [B] [D] [A] [C] B070D904.WMF B070D906.WMF cleaning unit to the toner entrance tank [B] for recycling. This toner is dropped into the toner entrance tank and mixed with fresh toner from the toner bottle. The toner bank motor [C] drives the toner transport coil via the toner supply coil clutch [D].
2.8 PAPER FEED 2.8.1 OVERVIEW 1 2 3 4 5 10 6 7 8 1. Duplex Tray 6. Feed Roller 2. Relay Roller 7. Separation Roller 3. Upper Registration Roller 8. 3rd Tray (Universal) 4. Grip Roller 9. 2nd Tray (Universal) 5. Pick-up Roller 10. 1st Tray (Tandem) This model has three paper tray feed stations. The 1st tray (10), the tandem feed tray, holds 2,000 sheets of paper (1,000 sheets x 2 stacks).
2.8.2 DRIVE 7 6 5 3 2 1 9 4 8 3 2 B070D709.WMF 1. Paper Feed Motor 6. Upper Relay Clutch 2. Paper Feed Clutches 1 to 3 7. LCT Relay Clutch 3. Vertical Transport Clutches 1 to 3 8. One-way Gear 4. Lower Relay Clutch 9. Knob 5. Relay Motor The paper feed motor (1) drives feed, pick-up, and separation rollers in trays 1, 2, and 3 via timing belts, clutches (2), and gears. The paper feed motor also drives the vertical transport rollers and the lower relay roller.
2.8.3 VERTICAL TRANSPORT [A] [C] [B] B070D617.WMFF The vertical transport rollers [A] in each feed unit are all driven by the paper feed motor. The vertical transport rollers and the vertical transport idle rollers [B], on the inner and outer vertical guide plates, transport the paper up from each feed unit towards the relay and registration rollers. The vertical transport guides [C] can be opened to remove jammed paper in the vertical transport area.
2.8.4 PAPER REGISTRATION Overview [A] [C] [E] From the LCT [B] [C] B070D702.WMF The registration sensor [A] is positioned just before the registration rollers [B]. When the paper leading edge activates the registration sensor, the registration motor is off and the registration rollers are not turning. However, the upper relay roller (or LCT relay roller for feed from the LCT) [C] stays on for a bit longer.
2.9 IMAGE TRANSFER AND PAPER SEPARATION 2.9.1 OVERVIEW [B] [A] [F] [C] [E] B070D401.WMF [D] The transfer belt unit consists of the following parts: [A]: Transfer belt A belt (length: 321 mm) with high electrical resistance which holds a high positive electrical potential to attract toner from the drum to the paper. Also, the electrical potential attracts the paper itself and helps the paper to separate from the drum.
2.9.2 TRANSFER BELT UNIT LIFT [C] [E] [A] [D] [E] [B] [F] B070D506.WMF The transfer belt lift solenoid [A] inside the transfer belt unit turns on to raise the transfer belt into contact with the drum. The front lever [B] and the rear lever [C] are connected to the solenoid by links [D], and they push up the stays [E] when the solenoid turns on. The support spring [F] helps the solenoid to raise the transfer belt. The solenoid turns off after the copy job is finished.
2.9.3 TRANSFER BELT CLEANING [B] [C] [D] [A] B070D403.WMF Some toner may adhere to the transfer belt when paper jams occur. The adhered toner must be removed to prevent the rear side of the copy paper from getting dirty. The cleaning blade [A] scrapes off any toner remaining on the transfer belt. This is a counter blade system.
2.9.4 TONER COLLECTION [D] [A] [C] [B] B070D505.WMF Transfer belt drive is transmitted to the toner collection coil [A] through idle gears [B]. The toner collection coil [C] transports the collected toner to the toner recycling unit [D] and from there it goes to the waste toner collection bottle. See Toner Supply and Recycling for details.
2.9.5 DRUM ANTI-CONDENSATION HEATER [A] B070D048.WMF The drum anti-condensation heater [A] is located under the transfer belt unit. It turns on when the main switch is off to prevent moisture from forming on the transfer belt. The heater is included in the machine at the factory, but the connector is not connected.
2.10 FUSING 2.10.1 OVERVIEW [E] [D] [A] [G] [F] [C] [B] [H] [I] B070D501.WMF After transferring the image, the copy paper enters the fusing unit. A heat and pressure process using a hot roller [A] and a pressure roller [B] fuses the image to the copy paper. There are three fusing lamps of different wattage [C] inside the hot roller. They are turned on and off to maintain the target fusing temperature.
2.10.2 OIL SUPPLY AND CLEANING [B] [C] [D] [A] B070D553.WMF [E] B070D504.WMF The oil supply and cleaning web [A] feeds the web felt soaked with silicone oil. Springs [B] hold a roller under the web [C] against the hot roller [D]. This intermediate roller applies a light coat of silicone oil to the hot roller and removes paper dust and toner from the hot roller. A spring clutch inside the mechanism pulls the web to take up the slack, to prevent it getting pulled in between the fusing rollers.
[D] [C] [A] [B] [E] B070D555.WMF SP1902 001 displays the web consumption. When the web consumption exceeds the value set with SP1-902-4 (Web Near End), the machine indicates web near-end on the operation display. The machine still operates while the actuator [A] remains above the web end sensor [B] undetected.
SP1902 004 (Web Near End) can be adjusted to change the near-end period. The defaults for and amount of web that remains for copying are different for NA and EUR/A. Near-End Area NA EUR/A Near-End 90% 86% Web Remaining 600K 350K The table below, provided for your reference, shows approximately how adjustment of SP1902 002 affects the near-end and end displays on the B070 (90 cpm) or B071 (105 cpm).
2.11 PAPER EXIT/DUPLEX 2.11.1 OVERVIEW [A] [B] [C] B070D661.WMF The printed page from the fusing unit goes either straight through to the output tray or finisher, or downward through to the inverter or duplex unit, depending on the position of the junction gate [A]. If the page is fed out directly, it arrives on the tray face-up. If the user selected facedown output, the page goes to the inverter [B] before being fed out.
2.11.2 INVERTER Feed-in and Jogging [A] [D] B070D802.WMF [C] [B] B070D803.WMF The inverter feed roller [A] feeds paper to the jogger section. After the trailing edge of the paper passes through the inverter feed roller, the jogger fences [B] move to square the paper. This happens every page. The jogger motor (a stepper motor) [C] moves the jogger fences [B] inward or outward.
Feed-out [D] [B] [A] B070D804.WMF [C] [E] [B] [F] [C] B070D805.WMF After jogging, the reverse roller solenoid [A] energizes to push down the reverse trigger roller [B]. The reverse roller [C] turns counterclockwise continuously, so the paper starts to reverse when the reverse trigger roller is down and catches the paper between the rollers. The inverter guide plate solenoid [D] energizes to lower the inverter guide plate [E], so that the paper is guided by the inverter guide plate.
2.11.3 DUPLEX TRAY FEED MECHANISM [A] [B] [C] [D] [E] [F] B070D806.WMF In duplex mode, after the paper leaves the inverter, the duplex inverter gate solenoid [A] switches the junction gate [B] to direct the paper to the duplex tray. The paper is fed through the duplex tray by duplex transport rollers 1 [C], 2 [D], 3 [E], and the duplex feed roller [F]. If duplex mode is not selected, the solenoid does not switch the junction gate, and the paper goes to the output tray or finisher face down.
2.11.4 BASIC DUPLEX FEED OPERATION To improve the productivity of duplex copying, a non-stacking style duplex mechanism is adopted. This type of mechanism allows more than one page to be processed at once, in a process called ‘interleaving’. Examples of this are given below. For paper lengths up to A4/Letter LEF, the top duplex speed is possible, with the duplex unit processing four sheets of copy paper at the same time.
2. The back of the 1st sheet is printed (2nd page). 3. The 2nd, 3rd, 4th sheets (3rd, 5th, and 7th pages) go into the duplex unit. 4. The 5th sheet (9th page) is fed in. B070D808.WMF 5. The 5th sheet is printed (9th page). 6. The 1st sheet is fed out (1st and 2nd pages printed). B070D809.WMF 7. The 5th sheet (9th page) is directed to the duplex unit. 8. The 6th sheet (11th page) is fed. 9. The back of the 2nd sheet is printed (4th page). B070D810.
10. The 2nd sheet is fed out (3rd and 4th pages printed). 11. The 6th sheet is printed (11th page) and directed to the duplex unit. 12. The back of the 3rd sheet (6th page) is printed. 13. The 7th sheet is fed and printed (13th page). B070D811.WMF 14. The back of the 4th sheet is printed (8th page) and fed out (7th and 8th page). 15. The back of the 5th sheet is printed (10th page) and fed out (9th and 10th pages). 16. The back of the 6th sheet is printed (12th page) and fed out (11th and 12th pages). 17.
2. The first 2 sheets go into the duplex unit. B070D858.WMF 3. The back of the 1st sheet (2nd page) is printed. 4. The 3rd sheet (5th page) is fed and printed. B070D859.WMF 5. The 1st sheet (1st and 2nd pages) is fed out. 6. The back of the 2nd sheet (4th page) is printed. 7. The 4th sheet (7th page) is fed and printed. B070D860.WMFF 8. The 2nd sheet (3rd and 4th pages) is fed out. 9. The back of the 3rd sheet (6th page) is printed. 10. The 3rd sheet (5th and 6th pages printed) is fed out. 11.
2.12 ENERGY CONSERVATION MODES 2.12.1 OVERVIEW Operation Stand-by Mode Auto Off Mode Energy Sav er Key Auto Off Tim er PC Signal Fusing lam p off. Energy Saver LED Off 5V Off Night Mode System 5V Off +5VE On Panel off Tim er Energy Saver Mode Energy Saver Key Selected by UP m ode Fusing lam p to low temp.
2.12.2 ENERGY SAVER MODE Entering the energy saver mode The machine enters energy saver mode when one of the following is done. • The Energy Saver Key is held down for a second. • The panel off timer runs out after the last job (User Tools - System Settings - Timer Setting - Panel Off Timer: default setting is 60 s).
2.12.3 LOW POWER MODE Entering the low power mode The machine enters low power mode when: The energy saver timer runs out after the last job. (User Tools - System Settings - Timer Setting - Energy Saver Timer: default setting is 15 min) What happens in low power mode The fusing lamp drops to the prescribed temperature, as shown in the table below (the temperature drops more than that in energy saver mode). The other conditions are the same as for the energy saver mode.
2.12.4 AUTO OFF MODE Auto off mode is used only if no optional printer/scanner unit is installed. Entering auto off mode The machine enters auto off mode when one of the following is done.
2.12.5 NIGHT MODE This is used instead of auto off mode when an optional scanner/printer unit is installed. There are two types of night mode: Night Stand-by Mode and Night Mode. The difference between night stand-by mode and night mode is the machine’s condition when the machine enters auto off mode. Entering night stand-by and night modes The machine enters the night stand-by mode and night modes when one of the following is done.
SECTION 3 SERVICE TABLES
3. SERVICE TABLES 3.1 SERVICE PROGRAM MODE OPERATION The service program (SP) mode is used to check electrical data, change modes, and adjust values. CAUTION Never turn off the main power switch when the power LED is lit or flashing. To avoid damaging the hard disk or memory, press the operation power switch to switch the power off, wait for the power LED to go off, and then switch the main power switch off. To Enter and Exit the SP Mode 1. Press Clear Modes key J. 2.
Using the SP Mode SP command numbers can be entered directly (if you know the entire number) or the command can be selected from the menus. Direct Entry If you know all seven digits of the SP code, enter the seven numbers and press Enter key . However, if you do not know all the numbers, enter only the first four numbers of the seven-digit SP and press Enter key . The display goes immediately to the first SP of that group. Then you can use the buttons to browse to the desired selection.
SP Mode Button Summary Here is a short summary of the touch-panel buttons. (1) (2) (3) (4) (5) 14APR 2002 03:25 SP Mode (Service) Open All Close All Copy Window SP1XXX Group SP2XXX Page X-XXX-XXX SP Direct Exit COPY: SP1-001-001 SP3XXX Line SP4XXX SP5XXX SP6XXX (6) (7) (8) (9) 21 Line Page Initial SP7XXX SP8XXX Group 0 (10) Prev Page Next Page B064S500.WMF Open All. Opens all SP groups and sublevels. Close All.
3.2 SERVICE PROGRAM MODE TABLES NOTE: The Service Program Mode is for use only by customer engineers so that they can properly maintain product quality. If this mode is used by anyone other than a customer engineer for any reason, data might be deleted or settings might be changed. In such a case image quality can no longer be guaranteed. Service Table Key Notation [range / default / step] Italics * DFU Japan only SEF LEF What it means [–9~+9 / +3.0 / 0.1 mm] The default setting +3.0 can be adjusted in 0.
3.3 USER PROGRAM MODE 3.3.1 ENTERING AND EXITING USER PROGRAM MODE The user program (UP) mode is accessed by users, and by sales and service staff. UP mode is used to input the copier’s default settings. Press the User Tools/Counter button (Item20), then select the UP mode program. After finishing the UP mode program, touch “Exit” key to exit UP mode.
1. Press the user tools key, then press the key corresponding to the set of user tools you wish to use. 2. System Settings: a) Print Priority: If set to Interleave, the machine may start printing pages from another job after the number of pages selected with ‘Interleave Print’. b) Interleave Print: See above c) Function Reset Timer: Also controlled by SP 5913. This is the length of time the machine waits before changing modes when using the multi-access function. The default is 3 seconds.
SECTION 4 INSTALLATION
4. INSTALLATION 4.1 INSTALLATION REQUIREMENTS 4.1.1 ENVIRONMENT 1. Temperature Range: 10°C to 32°C (50°F to 89.6°F) 2. Humidity Range: 15% to 80% RH %Rh 90 80 70 60 50 40 30 20 10 27°C (80.6°F) 80% 32°C (89.6°F) 54% Operation Range 32°C (89.6°F) 15% 10 20 10°C (50°F) 15% 30 Temperature B070I900.WMF 3. Ambient Illumination: Less than 1,500 lux (do not expose to direct sunlight or strong light) 4. Ventilation: Room air should turn over at least 3 times per hour 5. Ambient Dust: Less than 0.
9. Place the copier on a strong and level base. 10. Do not place the machine where it may be subjected to strong vibrations. 11. Do not connect the machine to a power source shared with another electrical appliance. 12. The machine can generate an electrical field which could interfere with radio or television reception. 4.1.2 MACHINE LEVEL 1. Front to back: Within 5 mm (0.2") of level 2. Right to left: Within 5 mm (0.
4.1.3 MINIMUM SPACE REQUIREMENTS Place the copier near the power source, providing clearance as shown below. The same amount of clearance is necessary when optional equipment is installed. Copier + Finisher + LCT + By-pass Tray 200 mm (8") 400 mm (16") 30 mm (2") 555 mm (22") B070I410.WMF Copier + Finisher 200 mm (8") 30 mm (2") 400 mm (16") 555 mm (22") B070I023.WMF NOTE: The controller box door on the back of the machine swings open and can be removed.
4.1.4 DIMENSIONS Side View 1476 mm (58") 980 mm (39") 1097 mm (43.2") Unit: mm/inch 898 mm (36") 806 mm (32") 1202 mm (48") 90 mm (3.5") 180 mm (7") 540 mm (22") B070I411.WMF Top View 858.5 mm (34") 730 mm (29") B070I412.
4.1.5 POWER REQUIREMENTS CAUTION 1. Make sure that the wall outlet is near the main machine and easily accessible. Make sure the plug is firmly inserted in the outlet. 2. Avoid multi-wiring. 3. Be sure to ground the machine. 4. Never set anything on the power cord. Input voltage level: North America: 208 to 240 V, 60 Hz: More than 20 A Europe/Asia: 220 ~240 V, 50/60 Hz: More than 16 A NEMA 6-20R Note: For USA installations, standard 220V (+/-10%) wall voltage is acceptable.
4.2 COPIER (B070/B071) 4.2.1 ACCESSORIES 1 12 13 14 2 6 7 15 16 3 8 4 9 5 10 17 11 18 19 20 B070I001.
Check the quantity and condition of the accessories in the box against the following list: Description Q'ty 1. Operation Panel..................................................................... 1 2. Lower Cover - Operation Unit Holder..................................... 1 3. Upper Cover - Operation Unit Holder..................................... 1 4. Operating Instruction Holder .................................................. 1 5. Right Arm Cover ....................................................
SECTION 5 LARGE CAPACITY TRAY
5. OVERALL MACHINE INFORMATION 5.1 SPECIFICATIONS Paper Weight Paper Size Tray Capacity: Tab Sheet: Paper Feed System: Remaining Paper Detection: Power Source: Power Consumption: Weight: Size (W x D x H): PTM 52 to 216 g/m2 52 to 216 g/m2 A4 LEF, B5 LEF, 81/2"x11" LEF, A5, Tray 4,5,6 51/2"x81/2" Tray 4, 5 1,000 sheets (Thick Paper 0.11 mm) Tray 6 2,550 sheets (Thick Paper 0.11 mm) Feed possible from Tray 4 or Tray 5. Requires installation of tab sheet fence.
5.2 OVERALL MECHANICAL INFORMATION 5.2.1 MECHANICAL COMPONENT LAYOUT 14 15 1 2 13 3 4 12 11 5 10 9 8 6 7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. Paper Feed Sensor Paper End Sensor Separation Solenoid Paper Tray Paper Height Sensors Tray Drive Belt Pick-up Roller Separation Roller B070/B071 B511V101.
5.3 ELECTRICAL COMPONENT DESCRIPTIONS Symbol Clutches MC1 MC2 MC3 MC4 MC5 MC6 MC7 Motors M1 M2 M3 M4 PCB Name Function Transport 1st Paper Feed 1st Grip 2nd Paper Feed 2nd Grip 3rd Paper Feed 3rd Grip Drives the transport rollers in the LCT. Drives the paper feed roller in the 1st tray. Drives the grip roller in the 1st tray. Drives the paper feed roller in the 2nd tray. Drives the grip roller in the 2nd tray. Drives the paper feed roller in the 3rd tray.
Symbol Name SN21 3rd Paper End SN22 3rd Lift Function Informs the copier when the paper in the 3rd tray has run out. Detects when the paper in the 3rd tray is at the correct paper feed height. Solenoid s SOL1 1st Separation SOL2 2nd Separation SOL3 3rd Separation SOL4 1st Pick-up SOL5 2nd Pick-up SOL6 3rd Pick-up Controls up-down movement of the separation roller in the 1st tray. Controls up-down movement of the separation roller in the 2nd tray.
5.4 DRIVE LAYOUT 11 12 13 14 1 2 10 3 9 2 8 4 7 5 6 B511V102.WMF 1. 2. 3. 4. 5. 6. 7. PTM 8. 9. 10. 11. 12. 13. 14.
5.5 DETAILED DESCRIPTIONS 5.5.1 PAPER FEED [A] [D] [C] [B] B511D113.WMF This LCT has three paper tray feed stations. The upper and middle trays can each hold 1,000 sheets of paper. The lower tray can hold 2,550 sheets of paper. All feed stations use an FRR paper feed system (paper feed roller [A], separation roller [B], pick-up roller [C]), and those rollers are driven by the LCT motor via the paper feed clutch [D].
5.5.2 PICK-UP AND FEED Overview [H] [F] [A] [G] [B] [D] [E] [C] B511D105.WMF Drive from the LCT motor is transmitted to the gear [A] in the paper feed unit via the timing belt [B]. Then the gear [A] transmits the drive to the pick-up [C], paper feed [D], and separation [E] rollers via gears and the paper feed clutch [F]. The gear [A] also transmits the drive to the grip roller [G] via gears and the grip roller clutch [H].
5.5.3 PICK-UP AND FEED [D] [I] [C] [G] [H] [A] [E] [B] [F] B511D105.WMF When a paper feed station is not selected, its separation roller solenoid [A] is deactivated and the separation roller [B] can turn freely. When the paper feed station is selected and the Start key is pressed, the feed clutch [C], separation roller solenoid [A], and pick-up solenoid [D] turn on.
5.5.4 SEPARATION ROLLER RELEASE [B] [C] [A] B511D104.WMF The separation roller [A] is normally away from the feed roller [B]. When the paper feed station is selected, the separation roller solenoid [C] contacts the separation roller with the feed roller as explained on the previous two pages. This contact/release mechanism has the following three advantages: 1. When the LCT motor turns on, all the separation rollers in the three feed stations rotate.
5.6 PAPER LIFT 5.6.1 TRAY DETECTION When a tray is set in the machine, the tray detection method used depends on the tray: • The upper tray and middle tray are detected when any one of the paper size switch signals is low. • The lower tray is detected when the switch 1 signal of the paper size switch is low. [F] [E] [E] [H] [J] [C] [D] [G] [I] [A] [B] B511D106.WMF B511D109.WMF 5.6.
5.6.3 LIFT SENSOR [A] [E] [D] [C] [B] B511D108.WMF When the lift motor turns on, the pick-up solenoid [A] activates to lower the pick-up roller [B]. When the top sheet of paper reaches the proper paper feed level, the paper pushes up the pick-up roller and the actuator [C] on the pick-up roller supporter [D] de-activates the lift sensor [E] to stop the lift motor.
5.7 PAPER SIZE DETECTION [A] [B] 1 2 3 B511D111.WMF SW1 SW2 SW3 A4-LEF B5-LEF A5-LEF A5-SEF LT-LEF 0 1 1 1 0 1 0 1 0 0 0 1 0 0 0 HLTLEF 1 0 0 1: HI HTLSEF 1 1 0 0: LOW Top Tray (Tray 1) and Middle Tray (Tray 2) For the top and middle trays, the paper size switch [A] detects the paper size. The paper size switch contains three microswitches. The paper size switch is actuated by an actuator plate [B] at the rear of the tray.
5.8 REMAINING PAPER DETECTION [E] [A] [D] [C] [B] B511D109.WMF The amount of paper remaining in the tray is detected by the three paper height photointerrupter sensors on the left rail as the bottom plate rises. Five states, determined by the position of the actuator are possible. 1. With the actuator [A] below paper height sensor 1 [B], no sensor is actuated and the display indicates 100%. 2. When the actuator passes paper height sensor 1 [B] , the display indicates 75% of the paper supply remaining.
5.9 PAPER END DETECTION [A] [B] B511D110.WMF The paper end sensor [A] detects the top sheet of the paper in the tray by monitoring the reflected light. When the paper tray runs out of paper, the paper end sensor does not receive the reflected light due to the cutout [B]. Then, the tray lift motor rotates backwards 2 seconds to drop the tray bottom plate.
SECTION 6 SR860 BOOKLET FINISHER
6. OVERALL MACHINE INFORMATION 6.1 SR860 3000 SHEET BOOKLET FINISHER (B468) NOTE: The 3000 Sheet Booklet Finisher B468 is used with the B070 (90 ppm) Upper Tray Tray Capacity (80 g/m2) Unstapled Stapled Stapled (Mixed Sizes) Paper Size Paper Weight 500 sheets (A4, A5 LEF, B5, 81/2"x11") 250 sheets (A3 SEF, B4 SEF, 11"x17" SEF, 81/2"x11", 12"x18" 100 sheets (A5 SEF, A6 SEF, B6 SEF, 51/2"x81/2") Max docs. Total sheets Size 50 docs. 500 sheets A4 LEF, 81/2"x11" LEF A3, A4 SEF, B4, B5, 12"x18", 25 docs.
Staple Specifications Binding Capacity (80 g/m2) Paper Size Paper Weight Stapling Position Stapling Capacity 50 sheets (A4, 81/2" x 11" or smaller) 30 sheets (B4, 81/2" x 14" or larger) Mixed 30 sheets (A3 and A4 LEF, B4 and B5 LEF, Sizes 11" x 17"and 81/2" x 11" LEF A3 to B5, 11" x 17" to 81/2" x 11" 64 g/m2 to 90 g/m2 Front (1), Back (1), Back (1: diagonal), 2 positions 5,000 staples/cartridge Same Size Booklet Staple Specifications Binding Capacity (80 g/m2) Paper Size Paper Weight Stapling Position S
6.2 PUNCH UNIT (B377) The Punch Unit B377 is installed in the 3000 Sheet Booklet Finisher B468 connected to the B070 (90 ppm).
6.3 OVERALL MECHANICAL INFORMATION 6.3.1 MECHANICAL COMPNENT LAYOUT 1 2 3 4 5 15 6 14 7 13 8 12 11 9 10 B468D001.WMF 1. Proof Tray 9. Stapler Unit 2. Guide Plate Motor 10. Pressure Plate Unit 3. Guide Plate 11. Saddle Stitch Stapler 4. Shift Roller 12. Folder Plate 5. Tray Junction Gate 13. Lower Tray 6. Punch Unit 14. Folder Rollers 7. Stapler Junction Gate 15. Upper Tray 8.
6.4 DRIVE LAYOUT 1 2 3 4 12 11 10 9 8 7 5 6 B468D006.WMFF PTM 1. Proof Tray Motor 7. Pre-Stack Motor 2. Lower Tray Lift Motor 8. Exit Motor 3. Lower Tray Encoder Disk 9. Entrance Motor 4. Upper Tray Lift Motor 10. Shift Roller Motor 5. Pressure Plate Motor 11. Shift Drive Motor 6. Stapler Transport Motor 12.
2 1 3 4 5 6 7 8 B468D007.WMF 1. Stack Feed Out Belt 5. Jogger Fence Motor 2. Folder Roller Motor 6. Jogger Fences 3. Folder Plate Motor 7. Stapler Movement Motor 4. Feed Out Belt Motor 8.
6.5 DETAILED DESCRIPTIONS 6.5.1 TRAY/STAPLER JUNCTION GATES Proof (Upper Tray) Sort/Stack Staple [D] [B] [A] [C] B468D010.WMF B468D009.WMF B468D008.WMF The finishing mode selected for the job determines the direction of the paper in the finisher. • Proof Tray (Top of the unit): Paper is sent to the top tray. • Shift: Paper is sent straight to the upper or lower tray. • Staple:.
6.5.2 PRE-STACKING [B] [E] [C] [F] [A] [D] B468D011.WMF During a multiple copy job selected for stapling, the pre-stacking mechanism delays the first two sheets of every set (after the first set) to allow enough time to staple the preceding stack on the stapler tray. Pre-stacking is performed with the first and second sheets for the second and all subsequent sets.
6.5.3 VERTICAL LIFT MECHANISM Overview [A] [B] B468D101.WMF At power on, both trays lower slightly, then the upper tray stops at the feed-out position. The machine is ready for feed out to the upper tray [A] During printing, the upper [A] or lower tray [B] (whichever is selected) is repeatedly lowered until the stack reaches a certain height and then the job halts. The upper tray holds 500 sheets (A4 LEF), and the lower tray holds 2500 sheets.
6.5.4 UPPER TRAY [B] [A] [E] [F] [C] [G] [D] B468D102.WMF [A]: [B]: [C]: [D]: [E]: [F]: Upper tray lift motor Upper tray paper height sensor Upper tray lift solenoid Upper tray full sensor Upper tray paper sensor Upper limit switch (upper tray) Just After the Power is Switched on At power on, the motor [A] moves the upper tray to the start position just under the feed-out slot. The motor stops when the paper height sensor [B] detects the tray.
6.5.5 LOWER TRAY [B] [D] [E] [A] [F] [C] B468D104.WMF B468D103.WMF [A]: [B]: [C]: [D]: [E]: [F]: Upper tray lift motor Upper tray upper limit sensor Upper limit switch (upper tray) Lower tray lift motor Lower tray paper height sensor 1 Lower tray paper height sensor 2 Just After the Power is Switched on At power on, the upper tray moves to the start position under the feed-out slot, as described previously.
Lower Tray Full [C] [D] [B] [F] [A] [E] [A]: [B]: [C]: [D]: [E]: [F]: B468D104.WMF Lower tray full sensor (sort/shift mode) Lower tray lift motor Lower tray encoder sensor Encoder disk Lower tray full sensor (saddle-stitch mode) Lower tray paper sensor The sensor that is used depends on which mode the user has selected. Normal sorting/stapling, without saddle stitching: When the bottom of the tray actuates sensor [A], the lift motor [B] continues to rotate for a certain number of rotations.
6.5.6 SHIFT MECHANISM [C] [A] [B] [K] [D] [J] [G] [E] [H] [I] [F] B468D105.WMF The same shift mechanism is used for the upper tray and lower tray. Shift Roller Rotation The shift roller [A] is turned by the shift roller motor [B]. Shift Roller Horizontal Movement The shift roller is moved from left to right by the shift motor [C] and shift gear disk [D].
6.5.7 PAPER POSITIONING [C] [F] [G] [D] [E] [B] B468D014.WMF [C] [A] Vertical Alignment When the trailing edge of the copy passes the stapler tray entrance sensor [A], the positioning roller solenoid [B] switches on long enough for the selected paper size and pushes the positioning roller [C] onto the paper. The positioning roller and alignment brush roller [D] rotate to push the paper and align the trailing edge of the paper with the stack stopper [E].
6.5.8 STAPLER Stapling Mechanism [B] [C] [A] B468D015.WMF [D] [E] B468D106.WMF Staple firing is driven by the stapler motor [A] inside the stapler unit. The stapler hammer [B] fires the stapler [C]. The cartridge set sensor [D] detects the cartridge at the correct position, or logs an SC if the stapler unit is not at the correct position. The stapler end sensor [E] detects the staple end condition and logs an SC.
6.5.9 STAPLER MOVEMENT The stapler performs horizontal and rotational movement in each of the four staple modes. Horizontal Stapler Movement [D] [A] [B] [C] B468D016.WMF The stapler movement motor [A] drives the timing belt [B] which moves stapler [C] left and right on a support bar [D]. When the Start key is pressed, the jogger fences move to the wait position 10 mm wider than the selected paper size, the stapler motor switches on and moves the stapler to the staple position and then switches off.
Rotational Stapler Movement [F] [E] [D] [C] [A] [B] B468D017.WMF When the user has selected oblique stapling at one position, first the stapler motor switches on and off for the amount of time needed to move the stapler to the stapling position for the selected paper size. At the correct time, the stapler rotation motor [A] switches on and via the timing belt [B] rotates the worm gear [C].
6.5.10 FEED OUT [D] [I] [C] [A] [B] [H] [G] B468D018.WMF [E] [F] B468D019.WMF After a set has been stapled, the stack feed out motor [A] switches on and drives the stack feed out belt [B]. The pawl [C] on the belt lifts the stapled stack and transports it to the exit rollers [D]. There are two pawls on the belt, to increase productivity.
6.5.11 BOOKLET FINISHING OVERVIEW Stapling: Two booklet staplers are used. These are about half way up the stack fed-out path The stack feed-out belt moves the stack to the correct position for stapling. Folding: This is done in two phases: initial folding and final folding. • Initial folding: At the top of the stack feed-out belt, a plate pushes the centre of the copy (at the stapled place) through a pair of rollers to give the booklet an initial fold. However, this fold is only a partial fold.
6.5.13 INITIAL FOLDING [B] [A] [C] B468D021.WMF [F] [D] [H] [E] [G] B468D022.WMF The folder plate motor [A] switches on and drives the folder plate [B] forward to push the center of the booklet into the nip of the folder rollers [C], giving the booklet a partial fold. This is a detailed cross-section of the operation described above. The timing of the sequence depends on the size of the paper selected for the job.
6.5.14 FINAL FOLDING AND FEED-OUT [J] [C] [D] [G] [H] [F] [I] [E] [A] [B] B468D023.WMF When the finisher is ready to feed out the first stapled booklet, the lower tray [A] descends past the pressure plate slot [J], the spring-loaded arms inside the lower tray snap into the grooves on the side fence, and the springs push the arms against the bottom of the support wing [B] to raise it.
6.6 PUNCH UNIT B377 (OPTION) The punch unit punches holes in printed sheets, one by one. The punch unit is provided with a new punch mechanism to improve the accuracy of punching. NOTE: The illustrations below show the unit for Europe for 2/4 hole punching. The North American unit has five holes for 2/3 hole punching. 6.6.1 PUNCH DRIVE MECHANISM [A] [F] [E] [D] [C] [B] B377D505.WMF The punch motor [A] drives the punch mechanism.
[C] [B] [D] [A] B377D504.WMF When the finisher has received the command that changes the number of punch holes for the job, the punch hole motor [A] turns on until the actuator disk changes the status of the punch hole switch [B] (until it switches on or off). This indicates that the cover [C] and the punch cam [D] have moved to one side or the other to determine which punchers are used.
6.6.2 PUNCH WASTE COLLECTION [A] [B] [C] B377D506.WMF Waste punchouts are collected in the punch waste hopper [A] below the punch unit inside the finisher. When the top of the punchout waste in the hopper reaches and actuates the hopper sensor [B], a message will be displayed on the operation panel after the current job is completed. This sensor also detects whether the punch waste hopper is installed.
SECTION 7 3,000-SHEET FINISHER MJ-1026
7. SR840 3000 SHEET FINISHER (B478) 7.
7.1.1 SPECIFICATION PUNCH UNIT (B531) The Punch Unit B531 is installed in the 3000 Sheet Finisher .
7.1.2 SPECIFICATION PUNCH UNIT (A812) The Punch Unit A812 is installed in the 3000 Sheet Finisher B478.
7.1.3 SPECIFICATION JOGGER UNIT B513 The Jogger Unit B513 is installed above the shift tray of the 3000 Sheet Finisher B478. Paper Size Paper Weight Weight Dimensions (W x D x H) Power Supply Power Consumption B070/B071 A3 SEF, B4 SEF, 11" x 17" SEF A4 LEF, B5 LEF, 81/2" x 11" LEF 52 g/m2 ~ 216 g/m2 Less than 1.7 kg (3.7 lb.) 125 mm x 450 mm x 100 mm 5" x 17.
7.2 MECHANICAL COMPONENT LAYOUT 1 2 3 4 5 6 21 7 8 20 9 19 18 10 17 11 16 15 12 13 14 B478V500.WMF 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. PTM 12. 13. 14. 15. 16. 17. 18. 19. 20. 21.
7.3 ELECTRICAL COMPONENT DESCRIPTION Symbol Motors Name M01 M02 M03 Shift Tray Exit Shift Tray Lift Exit Guide M04 Lower Transport M05 M06 M07 M08 M09 M10 M11 M12 M13 M14 M15 M16 Shift Positioning Roller Stacking Roller Drag Stacking Roller Jogger Stack Feed-Out Belt Stack Plate - Center Stapler Stack Plate – Front Stack Plate – Rear Stapler Rotation Staple Hammer M17 Punch M18 Upper Transport M19 Shift Jogger M20 Shift Jogger Lift Function Drives the exit roller for the shift tray.
Symbol S07 Staple Mode HP 2 S10 S11 S12 S13 Shift Lower Limit – Large Paper Shift Tray Lower Limit 2 Shift Tray Lower Limit 3 Shift Mode HP Stacking Roller HP S14 Shift Tray Half-Turn S15 Pre-Stack Tray Paper S16 S17 S18 S19 S20 S21 S22 S23 Stapler Tray Exit Positioning Roller HP Stack Feed-Out Belt HP Stapler Tray Paper Jogger HP Stack Plate - Center HP Stack Plate – Front Stack Plate – Rear S24 Stapler HP S25 Stapler Rotation HP S26 S27 Stapler Return Staple Waste Hopper S28 Punch Waste H
Symbol Name SOLENOIDS (Upper) Tray Junction SOL1 Gate SOL2 Stapler Junction Gate SOL3 Pre-Stack Junction Gate SOL4 Pre-stack Paper Stopper SOL5 Stapler Return Function Drives the tray junction gate. Drives the stapler junction gate. Drives the pre-stack junction gate. Drives the stopper pawl of the pre-stacking tray. Positions the stapler correctly on its return from the staple supply point.
7.4 DRIVE LAYOUT 1 2 3 4 5 19 18 17 16 15 14 13 12 6 7 20 21 11 22 23 10 B478V503.WMF 9 8 26 24 25 B478V504.WMF 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. PTM 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26.
7.5 DETAILED DESCRIPTIONS 7.5.1 TRAY AND STAPLER JUNCTION GATE Upper Tray Mode [A] [D] [C] [B] B478D506.WMF Sort/Stack Mode Staple Mode [A] [A] [D] [D] [C] [C] [B] [B] B478D505.WMF B478D507.WMF Depending on the finishing mode, the copies are directed up, straight through, or down by the combinations of open and closed junction gates.
7.5.2 PAPER PRE-STACKING [A] [E] [B] [F] [C] [D] B478D000.WMF This mechanism improves productivity in staple mode. It is only used when copying on A4, LT, or B5 (all LEF). During stapling, the copier has to wait. This mechanism reduces the wait by holding the first two sheets of a job while the previous job is still being stapled. It only works during the second and subsequent sets of a multi-set copy job.
7.5.3 JOGGER UNIT PAPER POSITIONING [C] [G] [A] [F] [E] [B] [D] [L] [M] [I] [K] B478D508.WMF [J] In the staple mode, as every sheet of paper arrives in the jogger unit, it is vertically and horizontally aligned, then the staple edge is pressed flat to ensure the edge of the stack is aligned correctly for stapling.
7.5.4 STAPLER UNIT MOVEMENT [A] [B] [C] B478D513.WMF Side-to-Side The stapler motor [A] moves the stapler [B] from side to side. After the start key is pressed, the stapler moves from its home position to the stapling position. If two-staple-position mode is selected, for the first stack the stapler moves to the rear stapling position first, staples, moves to the front position, staples and waits at the front.
[A] [B] [F] [D] B478D514.WMF [E] B478D523.WMF B478D515.WMF [C] Rotation (1) In the oblique staple position mode, the stapler rotation motor [A] rotates the stapler units [B] 45° to counterclockwise after it moves to the stapling position. Rotation (2) When the staple end condition arises, the stapler motor moves the stapler to the front and the stapler rotation motor rotates the stapler unit to clockwise to remove the staple cartridge [C]. This allows the user to add new staples.
7.5.5 STAPLER [C] [E] [A] [D] [A] B478D516.WMF B478D521.WMF [E] [F] B478D522.WMF [G] When the aligned copies are brought to the stapling position by the positioning roller and jogger fences, the staple hammer motor [A] starts stapling. During stapling, the stapler trims off the excess length [B] of the staples by lowering the cutter [C]. This excess length depends on the number of copies in the set; there will be very little for a stack containing 100 sheets.
[C] [D] [A] [B] [E] B478D518.WMF [F] B478D517.WMF The stapler has a staple end sensor [A], cartridge set sensor [B] and staple hammer HP sensor [C]. When a staple end or no cartridge condition is detected, a message is displayed advising the operator to install a staple cartridge. If this condition is detected during a copy job, the indication will appear, and the copy job will stop. The staple cartridge has a clinch area [D] where jammed staples collect.
7.5.6 FEED-OUT [G] [D] [A] [B] [C] [I] [H] [E] B478D519.WMF [F] B478D512.WMF After the copies have been stapled, the stack feed-out motor [A] starts. The pawl [B] on the stack feed-out belt [C] transports the set of stapled copies up and feeds it to the shift tray exit roller [D]. When stapling starts, the exit guide motor [E] opens the upper exit guide [F], which includes the upper shift tray exit roller [G], in order to feed out the leading edge of the copy set smoothly.
7.5.7 PAPER EXIT STACKING [A] [B] [E] [C] [F] [D] [H] [G] [I] B478D524.WMF The stacking roller assembly [A] is fastened to a plate [B] on a shaft by a spring [C]. The cam [D], in contact with the bottom of the plate, is connected to the stacking roller drag motor [E] via a timing belt. The stacking roller drag motor and timing belt rotate the cam against the bottom of the plate to move the rollers forward and back with each sheet ejected onto the shift tray.
7.5.8 SHIFT TRAY Overview [E] [D] [F] [G] [A] [B] [C] B478D010.WMF The shift tray lift motor [A] controls the vertical position of the shift tray [B] through gears and timing belts [C]. Stand-by Mode After the main switch is turned on, or when the stack is removed from the tray, the end of the feeler on the tray falls and its actuator [D] rotates up into staple mode HP sensor 2 [E] (S7) and switches it on.
7.5.9 SHIFT TRAY UP/DOWN MOVEMENT [D] [B] [C] [H] [A] [G] [F] [E] B478D010.WMF Sort/Stack Mode (Shift Mode) The shift tray moves to home position, which is when the actuator [F] has just exited the shift mode home position sensor [G] (S12). During feed-out, the tray is lowered automatically at prescribed intervals; sensor [D] (S7) is ignored.
7.5.10 SHIFT TRAY LOWER LIMIT DETECTION [A] [B] [C] B478D010.WMF This machine has two shift tray lower limit sensors: shift lower limit sensor [A] (S9) for large paper (B4 and larger) and shift lower limit sensor [B] (S11) for small paper (smaller than B4). NOTE: Sensor [C] (S10) is not used. When the actuator [D] enters sensor [A] while using large paper (about 1500 sheets are on the tray), a message will be displayed and copying will stop.
7.5.11 SHIFT TRAY SIDE-TO-SIDE MOVEMENT [D] [A] [F] [C] [B] [E] B478D520.WMF In sort/stack mode, the shift tray [A] moves from side to side to separate the sets of copies. The horizontal position of the shift tray is controlled by the shift motor [B] and shift gear disk [C]. After one set of copies is made and delivered to the shift tray, the shift motor turns on, driving the shift gear disk and the shaft [D]. The end fence [E] is positioned by the shaft, creating the side-to-side movement.
7.6 JAM CONDITIONS 1. The entrance sensor does not turn on when the copier has fed paper 426 mm after the copier exit sensor turned off. 2. The entrance sensor does not turn off when the upper transport motor has fed paper 1.5 times the paper’s length after it turned on. 3. The upper tray exit sensor does not turn on when the upper transport motor has fed paper 574 mm after the entrance sensor turned on. 4. The upper tray exit sensor does not turn off when the upper transport motor has fed paper 1.
7.7 PUNCH UNIT B531 (OPTION) 7.7.1 PUNCH UNIT DRIVE [C] [A] [B] [D] [E] B531D102.WMF The punch unit makes 2 or 3 holes at the trailing edge of the paper. The number of holes depends on a selection made on the operation panel. The cam [A] has 2 punches on one side and 3 punches on the other, and is turned by the punch motor [B]. The punch motor turns on immediately after the trailing edge of the paper passes the entrance sensor. The punches on the cam rotate downward and punch holes in the paper.
7.7.2 PUNCH WASTE COLLECTION [A] [B] [C] B531D103.WMF Punch waste is collected in the punch waste hopper [A] positioned under the punch unit. When the level of the punch waste in the hopper rises as far as the hole [B] in the hopper, the punch waste sensor [C] turns on, stops the job, and triggers a message on the operation to indicate that the hopper is full and must be removed and emptied. The job resumes automatically after the hopper is emptied and returned to the finisher.
7.8 JOGGER UNIT B513 (OPTION) 7.8.1 JOGGER UNIT MECHANICAL LAYOUT 2 1 3 4 7 6 5 B513D003.WMF 1. 2. 3. 4. 5. 6. 7.
7.8.2 JOGGER UNIT DRIVE [C] [F] [B] [A] [D] [G] [H] [J] [I] [E] B513D002.WMF At prescribed intervals, the jogger motor [A] switches on and drives the jogger timing belt [B], gear [C] and jogger fence timing belt [D] which drives the shift jogger fences [E] against the sides of the stack to align its edges.
SECTION 8 COVER INTERPOSER TRAY MJ-7002
8. COVER INTERPOSER TRAY TYPE 1075 (B470) 8.1 SPECIFICATION Paper Separation Paper Sizes Paper Weight Capacity Power Supply (from main machine) Power Consumption Dimensions (W x D x H) Weight PTM FRR System with Feed Belt A3 ~ A5, 11" x 17" ~ 51/2" x 81/2" 64 ~ 216 g/m2 200 sheets (80 g/m2) 24 V ±10%, 5 V ±5% (From Finisher) Less than 48 W 500 x 620 x 200 mm 19.7" x 24.4" x 7.9" Less than 12 kg (26.4 lb.
8.2 OVERALL MACHINE INFORMATION 8.2.1 MAIN LAYOUT 1 2 3 5 4 6 B470D001.WMF 1. Support tray 2. Slip sheet tray 3. Pick-up roller 4. Feed belt 5. Separation roller 6.
8.2.2 DRIVE LAYOUT 2 3 1 4 5 6 7 B470D003.WMF 1. Pick-up Roller 2. Feed Belt 3. Bottom Plate Lift Motor 4. Feed Motor 5. Transport Motor 6. Timing Belt 7.
8.3 DETAILED DESCRIPTIONS 8.3.1 PAPER PATH 1 2 3 4 5 6 B470D006.WMF 1. Pick-up Roller 2. Feed Belt 3. Separation Roller 4. Grip Roller 5. Transport Roller 1 6. Transport Roller 2 The paper feeds from the tray, to the feed belt, then to the grip roller and down into the paper path to the finisher below.
8.3.2 PAPER FEED [B] [C] [H] [G] [A] [E] [D] [F] B470D005.WMF Power On When paper is placed on the tray, the paper set sensor [A] in the tray actuates and switches on the bottom plate lift motor [B]. The top of the stack raises the pick-up roller unit until the actuator on this unit actuates the pick-up roller position sensor [C] and switches the motor off. Paper Separation and Feed The pick-up roller [D] picks up the original, and the feed belt [E] feeds the sheet to the grip roller.
8.3.3 PAPER SIZE DETECTION The width sensors [A] (S1, S2, S3) and length sensors [B] (S4, S5, S6) detect the width and length of the paper on the interposer feed tray. DLT SEF A3 SEF 8 K SEF B4 SEF LG 10"x14" F4 S6 A4 SEF S5 LT SEF US EXE SEF 16 K SEF B5 SEF 8"x10" S4 HLT SEF A5 SEF LT LEF 16 K LEF B5 LEF US EXE LEF A5 LEF HLT LEF P5 P4 P3 P2 S3 P1 S2 S1 B470D901.
The table below lists the sensor output for each paper size. A3 B4 A4 SEF A4 LEF B5 SEF B5 LEF A5 SEF A5 LEF 11" x 17" 10" x 14" SEF 81/2" x 14" 81/2" x 13" 81/2" x 11" 11" x 81/2" 8" x 10" 51/2" x 81/2" 81/2" x 51/2" 71/2" x 101/2" (US Exec.) 101/2" x 71/2" (US Exec.
B064/B065: Correct Paper Size Display North America Execute SP5959 006 and enter the correct number for the size of the paper loaded for feeding from the cover interposer tray. Loaded Display (Default) 81/2" x 13" 101/2" x 71/2" 8" x 10" 81/2" x 14" 81/2" x 11" 81/2" x 11" To Select for Display 81/2" x 13" 101/2" x 71/2" 8" x 10" Enter 165 173 171 Europe/Asia Execute SP5959 006 and enter the correct number for the size of the paper loaded for feeding from the cover interposer tray.
SECTION 9 MULTI BYPASS TRAY MY-1024
9. MULTI BYPASS TRAY TYPE 2105 (B512) 9.1 SPECIFICATION NOTE: The Bypass Tray is attached to the top of the LCT B511. Paper Feed System Tray Capacity Remaining Paper Detection Paper Size Tab Sheets Paper Weight Weight Power Source Power Consumption Dimensions (W x D x H) PTM FRR 500 sheets (Thick Paper 0.11 mm) 4-Step: Including Near-End A5 to A3, 51/2" x 81/2" to 12" x 18" A4 LEF, 81/2" x 11" LEF (requires attachment of tab fence) 52 to 216 g/m2 Less than 18 kg (39.6 lb.
9.2 OVERALL MACHINE INFORMATION 9.2.1 MECHANICAL COMPONENT LAYOUT 3 4 5 6 7 8 9 2 1 B512D001.WMF 12 11 10 1. Transport Roller 2 2. Transport Roller 1 3. Grip Roller 4. Paper Feed Sensor 5. Lift Sensor 6. Feed Roller 7. Pick-up Roller 8. Paper Height Sensor 1 9. Paper Height Sensor 2 10. Lift Plate Actuator 11. Lift Plate 12.
9.3 ELECTRICAL COMPONENT LAYOUT 3 4 5 6 7 8 2 1 9 10 11 12 14 15 13 B512D002.WMF 1. Paper Feed Sensor 2. Paper End Sensor 3. Lift Sensor 4. Pick-up Solenoid 5. Transport Clutch 6. Grip Clutch 7. Feed Clutch 8. Tray Motor 9. Paper Height Sensor 1 10. Paper Height Sensor 2 11. Lift Motor 12. Paper Length Sensor 13. Paper Width Switch 14. Lower Limit Sensor 15.
9.3.1 ELECTRICAL COMPONENT DESCRIPTIONS Symbol Clutches MC8 MC9 MC10 Motors M5 M6 Sensors Name Transport Paper Feed Grip Drives the transport rollers in the bypass tray. Drives the paper feed roller in the bypass tray. Drives the grip clutch in the bypass tray. Tray Tray Lift Drives all rollers in the bypass tray. Lifts and lowers the tray.
9.4 DRIVE LAYOUT 2 1 3 4 5 6 7 8 12 11 10 9 B512D003.WMF 1. Transport Roller 2 2. Transport Roller 1 3. Grip Roller 4. Grip Clutch 5. Paper Feed Clutch 6. Transport Clutch 7. Tray Motor 8. Lift Motor 9. Lift Plate 10. Pick-up Roller 11. Separation Roller 12.
9.5 DETAILED DESCRIPTIONS 9.5.1 PAPER PATH 1 2 3 4 5 6 B470D006.WMF 1. Pick-up Roller 2. Feed Belt 3. Separation Roller 4. Grip Roller 5. Transport Roller 1 6. Transport Roller 2 The paper feeds from the tray, to the feed belt, then to the grip roller and down into the paper path to the finisher below.
9.5.2 PAPER FEED [B] [C] [H] [G] [A] [E] [D] [F] B470D005.WMF Power On When paper is placed on the tray, the paper set sensor [A] in the tray actuates and switches on the bottom plate lift motor [B]. The top of the stack raises the pick-up roller unit until the actuator on this unit actuates the pick-up roller position sensor [C] and switches the motor off. Paper Separation and Feed The pick-up roller [D] picks up the original, and the feed belt [E] feeds the sheet to the grip roller.
9.5.3 PAPER SIZE DETECTION The width sensors [A] (S1, S2, S3) and length sensors [B] (S4, S5, S6) detect the width and length of the paper on the interposer feed tray. DLT SEF A3 SEF 8 K SEF B4 SEF LG 10"x14" F4 S6 A4 SEF S5 LT SEF US EXE SEF 16 K SEF B5 SEF 8"x10" S4 HLT SEF A5 SEF LT LEF 16 K LEF B5 LEF US EXE LEF A5 LEF HLT LEF P5 P4 P3 P2 S3 P1 S2 S1 B470D901.
The table below lists the sensor output for each paper size. A3 B4 A4 SEF A4 LEF B5 SEF B5 LEF A5 SEF A5 LEF 11" x 17" 10" x 14" SEF 81/2" x 14" 81/2" x 13" 81/2" x 11" 11" x 81/2" 8" x 10" 51/2" x 81/2" 81/2" x 51/2" 71/2" x 101/2" (US Exec.) 101/2" x 71/2" (US Exec.
B064/B065: Correct Paper Size Display North America Execute SP5959 006 and enter the correct number for the size of the paper loaded for feeding from the cover interposer tray. Loaded Display (Default) 81/2" x 13" 101/2" x 71/2" 8" x 10" 81/2" x 14" 81/2" x 11" 81/2" x 11" To Select for Display 81/2" x 13" 101/2" x 71/2" 8" x 10" Enter 165 173 171 Europe/Asia Execute SP5959 006 and enter the correct number for the size of the paper loaded for feeding from the cover interposer tray.