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DANA 4600, Technical Manual

The Toshiba 4600 is a versatile device designed to meet your needs. With its user-friendly interface, advanced features, and high performance, this product is a must-have. Easily access the detailed specifications and user manual for free download at manualshive.com, where we prioritize your satisfaction with the product.

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ARTEKMEDIA => 2012

Summary of Contents for 4600

Page 1: ...RNIA 92715 EPT 1 u TELEPHONE 714 833 1234 TELETYPE 910 595 1136 TELEX 678 341 PUBLICATION DATE MAY 1977 Copyright 1977 by Dana laboratories Inc Printed in the United States of America All rights reserved This book or parts thereof may not be reproduced in any form without written permission of the publishers ...

Page 2: ...can often be done very reasonably in consideration for adding your manual to our library Typically the scans in our manuals are done as follows 1 Typed text pages are typically scanned in black and white at 300 dpi 2 Photo pages are typically scanned in gray scale mode at 600 dpi 3 Schematic diagram pages are typically scanned in black and white at 600 dpi unless the original manual had colored hi...

Page 3: ...ARY NOTICE This document and the technical data herein disclosed are proprietary to Dana Laboratories Inc and shall not without express written permission of Dana Laboratories Inc be used in whole or in part to solicit quotations from a competitive source or used for manufacture by anyone other than Dana Laboratories Inc The information herein has been developed at private expense and may only be ...

Page 4: ...rth connection of the power mains Before operating the unit ensure that the protective con ductor green wire is connected to the ground earth protective conductor of the power outlet Do not defeat the protective feature of the third protective conductor in the power cord by using a two conductor extension cord or a three prong two prong adapter Maintenance and calibration procedures contained in t...

Page 5: ...8 Input Output Controls 2 4 2 9 Operation 24 2 9 2 Autorange 2 4 2 9 3 Manual Range 24 2 9 4 Overrange 24 2 9 5 Signal Input 24 2 9 6 Function Select 24 2 10 Hold Read Probe Option 81 2 5 2 11 BCD Output Option 51 2 5 2 12 Battery Pack Option 70 2 5 3 BCD OUTPUT 3 1 3 1 General 3 1 3 2 Mechanical Description 3 1 3 3 Electrical Description 3 1 3 4 Operation 3 3 3 4 3 Function Codes 3 3 3 4 4 Range ...

Page 6: ...Introduction 5 1 5 2 Calibration Checks 5 1 5 3 Calibration Adjustments 5 5 5 3 5 Calibration Procedure 5 6 5 4 Troubleshooting Performance Tests 5 9 5 4 7 Unit Performance Tests 5 9 5 4 10 Subassembly Performance Tests 5 20 6 DRAWINGS 6 1 7 PARTS LIST 7 1 iv ARTEKMEDIA 2012 ...

Page 7: ... ACV Single Thread Diagram KOhms Single Thread Diagram DCmA Single Thread Diagram ACmA Single Thread Diagram Main PCB Oscillator Clock Test Point Locations Main PCB Reference Voltage Generator Test Point Locations Main PCB Timing and Control Logic Test Point Locations Range and Relay Logic Test Points Range Relay Logic Level Performance Standard Range Relay Status Chart Main PCB Null Detector Test...

Page 8: ...t Performance Test 5 18 5 15 Main PCB Power Supply Line Only Subassembly Performance Test 5 21 5 15 1 Table S 15 1 5 21 5 15 2 Table 5 15 2 5 21 5 15 3 Table 5 15 3 5 21 5 15 4 Table 5 15 4 5 21 5 16 Main PCB Oscillator Clock Subassembly Performance Test 5 22 5 17 Main PCB Reference Voltage Generator Subassembly Performance Test 5 24 5 18 Main PCB Timing and Control Logic Subassembly Performance T...

Page 9: ...ble Shielded input cable for use in high noise environments Hold Probe provides pushbutton control of Measure Hold functions 5 KV HV Probe extends DC voltage measurement to 5 KV 50 KV HV Probe extends DC voltage measurements to 50 KV GENERAL DESCRIPTION Option 84 RF Probe measures RF voltages to 200 MHz Option 88 Deluxe test leads include assorted tips Option 89 Standard test leads with replaceabl...

Page 10: ...digit oC 2V Range 2 Kn 20 Kn 200 Kn 0 002 of reading Ranges 5 digit oC 0 002S of reading Input 2V Range 1 digit oC Resistance 1010nminimum 2000 Kn Range 2V Range O OOS of reading 101On minimum 1 digit oC 20V 200V 1000V Ranges 20 000 Kn Range 10 Mn 25 O OOS of reading formal Mode 80 dB at 50 and 60 Hz and at I Noise Rejection multiples of 10 Hz 0 1 50 dB at 59 Hz general slope I increasing at 12 dB...

Page 11: ...ise 60 Hz with I Kohm imbalance Rejection in either lead Input 1 Megohm with 100 pF Impedance shunt capacitance with 221J F in series on aRranges Zero Offset Range 2V 40 digits max 2V 5 digits max 20V 30 digits max 200V 5 digits max 2000V 5 digits max Settling Time 1 of range to F S or F S To 100 of range to 1 of range Step settles to 0 1 of final value within 1 5 seconds 20 Volt Range 30 Hz to 50...

Page 12: ...ximum Accuracy 6 Months 230 C SoC Common 1 KV DC or peak AC input 2 2 20 200 rnA Ranges Mode Voltage to Earth Ground 0 12 of reading 4 digits 2000 rnA Range 0 3 of reading Power 100 120 220 240 volts Requirements IO from nominal 50 to 400 Hz 10 watts maximum 20 digits Temperature o to 500 C Coefficient 0 01 of reading 2 digits oC Storage 200 C to 750 C Temperature 200 C to 650 C w battery opt Oper...

Page 13: ...UNTING SHOWN INSTALLATION OPERATION 2 4 RACK MOUNTING 2 4 1 The rack mounting kit Option 60 allows the user to mount the instrument Offset Left or Offset Right in a standard 19 inch rack and requires 3 1 2 inches of vertical mounting space The kit consists of a rack mount panel left and right case supports two brackets and 8 securing nuts 2 4 2 The option is shown in figure 2 1 and assembled as de...

Page 14: ...age adjustment PCB is gained by removal of 3 screws at the rear of the instrument and the removal of the case see table 2 2 2 2 I J UP ON AUTO POWER ON OFF AUTO selects range most compatible with input signal Push on push off DN Causes instrument to downrange Momentary on UP Causes instrument to uprange Momentary on DC OFFSET Allows user to compensate out un wanted input signal bias DISPLAY consis...

Page 15: ...carton with its molded plastic foam form and plastic dust cover is specifically designed to pro vide the required support necessary for safe shipment Whenever possible these should be used for reshipment 3 8 READ HOLD Control Connector Receives Read Hold Switch option eD DISASSEMBLY Screws Removal of these screws permits removal of case SIDE VIEW APERTURE REAR OF INSTRUMENT PCB JUMPER Figure 2 3 L...

Page 16: ... 5 1 Signal input is through four banana jacks on the front panel These jacks accept standard probe banana plugs and are spaced to accept dual banana plugs Several probe sets for the 4600 are available from the factory see Section 1 2 9 5 2 The left hand pair of input jacks are reserved for DC and AC current measurements the jacks on the right are for voltage and resistance measurements CAUTION Do...

Page 17: ...on 70 battery pack 2 12 BATIERVPACK Option70 2 1 2 1 With the battery pack option the instrument becomes completely portable taking measurements for up 980479 to four hours of continuous use Recharging occurs when the instrument is connected to the power line and the power switch is set to the OFF position 2 12 2 When the battery charge drops below operating level the condition is indicated by a L...

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Page 19: ...in PC board by four spacers an aluminum shield located between the boards prevents any digital noise generated on the option board from affecting the measure ment circuitry on the Main board 3 2 2 One end of the option board forms an edge con nector that extends out the back of the instrument through a slot provided for this purpose This connector is the option output connector and is designated J...

Page 20: ...Logic END OF DIGITIZING TRANSFER J t 5 MSEC j PART OF MUX U6 U7 00 1 MS il n _______ DATA TRANSFER MUX CLOCK 1 kHz SERIAL DATA STROBE PARALLEL DATA VALID _________ I I f 8 MS oIL I I I I II I I I I I I I I UNITS TENS HUNDREDS THOUSANDS TEN THOUSANDS FUNCTION J RANGE J Figure 3 3 Timing Diagram 20 IlS ARTEKMEDIA 2012 ...

Page 21: ...ed Function byte The seventh step the multiplexer selects the Range byte On the eighth step the flip flop is reset and the gate is inhibited preventing the advancement of the counter or the generation of additional strobe signals The counter is reset when TRANSFER goes false 3 3 2 4 The function encoding circuitry converts the polarity AC T and Kninputs into a BCD coded output for use by the multi...

Page 22: ...I Function Fl F2 F4 F8 Dec DC 0 0 0 0 0 DC 1 0 0 0 1 ACV 1 1 0 0 3 DCI 0 0 1 0 4 DCI 1 0 1 0 5 ACI 1 1 1 0 7 Kn 1 0 0 1 9 3 4 4 Range Codes 3 4 4 1 The range codes are shown in table 3 3 3 4 Range Rl R2 R4 Dec 20 000 1 0 1 5 2 000 0 0 1 4 200 1 1 0 3 20 0 1 0 2 2 1 0 0 1 2 0 0 0 0 3 4 5 Serial Output 3 4 5 1 The data output is available in serial form on four lines strobe data is available in logi...

Page 23: ...ld 3 4 7 1 The hold line is an external command line When held at logic low prevents a new measurement cycle from starting Any measurement in progress when hold is com manded is allowed to complete 980479 Table 3 6 Parallel Out Pin Location 1202 5VRef 1 A Earth Ground 2 B 3 C 4 D Parallel Data Valid 5 E 6 F Inhibit Parallel Data 7 H Hold 8 J Thousands 8 Thousands 4 9 K Function 4 10 L Range 4 11 M...

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Page 25: ...nd counter with the synchronization required to perform the analog to digital conversion of the measurement signal The instrument performs continuous measurement cycles The measurement cycle is illustrated in figure 4 3 4 10 Note that the digitize cycle is divided into four major periods The first which is 100 milliseconds long is the signal integrate period During this time the Timing and Control...

Page 26: ...E DECODER I INTEGRATOR TIMING TIMING AND AND MULTI MUX SWITCHING 4 TO 7 LINE LED DISPLAY I I I CONTROL SIGNALS PLEXER BCD 7 LlNE ODE DECODER r r r REFERENCE GENERATOR CONTROL _ _ SIGNALS I L P O L A R IT Y ________________ I I I I ____ DIC T IN ISPLAY__ _ RANGING RANGE RANGE RANGE CODE DECIMAL DECIMAL POINT CONTROLS L CO NT RO L 1 _______________ tL _ L _ L __ L __ LOGIC DECODER CIRCUIT PATH LEGEN...

Page 27: ... the attenuator in the AC Converter circuit The isolator gain is also controlled by the range control logic and is switched from Xl to XIO gain depending on the selected operating range of the instru ment The range code from the range control logic is applied to the decimal decoder which provides the signals to the LED displays to properly locate the decimal point A simplified block diagram of the...

Page 28: ...ed form in figure 4 5 The attenuator and shunt circuit performs the following functions 1 at tenuation of input measurement voltages on the 20 200 and 1000 volt dc ranges 2 scales down the ohms current source when the instrument is on the Kohms ranges 3 acts as a shunt when on the ac or dc current ranges and 4 the attenuator and shunt circuit contains two series resistance strings with pick off pO...

Page 29: ... s ate of the range relays 4 17 Ohms Amplifier A simplified functional block diagram of the ohms amplifier is illustrated in figure 4 6 The ohms amplifier may be viewed as a current to voltage converter in that it produces an output voltage directly proportional to the input current The input current is directly proportional to the value of the resistance being measured The output voltage produced...

Page 30: ...ent application of more than 5V to the input of the isolator amplifier The isolator amplifier is an operational amplifier with a gain of 1 or a gain of 10 depending upon the control signals applied to the gain switches by the range control logic of the instrument The isolator accepts either positive or negative voltage levels at its input on one of two ranges 1 zero to 1999 volts or 2 zero to 1 99...

Page 31: ...wo slopes shown representing the capacitor charging slope these represent two measurement levels Note that the time is the same for the charge for both measurements but that the charging rate and the final charge level is different From this it can be seen that the signal integrate period is always the same length but the charging rate and level of the capacitor varies with the measurement Signal ...

Page 32: ...rough potentio meters which are adjusted to provide 1V dc from the reference source These two amplifiers are operated at unity gain are non inverting and produce a positive 1V dc output 4 8 4 22 Timing and Control Circuit Operation of the 4600 is controlled by the Timing and Control circuits figure 4 11 block diagram These circuits provide synchronization and control signals which control the sequ...

Page 33: ...ESET 3 4 RESET 4 11 MEASUREMENT G CYCLE TIMIN RESET SW INTEG RESET UPRANGE SW U9 OIL DISPLAY PCB OIL TORNGSW 6 10 U13 fr U14 REF SW 11 INTEG G NT INTEG ft 7 2 U13 U14 REF SW 13 13 INTEG 9 U7 SIG INT AUTO RANGE 5 1 4 U9 r U7 RESET POL DR AUTO RANGE F F US 2 D LO POL 9 3 6 HI POL CLK Q POL TR ANSFER Figure 4 11 Timing and Control Circuit Simplified Block Diagram 4 9 ARTEKMEDIA 2012 ...

Page 34: ...INTEGRATE 10 000 COUNTS 10 000 COUNTS HIS 10 000 COUNTS F S 10 000 COUNTS 100 MSEC 100 MSEC 100 MSEC 100 MSEC INTEGRATOR OUT I I NULL DETECTOR I L I I Qe1 J I I Qe2 I I I SiGiNT L I I I I TRANSFER J I I I I RESET J r I I I I SIG SW J I I I REF SW I I I RESETSW I L Figure 4 12 Measurement Timing Cycle 4 10 ARTEKMEDIA 2012 ...

Page 35: ...000 COUNTS F S 10 000 COUNTS 100 MSEC 100 MSEC 100 MSEC 100 MSEC I 8V I I I I I I I I I I I I I I I I I I I I I INTEGRATOR OUT I I NULL DETECTOR O r I I I I 0 81 1 r I I I I 0 82 I I I I I I SIG INT L I I I I TRANSFER J I I I I I RESET 1 r I I I I SIGSW I I I I I REF SW I I I I I I RESETSW I L Figure 4 12 Measurement Timing Cycle continued 4 11 ARTEKMEDIA 2012 ...

Page 36: ...s a handy reference to use while reading the detailed description Qe1 1 Qe2 0 100 msec count from 10 000 to 19 999 called reference integrate This count total limit is referred to as full scale Qe1 0 Qe2 1 100 msec countfrom 20 000 to 29 999 called reset fixed Four timing segments are established by the CMOS chip 3814 counter on the Display PCB With an internal clock frequency of 100 kHz these fou...

Page 37: ...in 8 also causes the transfer to go to a logic low that signals the termination of the clock count in the CMOS 3814 At this point the digitizing sequence is only at the end of sequence 2 but because a zero detect null detect has been sensed the next sequence state 3 is an internal reset until sequence 4 which is a fixed reset sequence If a null detect is sensed during sequence state 2 before 1000 ...

Page 38: ... LATCH f OET BLANKING CONTROL ABC 0 E 8 7 17 22 21 100 120 A A B C C J J 3814 Lc Lc f I f f 6 SCANNER j 111 STEP Figure 4 13 Logic Array 19 0 E f 4 DO 01 J 0 4 f IA B clo E IMULTOPLE C SELECT 0 E 1 02 03 04 Vss VGG_ VOO 4 5 6 10 18 aE1 16 0E2 9 aE2L 2 1 1 4 5 3 ARTEKMEDIA 2012 ...

Page 39: ...integrator output to mask the switching transients that occur during the transitions from signal integrate to reference integrate 4 31 Qe1 0 and Qe2 O During this period the signal switch is turned off and a reference plus or minus is con nected to the input of the integrator through a bi lateral switch The decade counter is set to 00 000 and the 3814 will ignore the next 10 counts Because of the ...

Page 40: ...er energizes the strobe line B This is repeated until all the codes have been displayed on the display devices and the sequence begins again with the lower digit The LEDs are illuminated only as long as the strobe lines A through E from the multiplexer are 4 16 energized However this display strobe frequency is such that the LEDs appear to be continuously Itt due to the persistence characteristic ...

Page 41: ...E COUNTER R1 R2 R4 1 3Ir SV K1 ROM K3 K4 KS K6 7 K2 AC RELAY POWER ENABLE ISO X1 SW ISO X10 SW ATTENUATOR CURRENT SHUNT RELAYS SV 20 200 4 AC RELAY 1000 AC RELAY 1 _ R 2 D gIMAL I DECODER R1 R4 DISPLAY 5 6 2 4 r STEP DOWN OR 2K 57 2 11 57 4 CLK a CLR 57 3 D Figure 4 16 Range Control 4 17 ARTEKMEDIA 2012 ...

Page 42: ...step up flip flop and causes the range counter to step up one count If the null detect signal 4 18 should occur before the counter reaches the 5 point in its count a signal termed divide by 2K 7 2K is produced indi cating that the measurement is less than 5 of full scale This divide by 2K signal is applied to the step down flip flop which causes the range counter to count down one step Thus the ma...

Page 43: ...to Unit Performance Tests and Subassembly Performance Tests The unit level performance tests are designed to check the instrument by MAINTENANCE function such as AC Volts and enable isolation of a mal function to a replaceable module or subassembly The sub assembly performance tests are designed to check the operation of a module or subassembly and isolate a mal function to an individual component...

Page 44: ...t 0999 8 to 1000 2 DMM downranges in auto from 2000 Range to 210 Range 0099 9 Vdc DMM downranges in auto from 200 Range to 20 Range 009 99 Vdc DMM downranges in auto from 20 Range to 2 Range 00 999 Vdc DMM downranges in auto from 2 Range to 2 Range 0 0999 Vdc DMM upranges in auto from 2 Range to 2 Range 20000 Vdc DMM upranges in auto from 2 Range to 20 Range 2 0000 Vdc DMM upranges in auto from 20...

Page 45: ...e to 2 range 2 1 9900 VAC 30 Hz to 50 Hz 1 9830 to 1 9970 2 1 9900 VAC 50 Hz to 20 kHz 1 9871 to 1 9929 2 1 9900 VAC 20 kHz to 50 kHz 1 9870 to 1 9930 2 1 9900 VAC 50 kHz to 100 kHz 1 9746 to Overload manual or 02 005 auto to 20 range 20 19 900VAC 30 Hz to 50 Hz 19 820 to 19 980 20 19 900VAC 50 Hz to 20 kHz 19 868 to 19 932 20 19 900 VAC 20 kHz to 50 kHz 19 864 to 19 936 20 19 900 VAC 50 kHz to 10...

Page 46: ...mA Range Auto Input Terminals JI Hi and J2 Lo connected with a copper jumper DMM Range Signal Input Readout 2 199 P ADC 19872 to 19928 2 1 99 mA DC 1 9872 to 1 9928 20 19 9 mA DC 19 872 to 19 928 200 199 mADC 198 72 to 199 28 2000 1 99ADC 1982 0 to 1998 0 Table 5 5 ACV mA Calibration Check Input and Control Performance Setting Standard Function ACV mA Range Auto Input Terminals JI Hi and J2 Lo con...

Page 47: ...o temperature stabilize 5 3 2 Disassembly of the instrument case is as follows a Place instrument on a flat level surface with the bail extended towards the back of the instrument b Refer to the operating manuals provided with the test equipment to be used and provide appropriate warmup time WARNING Removal of covers exposes potentially lethal voltages On units equipped with battery pack option th...

Page 48: ...n the procedure are indicated in figure 5 1 5 6 5 3 5 CALIBRATION PROCEDURE 5 3 6 The following steps are for zeroing the instrument prior to range calibration a b Disconnect WI jumper Apply a 1 millivolt dc signal to the integrator side of WI 0 refer enced to Mecca The polarity of this signal should be such that R82 has no effect if adjusted Adjust R81 for a display of 00010 disregard decimal Rev...

Page 49: ...tment is indicated the calibration step is for verification of proper instrument operation 5 3 8 At the completion of the procedure remove power cord from line Reassemble case by reversing the procedure of paragraph 5 3 2 Table 5 7 DC Calibration Adjustment FUNCTION RANGE INPUT ADJUST DISPLAY REMARKS DC 2V 19900 R51 19900 20V 19 900 R29 19 900 200V 199 00 R31 199 00 1 KV 1000 0 R33 1000 0 Reduce i...

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Page 51: ...performance test table The numbered test points refer to square black test point flags IIappearing on the assembly drawing and schematics in the drawing section 6 These black square test point flags indicate voltage measure ment points Si nilarly the alphabetic test points refer to black diamond shaped flags appearing on the assembly drawings and schematics The Alphabetic diamond flags indicate os...

Page 52: ... Isolator Output E17 Fig 5 2 1 9900VDC Tol Range 2 Manual Set DC voltage standard to 1 9900V DC Voltage Input S3 2 N C Fig 5 2 1 9900VDC Tol Isolator Input SI 4 N C Fig 5 2 1 9900VDC Tol Isolator Output E17 Fig 5 2 1 9900VDC Tol Range 20 Manual Set DC Voltage stand ard to 19 900V DC Voltage Input S3 2 N C Fig 5 2 19 900VDC Tol Isolator Input SI 4 N C Fig 5 2 1 990VDC Tal Isolator Output E17 Fig 5 ...

Page 53: ...standard to 1000 0V DC Voltage Input S3 2 N C Fig 5 2 1000 0VDC Tol Isolator Input SI 4 N C II Fig 5 2 l OOOVDC Tol Isolator Output E17 Fig 5 2 l OOOVDC Tol DCV S4 II R37 R 200K 10M S2 1 0 0 0 6 R44 lOOK 10 9M 10 R49 E17 100 900K U1SA 2 100 13 X1 RSO 90K 4 42K 4 U1sa 3 1000 S 9K X10 R52 S3 3 S3 8 487 0 0 1K M ENERGIZED Figure 5 2 DCV Single Thread Diagram 5 1I ARTEKMEDIA 2012 ...

Page 54: ... Signal Input Sl 1 COM Fig 5 3 1 990V AC Tol Isolator Input S2 4 COM Fig 5 3 1 990VDC Tol Isolator Output E17 Fig 5 3 1 990VDC Tol Range 20 Manual Set AC voltage standard to 19 9V 10 kHz AC Signal Input Sl l COM Fig 5 3 19 9V AC Tol Isolator Input S2 4 COM Fig 5 3 O l990VDC Tol Isolator Output E17 Fig 5 3 1 990VDC Tol Range 200 Manual Set AC voltage standard to 199 0V 10 kHz AC Signal Input Sl 1 C...

Page 55: ...CONV RELAY POWER ENABLED AC 1000 RELAY AC 20 200 RELAY 3 3 o L __ JVV r I II I r _ _ 8 t m I AC CONVERTER ASSY_ P N 403873 AC CONV RELAYS IIIENERGIZED Figure 5 3 ACV Single Thread Diagram X1 X10 II 5 13 ARTEKMEDIA 2012 ...

Page 56: ... 4 0 199V DC Tol Isolator Output E17 II Fig 5 4 1 990V DC Tol Range 2 Manual Set Ohms standard to 1 99 Kohms Isolator Input S2 4 COM Fig 5 4 1 990VDC Tol Isolator Output E17 II Fig 5 4 1 990V DC Tol Range 20 Manual Set Ohms standard to 19 9 Kohms Isolator Input S2 4 COM Fig 5 4 1 990V DC Tol Isolator Output E17 II Fig 5 4 1 990VDC Tol Range 200 Manual Set Ohms standard to 199 Kohms Isolator Input ...

Page 57: ...IN ENERGIZED 52 1 53 2 0 0 0 53 5 B 53 3 C26 53 1 0 53 8 1V OHM REF R109 10K R49 100 2 U15A 13 R50 4 42K X1 4 U15B 3 5 R52 487 X10 M Figure 5 4 KOhms Single Thread Diagram E17 1V DC FROM REFERENCE DIVIDER 5 15 ARTEKMEDIA 2012 ...

Page 58: ...0V DC Tol Range 2 Manual I Set current standard to 1 99 rnA DC I Current Shunt 0 1990VDC Isolator In K3 Fig 5 5 Tol Isolator Output E17 II Fig 5 5 1 990V DC Tol Range 20 Manual Set Current standard to 19 9 rnA DC Current Shunt O l990VDC Isolator In K4 Fig 5 5 Tol Isolator Output E17 Fig 5 5 1 990V DC Tol Range 200 Manual Set current standard to 199 rnA DC Current Shunt O l990VDC I Isolator In K5 F...

Page 59: ...A 51 54 51 4 53 1 o o 51 6 0 1 I E12 M ISO RANGE K2 K3 K4 K5 K6 7 GAIN 1m_ENERGIZED Figure 5 5 DOnA Single Thread Diagram X1 4 X10 SHUNT RESISTANCE U15A 13 U15B 5 2 R50 4 42K 3 R52 487 5 17 ARTEKMEDIA 2012 ...

Page 60: ...t K3 Fig 5 6 0 1990V AC Tol Isolator Input S2 4 COM Fig 5 6 0 1990VDC Tol Isolator Output E17 Fig 5 6 1 990VDC Tol Range 20 Manual Set AC current standard I to 19 9 rnA AC Converter Input K4 Fig 5 6 0 1990V AC Tol Isolator Input S2 4 COM Fig 5 6 0 1990VDC TOl l Isolator Output El7 Fig 5 6 1 990V DC Tol Range 200 Manual I I Set AC current standard I to 199 rnA AC Converter Input K5 I II Fig 5 6 0 1...

Page 61: ...NVERTER RELAY POWER DISABLED AC 1000 RELAY AC 20 200 REL AY I E12 M 8 m 1 2 I I 51 M 0 0 Xl goon Xl0 ISO K4 K5 K617 GAIN nt 1 1 ENE RG IZED Figure 5 6 AemA Single Thread Diagram M SHUNT RESISTANCE 5 19 ARTEKMEDIA 2012 ...

Page 62: ...s are segregated because the main PCB contains a number of separate functional circuits such as the clock isolator range control and null detector Separate performance tests are provided for each of the remaining smaller boards 5 4 12 Note that the test points in the performance test tables refer to the performance standard or waveforms in the test and to the test point shown on the assembly drawi...

Page 63: ...s E43 to E47 16 to 16 5n E43 to E46 16 to 16 Sn E46 to E47 32 to 33n E42 to E44 0 8 to 0 9n E42 to E4S 0 8 to 0 9n E44 to E45 1 6 to 1 8n Measure rectified DC Voltages per table S IS 4 NO Repair defective component s P8 1 to P8 2 2 6 to 2 7Sn P8 1 to P8 3 2 6 to 2 7Sn Table 5 15 4 P8 2 to P8 3 5 2 to 5 Sn DC Voltages Referenced to TPI Mecca CR26 27 Cathodes 21 0 to 22 0 Vdc Table 5 15 3 CR24 2S An...

Page 64: ...ital common and J4 La connected with a copper jumper Crystal Oscillator U7 13 Fig 5 7 Waveform No I Output Oscillator Output U7 10 Fig 5 7 Waveform No 2 Clock Output U8 9 Fig 5 7 Waveform No 3 Waveforms for Table 5 16 CRYSTAL OSCI LLATOR OUTPUT 2 OSCILLATOR OUTPUT riiQ U7 13 j j 1 V V OIV DC COUPLED 3 NO U8 9 2 V V OIV DC COUPLED 5 22 I I J 5 jlS S OIV CLOCK OUTPUT 10 jlS S OIV 200 kHz I I J 1 J 1...

Page 65: ...V J Sill B R30 C 7 88 K nop LSV R28 ZI Etj W1 I J _ 24B I _ f IN lIAB 14LSIOS 1 13V S IV ffiiRHJviis l 74L7ooIS C7 Ipf I n Y DOV E1 EZI E l 22 TRJ U8 REF DIGITAL COMMON REF MECCA Figure 5 7 Main PCB Oscillator Clock Test Point Locations 5 23 ARTEKMEDIA 2012 ...

Page 66: ... Current Generator CR14 Cathode bias voltage Fig 5 8 9 5 to 9 9 Vdc Current Generator R64 Fig 5 8 10 1 to 10 6 Vdc bias voltage Reference Zener VR8 Cathode Fig 5 8 6 2 to 6 4 Vdc voltage refer to voltage on zener tag 1 V Reference Output ARlb 14 II Fig 5 8 0 9999 to 1 0001 voltage Vdc IV Reference Input ARlc 10 Fig 5 8 l 0005 to 1 0015 Vdc 1V Reference Output ARlc 8 Fig 5 8 0 9999 to 1 0001 Vdc 1V...

Page 67: ... rIO REF MECCA CI 2200 1 IOV II Ii 5 1Jl _ r _ J B 1 1AI 2 74L M_I 8 53 Figure 5 8 Main PCB Reference Voltage Generator Test Point Locations iN 5ZA 0 S V 5 25 ARTEKMEDIA 2012 ...

Page 68: ...xt trig scope at S7 3 NIO Counter Output Qel U9 2 Fig 5 9 Waveform No 4 Counter Output Qe2 U9 1 Fig 5 9 Waveform No 5 Signal Integrate U9 3 Fig 5 9 Waveform No 6 Fig 5 9 Waveform No 7 Reset U9 6 Signal Switch Output Ul4 2 Fig 5 9 Waveform No 8 Reference Switch Ul4 10 Fig 5 9 Polarity Display Output Waveform No 9 Reference Switch Ul4 12 Fig 5 9 Polarity Display Output Waveform No 9 Reset Switch Out...

Page 69: ...JIOlo o 0 0 6 2 o 0 0 10 0 0 57 1 57 a o 0 0 I EI5 REF EXT SCOPE TRIGGER _ _ REF DIGITAL COMMON Figure 5 9 Main P B Timing and Control Logic Test Point Locations 5 27 ARTEKMEDIA 2012 ...

Page 70: ...IV 6 SIGNAL INTEGRATE 7 RESET NO NO U9 3 U9 6 I I 2 0V 2 0V I I V OIV V OIV 50 MS 50 MS DC COUPLED S OIV DC COUPLED S OIV 8 SIGNAL SWITCH 9 MINUS REFERENCE SWITCH NO NO U14 10 U14 2 O N HIS FIS I l J 2 0V 2 0V O N HIS FIS i CVlDIV V OIV I I I I I 50 MS 50 MS i DC COUPLED S OIV DC COUPLED S OIV i I I I 5 28 ARTEKMEDIA 2012 ...

Page 71: ...OIV RESET SWITCH U14 4 OIN HIS FIS I 5QMS DC COUPLED S OIV REF DIGITAL COMMON Waveforms for Table 5 18 11 l NoT 2 0V v OIV TRANSFER U10 8 OIN DC COUPLED HIS FIS 50 MS S OIV REF DIGITAL COMMON i 5 29 ARTEKMEDIA 2012 ...

Page 72: ...uts outputs US II ROM inputs outputs US Fig 5 10 ROM inputs outputs US ROM inputs outputs US ROM inputs outputs US ROM inputs outputs US ROM inputs outputs US B Fig 5 10 ROM inputs outputs US ROM inputs outputs US 5 4 13 The test point 9 specified in table 5 19 refers to the ROM input and output pins on ROM US shown in fig ure 5 10 For the specific pin to be used for testing refer to figure S 11 F...

Page 73: ... lo lo ___________B _____ B__________ B_ _ _________ B____________ 5 i Z o 0 0 o 0 0 0 0 0 0 0 0 57 57 2 o 0 0 o 0 0 57 3 57 4 o 0 0 Figure 5_10 Range and Relay Logic Test Points 5 31 ARTEKMEDIA 2012 ...

Page 74: ...ENT 1 ROM INPUT Kn CURRENT Rl I R2 R4 I B C D E ROM OUTPUT _ 085 to 145 D 5 26 to 5 3 Typical for all Outputs 9 F F F F j 4 j I I Base of Q1 K1 1 1 U4 11 LOAD K3 1 K4 K5 K6 K7 UPLIMIT K2 Figure 5 11 Range Relay Logic Level Performance Standard 5 32 ARTEKMEDIA 2012 ...

Page 75: ... X10 Xl Source 2 a DC 10 100 1000 2 1 rnA 2 1 rnA 20 100 uA b Kn 200 1O uA 2K l uA 20K 100 nA 2 2 c AC 20 lOOKl 200 100 Kl 1K 1000 K2 2 909n 2 90 9n d DC 20 9 09n rnA 200 909n 2K In 2 909n 2 90 9n e AC 20 9 09n rnA 200 909n 2K In D OFF ON Figure 5 12 Range Relay Status Chart 5 33 ARTEKMEDIA 2012 ...

Page 76: ...ure Range Auto ments are referenced Input Terminals J3 Hi to TPI Mecca and J4 Lo connected Scope Ext trig at to a 1 Vdc source S7 3 N O Null detector input CRI5 Cathode Fig 5 ll Waveform No 12 Null detector output R79 Fig 5 11 Waveform No 13 J3 Hi and J4 Lo connected to a 1 Vdc source Null detector input CRI5 Cathode Fig 5 11 Waveform No 14 Null detector output R79 Fig 5 11 Waveform No 15 5 34 ART...

Page 77: ...S oIV 14 NULL DETECTOR IN MINUS SIGNAL CR15 CATHODE 0 2V V oIV DC COUPLED REF MECCA 50 MS S oIV 13 NO NULL DETECTOR OUTPUT 2 0V V oIV R79 DC COUPLED REF MECCA 50 MS S oIV 15 NULL DETECTOR OUTPUT NO R79 2 0V VIOl V DC COUPLED REF MECCA 1 1 I 50 MS S oIV I I I 1 J j I J I J I j I i I 5 35 5 36 Blank ARTEKMEDIA 2012 ...

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Page 79: ... no 0 o 0 0 5 2 0 0 0 10 0 0 57 1 57 2 o 0 0 I E 5 1 30 8891 R28 REF EXT SCOPE TRIGGER REF MECCA Figure 5_13 Main PCB Null Detector Test Points CI 2200jlf IOV 5 37 ARTEKMEDIA 2012 ...

Page 80: ... 1 Vdc source Integrator Op Amp output 16 NO INTEGRATOR OUT C7 5 0V V OIV EXT TRIG 57 3 N O DC COUPLED REF MECCA 5 38 50 M5 S OIV Reference Test Illustration Designation Point Reference R77 III Fig 5 14 R76 II Fig 5 14 C7 Fig 5 14 C7 Fig 5 14 Waveforms for Table S 21 r I 5 0V V OIV EXT TRIG 57 3 N O DC COUPLED 50 M5 S OIV REF MECCA Performance Standard NOTE All measure ments are referenced to TP1 ...

Page 81: ...iTlO 0 0 0 0 57 57 2 o 0 0 m i1 I i1 I i1 Ii1 I J i1 I C 15 2200 f IOV V R30 889K REF EXT SCOPE TRIGGER REF MECCA 1m Figure 5 14 Main PCB Integrator Test Points 5 39 ARTEKMEDIA 2012 ...

Page 82: ...0003 Vdc Bootstrap amp 0 004 to 0 004 output VR2 anode Fig 5 15 Vdc Bootstrap voltage VR2 cathode Fig 5 15 4 90 to 5 10 Vdc Bootstrap voltage VR3 anode II Fig 5 15 4 90 to 5 10 Vdc Range 2 Isolator XIO switch control voltage on U15b 5 II Fig 5 15 4 7 to 4 8 Vdc Isolator XI switch control voltage off VISa 13 Fig 5 15 5 04 to 5 08 Vdc Range 2 Isolator XIO switch control voltage off U15b 5 II Fig 5 1...

Page 83: ...J3 and J4 to a Isolator input R44 II Fig 5 15 0 0999 to 0 1001 0 1 Vdc source Vdc range to 2 Isolator op amp II 1 0190 to 1 0210 output ARIa 7 Fig 5 15 Vdc Bootstrap voltage VR3 anode Fig 5 15 4 99 to 5 2 Vdc Bootstrap amp output VR2 anode II Fig 5 15 0 0950 to 0 0970 Vdc Isolator output e17 Fig 5 15 0 9998 to 1 0002 Vdc 5 41 5 42 Blank ARTEKMEDIA 2012 ...

Page 84: ...THIS PAGE LEFT BLANK SCANS By ArtekMedia ARTEKMEDIA 2012 ...

Page 85: ...II REF MECCA J O ________ ______________ ____________t 0 0 0 57 1 57 2 o 0 0 1111 II II Figure 5 15 Main PCB Isolator Bootstrap Test Points CI 22oo f IOV 5 43 ARTEKMEDIA 2012 ...

Page 86: ...g 5 16 2 560 to 2 580 Vdc Ohms protection bias VR9 anode Fig 5 16 1 940 to 1 960 Vdc Ohms protection bias CR21 cathode Fig 5 16 0 550 to 0 570 Vdc Ohms output drive CR21 anode Fig 5 16 0 0001 to 0 0001 Vdc Ohms reference 1 0005 to 1 0020 voltage R36 II Fig 5 16 Vdc Remove jumper from Ohms op amp non J3 and 14 set range to inverting input R85 Fig 5 16 2 69 to 2 71 Vdc 2 manual Ohms opamp 13 38 to 1...

Page 87: ...8 0 1 1111 REF MECCA Figure 5 16 Main PCB KOhm Amplifier Test Points elI 2200jAf IOV C7 IJ If I Y DOV ella 22 00jAf IOV J SIn Q lN75ZA 0 CI7 5 oV qWP 25 V LZI 1 M 5 _ E E 8 4f 7 74LS05 G I 7 cift 2 8 lolLS OS I i 3V uk zt 5 1 7S 1 IK IK 5 45 ARTEKMEDIA 2012 ...

Page 88: ... function to Kohms Qe2L 0 L U2 9 Fig 5 15 low until overrange open input terminals 100 step U2 I1 20 E9 Fig 5 15 Waveform No 4 2K U2 19 Waveform No 5 50 Hz 5 Hz Transfer U2 2 Waveform No 6 OA U2 S Waveform No 7 OB U2 7 Waveform No 8 Oc U2 17 Waveform No 9 00 U2 22 E14 Waveform No 10 OE U2 21 Waveform No II Q1 U24 E5 Waveform No 12 Q2 U2 5 E6 Waveform No 13 Q4 U2 6 E7 Waveform No 14 Qs U2 10 ES Wav...

Page 89: ...llector NOTE To derive counter content connect oscilloscope probe to TP12 and record the HI LO logic levels as shown in Waveform 12 Then connect the oscilloscope probe to test points 13 through 15 and record the HI LO content shown for each point Add the values as shown within waveform grid 16 and the total is the content of the counter Performance Standard Waveform No 17 Waveform No 18 Waveform N...

Page 90: ...DIV V DIV 10 J LSEC 50 MSEC S DIV S DIV 3 Q e2 4 100 STEP NO NO I U2 16 U2 11 20 or E9 I I I I 2 0V 2 0V I I i I V DIV V DIV I 50 MSEC 1 MSEC S DIV S DIV I 5 2K 6 TRANSFER NO NO U2 2 U2 19 OIN HIS F S i 2 0V 2 0V I v DIV V DIV I 10 MSEC 50 MSEC S DIV S DIV i 5 48 ARTEKMEDIA 2012 ...

Page 91: ... i 9 Oc 10 OD NO NO I U2 17 U2 22 or E14 I r r r r I I 2 0V 2 0V i V OIV V OIV 1 MSEC 1 MSEC S OIV S OIV EXAMPLE DIGITAL DISPLAY 18229 KOHMS 11 OE 12 Q1 DECIMAL WEIGHT OF 1 U2 4 E5 NO NO U2 21 LSD TO j1 I0 I0 I0 I1 t SI NG LE SCAN MSD r 2 0V 2 0V I Iv DIV V OIV 1 MSEC 1 MSEC S OIV S OIV iI I 5 49 ARTEKMEDIA 2012 ...

Page 92: ...DIV S DIV EXAMPLE DIGITAL DISPLAY 18229 KOHMS SUM OF 12 TO 15 15 Q8 DECIMAL WEIGHT OF 8 U2 10 E8 16 DIGITAL DISPLAY 18229 KOHMS NO NO LSD TO I LSD T0 11 I 0 1 0 11 I0 SINGLE SCAN MSD r SI NG LE SCAN I MSD I Q1 1 0 0 0 1 I Q2 0 1 1 0 0 J Q4 0 0 0 0 0 I I 2 0V I Q8 1 0 0 1 0 V DIV I TOTAL I I 1 MSEC 1M I S DIV S DIV 17 Q1 COLLECTOR LED 5 STRO E 18 Q2 COLLECTOR LED 4 STROBE NO NO I I to I I I I I r I...

Page 93: ...or Table 5 24 continued 19 03 COLLECTOR LED 3 STROBE NO 2 0V V OIV 1 MSEC S OIV 21 05 COLLECTOR LED 1 STROBE NO 2 0V V OIV 1 MSEC S OIV 20 04 COLLECTOR LED 2 STROBE NO 2 0V V OIV 1 MSEC S OIV 5 51 ARTEKMEDIA 2012 ...

Page 94: ... El0 Ell 410704 J E12 Figure 5 17 Display Subassembly Test Points 5 52 ARTEKMEDIA 2012 ...

Page 95: ...n Fig 5 18 0 02 to 0 03 Vdc Output driver bias R13 15 junction Fig 5 18 13 4 to 13 6 Vdc Output driver bias R16 17 junction Fig 5 18 13 4 to 13 6 Vdc Driver output C15 minus Fig 5 18 0 85 to 0 95 Vdc Connect 13 Hi and J4 Op amp output R15 16 junction Fig 5 18 Waveform No 1 10 to a 1 RMS ACV 1 kHz source 2 range output driver signal R13 15 junction Fig 5 18 Waveform No 2 output driver signal R16 17...

Page 96: ... I V i 3 NEGATIVE OUTPUT DRIVE R16 R17 JUNCTION I 1 100 MV V OIV AC COUPLED V J V 200 J LSEC S OIV i 5 POSITIVE RECTIFIED OUTPUT CR5 CATHODE 2 0V V DIV I I DC COUPLED 5 54 L 1 200 J LSEC S OIV l I I I 4 DRIVER OUTPUT NO C15 MINUS SIDE I I I 1 l I V 2 0V V DIV I I V 200 J LSEC AC COUPLED S OIV 6 NEGATIVE RECTIFIED OUTPUT NO CR6 ANODE 2 0V V OIV I II VI I I 200 J LSEC DC COUPLED S OIV ARTEKMEDIA 201...

Page 97: ...10 I oo RI 1M oS oO K2 Figure 5 18 A C Converter Subassembly Test Points 5 55 ARTEKMEDIA 2012 ...

Page 98: ...4 E6 WIIT 5 D2 E14 GRY 13 OD lK MUXDR E8 VIO 4 D8 E5 BLU 14 Dl E15 GRN 3 Kohms E16 YEL 15 ACV E20 ORG 2 I CURRENT E19 RED 16 5V DC E21 BRN 1 DIG COM Connect P8 on Main PCB to J8 on Data Output PCB isolated supply Check following voltage levels referenced to of C6 Rectified voltage CR1 CR2 cathode Fig 5 20 7 9 to 8 2 Vdc Zener voltage VR3 cathode B Fig 5 20 5 5 to 5 7 Vdc Isolated regulator voltage...

Page 99: ...strobe U7 I2 1202 E Fig 5 20 Waveform No 8 Parallel data valid U7 4 J202 D Fig 5 20 Waveform No 9 Check the function code as shown below FI F2 F4 Fg Wght DCV 0 0 0 0 0 DCV 1 0 0 0 I PCB locations are ACV 1 1 0 0 3 Fi UlO 4 DCI 0 0 1 0 4 F2 U11 4 DCI 1 0 1 0 5 F4 Ul2 4 ACI 1 1 1 0 7 F8 Ul3 4 KSl 1 0 0 1 9 18 V 10 L 1202 Check the range code as shown below Range Code Rl R2 R4 Wght 2 0 0 0 0 2 1 0 0 ...

Page 100: ...0 100 1202 21 lK 1202 6 10K J202 17 2 1202 Z 20 1202 Y 200 1202 X 2K 1202 T 20K 1202 U 4 1202 14 40 1202 13 400 J202 12 4K 1202 9 8 1202 8 80 1202 P 800 J202 N 8K 1202 K Check the serial 1 output at 1202 S or U1 0 1 Ext trig Ul 0 8 Check the serial 2 output at 1202 15 or Ul 1 Ext trig U11 8 as shown in figure 5 19 Check the serial 4 output at 1202 8 or UI2 Ext trig Ul2 8 Check the serial 8 output ...

Page 101: ...to 18 243 Kn Serial Data Strobe I U1 0 1 Serial 1 U11 1 Serial 2 U12 1 Serial 4 U UB l Serial 8 U I I I I I I U lJ Figure 5 19 Serial Output Codes SYNC OR 100 0 1 OR 1 0 1 0 0 OR 0 1 0 0 0 000 1 0 EQUALS 3 4 2 8 1 OR t UNITS TENS HUNDREDS THOUSANDS TEN THOUSANDS 1 0 0 1 0 0 1 0 9 2 FUNCTION 9 Kn RANGE 2 20 Rng 5 59 ARTEKMEDIA 2012 ...

Page 102: ... HIS F S OV HIS F S I I Ia Ia I I I 2 0V 2 0V I V DIV V DIV I I EXT TRIG S7 3 N O 50 MS EXT TRIG S7 3 N O 50 MS DC COUPLED S DIV DC COUPLED S DIV REF DIGITAL COMMON REF DIGITAL COMMON 5 DATA STROBE 6 SERIAL DATA STROBE NO NO U7 5 AT END OF DIGITIZING OCI 5 PIN 1 PULSE WIDTH 40J S I 2 0V 2 0V VIDIV V DIV I EXT TRIG S7 3 N O 1 MS EXT TRIG S7 3 N O 1 MS DC COUPLED S DIV DC COUPLED S DIV REF DIGITAL C...

Page 103: ...PLED REF OUTPUT COMMON 10 MS S OIV 9 PARALLEL DATA VALID NQ i U7 4 AT END OF DIGITIZING 2 0V V OIV EXT TRIG S7 3 N O 10 MS DC COUPLED S OIV REF OUTPUT COMMON 8 NO 2 0V V OIV SERIAL DATA STROBE U7 12 AT END OF DIGITIZING PULSE WIDTH 40J LS EXT TRIG S7 3 N O DC COUPLED 1 MS S OIV REF OUTPUT COMMON 5 61 ARTEKMEDIA 2012 ...

Page 104: ...5 62 0 UlO U i A 3 0 B9 74L 41 U4 7 11153 0 IT UII 0 74L 0 J _I 1 3 UB 7 11L S041 R IT 13 OCI I 10K 74LSI 7 L SI C6 1000 1 IOV Figure 5 20 Data Output Subassembly Test Points ARTEKMEDIA 2012 ...

Page 105: ... ref mecca 111 pin 2 Fig 5 21 24 0 to 26 0 Vdc Battery voltage J11 pin 3 Fig 5 21 6 3 to 6 7 Vdc Battery voltage switched 111 pin 4 II Fig 5 21 6 3 to 6 7 Vdc 22 Vdc ref mecca 111 pin 5 Fig 5 21 15 0 to 16 0 Vdc f Battery circuit bias 111 pin 6 Fig 5 21 6 3 to 6 7 Vdc Dig Com mecca bias 111 pin 7 Fig 5 21 5 5 to 5 8 Vdc Dig Common 111 pin 8 Fig 5 21 0 020 to 0 020 Vdc Battery La voltage 111 pin 9 ...

Page 106: ...STORS 04 05 COLLECTORS f 8 8 kHz 50 lS DC COUPLED S DIV REF DIGITAL COMMON 5 64 Waveforms for Table S 27 10 V V DIV BATTERY PACK RECTIFIER DRIVE CR4 5 CATHODES CRS 7 ANODES Ir _ _ 50 lS DC COUPLED S DIV REF MECCA ARTEKMEDIA 2012 ...

Page 107: ...____8 _____ 8__________ e_e_e __ _________________8 __CJ S5 2 o 0 0 o 0 0 S 2 0 0 0 0 0 0 57 1 57 2 0 0 0 E 5 0 13 c JI3 Figure 5 21 Battery Pack Subassembly Test Points ell 22 001 IOV C 2200 IOV 5 65 ARTEKMEDIA 2012 ...

Page 108: ...2002 00 Gl _ I o KI Figure 5 22 Battery Pack Subassembly Test Points 5 66 ARTEKMEDIA 2012 ...

Page 109: ...OM E51 52 11 INPUT 51 REF SW DRIVE TO E50 12 CURRENT 52 REF SW DRIVE TO ESO 13 INPUT 53 HOLD PROBE SW INPUT TO E58 ON 0 0 14 00 STROBE DRIVE DISPLAY 54 R99 15 KOHMS 55 R99 16 AC 56 R98 17 ISOLATOR OUTPUT TO E18 57 R98 18 INTEGRATOR INPUT TO E17 58 HOLD ON DATA OUTPUT PCB TO E53 19 5V REF DIG COM 59 W8 LINE OP 20 I CURRENT BAR 60 W8 LINp OP 21 DIGITAL COMMON 61 MECCA 22 TRANSFER 62 Wll BATT 23 PRIM...

Page 110: ...POWER SUPPLY VOLTAGE DEFINITIONS 2 J NO IDENTIFICATIONS 3 E NO IDENTIFICATIONS 4 TP NO IDENTIFICATIONS 5 ERRATA SHEET TO COVER ALL PREVIOUS MANUALS J 2 3 CURRENT INPUT AC DC CURRENT INPUT AC DC NON EXISTENT 4 NON EXISTENT 5 NON EXISTENT 6 NON EXISTENT 7 NON EXISTENT 8 DATA OUTPUT POWER CONN 9 INTERCONNECT TO MAIN PCB CONN 10 AC CONVERTER CONN 11 BATTERY PACK CONN 12 HOLD PROBE CONN 13 INTERCONNECT...

Page 111: ...Z D O j Z II J 0 alO J r II f 2 J1 8 1 H 17 F 161 E 1514131 D IC 121 B 11 0 A f f 0 J9 al E NOS I8 I6 I4 I 3 I 1 I2 I 9 I 7 114 5 I lZ NOTES REFERENCE DESIGNATIONS J4 J5 J6 ANDJ7ARENOLONGERUSE J9 AND J13 ARE NO LONGER JACKS THE INTER BOARD CONNECTIONS ARE HARDWIRED AS SHOWN IN INSET FIGURE A BATTERY PACK OPT 70 AND DATA OUTPUT OPT 51 CANNOT BE INSTALLED AT THE SAME TIME JUMPER BETWEEN E50 AND E51 ...

Page 112: ...c AC Converter 432083 Assembly Data Output Option 403894 Layout Data Output Cable 403914 Layout Data Output PCB 403879 Schematic Data Output Option 432085 Layout Data Output Connector 403920 Layout Battery Pack Module 403888 Layout Battery Pack PCB and Interconnection Schematic Battery Pack Main Logic PCB Interconnection Assembly Rack Mounting Option 403892 DRAWINGS Page 6 2 6 3 6 4 6 5 6 6 to 6 8...

Page 113: ...ACES NOT DING USED OH APPt ICATION BDTTOM VIEW OF CAS UNLESS OTHERWISE SPECifiED DIMENSIONS IN MILLIMETERS AND INCLUDE THICKNESS Of Pt ATlNG 920710 ABEL SERrAL NO R AR VI W DF CASE POSlTltAV FEET ON UJN TErrW I AREAS OF CASEr4I ACEq QZ0773 INPtJT L L FORWARD IDIFllflIFlI DANA IS INC TOP ASSEMBLY 4600 OO 77 D OF I I I I I I I I I I I I I I I I I ARTEKMEDIA 2012 ...

Page 114: ... 1 9 iJ W RE WUT 2 1 j HII S D TAIL C VIEW C 10387 4 REF NOTE BE gURE WHITE WIRE FROM 4C POWER CONN S ATTA TO E 3 1 BE SURE 1l 8 QS W RE FROM FUSE S ATTACH D TO FOR LINE OPERATED MM s ONLY 50000 3 03 1 50 Z 06 f 20779 Fll5fHOLD Z077 FUSE 2 5 Ht lP 45 4050 ROD T IN s I 12 D C 5OOO25 WIRE 00534TERM DET IL AI POWEr SWITCH 5DO 175 CABLEi FLAT 153 a NUT HEX d POWER 40385 A ASS 1 1_1_1 J 3 TERM 4 PlCS R...

Page 115: ... 100078C POST 453402 BRKr T T AN6 L 10 77 RILJET W078 CONN 3 PIN SDDOIoD 18G A SLI EVIAIIr AIR CEMENT C R13 TO TOP OF 5 US Nb 205 10 SCOTCH 5 C EMENT OETAIL B foD07S POST __ 410711 PCB THE GLASS 80DV OF CRI3 Ll 1USI MAKE CONTACT WITJ I METAL CAN OF GS ___ FEMALE PIN fDOOfc 5 ONN f N LE x C PIN rL L L l L L l_1r_ I5403B SPACER 0062CJ _ CONI IE TOR A f GiD 0 IFoR PI f DE 5CRIP l l JI3lsEE PAISE 5 b9...

Page 116: ...5 7 0 o 0 0 CIRCUIT 510 WIRIN 0 R30 R28 0 o 0 0 0 0 0 0 0 0 0 5 1 o 0 0 o 0 o 0 o 0 0 0 S 2 5 3 0 0 0 0 0 0 5 b LIST FOR TRl COLOR 5 L ENCzIIJ GREEN GND 2 3 8 e2 1 RPnWN 2 1 2V f L l K 23 2 3 RED 2b 3 YELLOW 27 3 ORANM 25 3 TOP COY 4fo 3 BOTTONI RE 47 3 TOP BLUE 45 3 BOTTOM BLUE 4 3 BLACK 43 3 VIOLE T 1 2 3 NEXT OWG USED ON APPlICATION 11m FHIIl _ 14ft INISH QTY REQD REVISIONS t IO 1I CLAMp CABLE ...

Page 117: ...1 SFSV 4 7 IOOpF s SEL I D c B At CONY SIC 1 I Ar CONY RlY I ENABLE 30B I 1 SW 3D8 ISO XIO SW SHUNT BB 9K eZ9 RIID RII R2 I C2 liV t 5 IV Q9 FUNCTION I t T2 7 0 0 R 7 I POLY RII 3 bM MPS A 2 I 35V 3W I lOOK 0 C R2 1 I L f0NTROL ___ R 4 N_OM _ 9zw I I I LYV B 8 3K 1_ ______ II b II ___ __1 I R 5 o o I I DC JI3 A 9 TRANSISTORS ARE 200Z00 1 RESISTOR MA 1 BI OMITTED ON lATtR PRODUCTION MODELS 7 tlDV L...

Page 118: ... 4 I I 5DO Rb9 JI2 E53 4 UIO 9 74lS00Y L 1 DPST I RIOI IK I I I I 0 2 0 PSTQ S 10 74lS00F U8 POL DR F F I JI3 I 2 49 LM324 I I Ull TRANSFER ClK 011 I K 1 2 q J elK I HI 74l7 I I I I IOW RI09 IV fiREF Go POL 1 R 8 R7 10K I 3 74174 I 6V I I I IOK 51 5V ClR L J 1 I I I I TRANSFER 1 Jill Q L M _ J L _______________ L _______________________ I I J C el I 1 1 S8 3D8 BB 3e8 AB 3 8 4 T 1 E I Qe1 IV 11 REF...

Page 119: ... I I STEP DOWN l p T oOI100I 1 I HI w m I D v 11 I 13 Y4 04 4 Ol I Q e1 O ul RI9 7 I lSI II 57 r I 5 20K J 2 Z two G lb n 1 0 b RI T3 D 5V T A N T I SIC IWT oD l n I 20K V I 2el I I Y M I I I I t L l TI DP 5V r J I l I l eLK II Q R V I 2CI RESET I 001 R2 74l7 10 U3 8 l I O ISpf 6 10 a L_____ H 30K J l Q 374LSIO I 74lSIO M 4 lD PSTa V ZI r U7 A U7 V us I J13 0 I D 1 74C04 IL II 74 04 10 II eLK I I ...

Page 120: ...crc N O 4 E 37 O o E41 I F201 I I D o 1 3 25A E33 E W5 E40 JI3 IO LOW BATT IND 9 4 I I 6mA I 9MI IIIY t Lxce S 1 PCB REVISIONS REV LTR I DESCRIPTION IRELEASED PER DRN SE H I 1 I DR I CHK I APPD I I I PROPRIETARy NOTICE g LEEJ o HfRRtl EI g ID IRlnIRI DANA LABORATORIES INC E D c B 1A THIS DOCUMENT AND THE TECHNICAL DATA HERE t ____ _____ __f t I NC LU D E TH IC KN E SS O F PLA TI NG __r r _d __ R V...

Page 121: ...NG TOLERANCES 3 MATC HI IG LEO LIG T INTE NSITy C ODE DECIMALS IANGLES I HOlE X OJO 0 30 DIAMETERS XX 02D FORMED 004 TO OTHE R Lt O IS NOT MAN D TOR I 2 ALL TRANSISTORS MPSA55 TVPE I SCHEMATIC REF 32 08 1 NOTES UNlESS OTHERWISE SPECIFIED L 111 XXX OID l 0 001 DIMENSIONS ANO TOLER NCES PER USAS YlUS 4D3 4WO D 2A I I 17TERIAL 71NISH NEXT DWG USED ON Nm FINAL ____ D Y APPLICATION QTY REQD DRAWN CHECK...

Page 122: ...f NO EI R4 E 2 R2 E3 RI E4 POL E5 DI Eb D2 E 7 D4 E8 D8 E 3 00 EI f Dp NEXT DWG USED ON APPLICATION Q1Y REQO UNLESS OTHERWISE SPECIFIED DIMENSIONS ARE IN INCHES AND INCLUDE THICKNESS OF PLATING HOLE DIAMETERS eH CO REVISIONS LTR DESCRIPTION DR CHI APPO D RELEASED PER DRN II 3 t E REVISED PER E O 8B7 f VISED P I 0 1 3 H REVISED PER E O 10220 J EO 11012 15 75 CH VJATIC DECIMALS X 030 XX 020 XXX OIO ...

Page 123: ...DOClJMENT AND THE TECHNICAL DATA HERE OftAWN ON OISCLOSEO flflE PRQPRI TARY TO DANA L I t T T__ __j J f LABORATORIES INC AND SHAll NOT WITHOUT DlClMAlS S I T U S SE O o CLlts 1 1 1 X 030 IN WHOLE OR IN PART OR U O TO SOLICIT aUOTA xx 020 F R cg P J6 sg TRH E t t t XXX O I O siirot ERi h n I t 71 LA80RATORIES INC T E INFORMATION HEREON J g t g CR ST F SEEER g r 7i h i EVALUATION AND FOR INCORPORATI...

Page 124: ...THAN DANA LABORATORIES INC THE INFORMATION HEREON HAS BEEN DEVELOPED AT PRIVATE EXPENSE AND MAYONLY BE USED FOR PURPOSESOFENGINEERING EVALUATION AND FOR INCORPORATION INTO TECHNICAL SPECIFICATIONS AND OTHER OOCU MENTS WHICH SPECIFY PROCUREMENT OF PRODUCTS FROM DANA LABORATORIES INC 4038B 4 00 NEXT OWG USED ON NEXT fIlIAl DWIl ASSY APPLICATI N QTY REQO UNLESS OTHERWISE SPECIFIED DIMENSIONS ARE IN I...

Page 125: ... q t 0 J t LL 0 0 r t n UJ II UNLESS OTHERWISE SPECIFIED DIMENSIONS IN MIlliMETERS AND INCLUDE THICKNESS OF PLATING HOlE LTR A J S t 0 N N J J t Q 4 g 0 1 DltAWN REVIS ONS DESCRIPTION R 1EASED PER DRN III 0 N N 0 0 fl o r c J N u cr 9 0 g E 5J T 4 R2 11 PL L 01 02 4 08 100 00 l TI Sv CTND 403Cj 4 CABLS ASS V COMPOfIJ NT SlOG CIRCUIT SIDE DECIMALS x 5 xx 25 t i xxx OIO DIAMETERS CH CK 10 t h i 7 t ...

Page 126: ...O i DIMENSIONS ARE IN INCHES AND INCLUDE THICKNESS OF PLATING IDIAlnlMI DANA LAIORATORIES INC M IRVINE CALIFORNIA NOTES UNLESS OTHERWISE SPECIFIED TOLERANCES DRAWN DECIMALS O OfJ XXX OlO ANGLES HOLE 0 30 DI ETERS I CH_E_CK _ _ _ _ t _ t FORMED 004 1 0 001 DESIGN MECH DIMENSIONS AND TOLERANCES NCR C BlE SSY DATA OUTPUT OPTION tdMi rl A hi n t T 1 w y iPE R U SAiS Y 14F 15iNiSii O oItW lJ Il J Z1 I ...

Page 127: ... 4caOO NEXT DWG USED ON APPlICATION 6 16 UNLESS OTHERWISE SPECIFIED DIMENSIONS ARE IN INCHES AND INCLUDE THICKNESS OF PlAnNG I B Ii EV LTR DESCRlPI lON lit QtK APPO I A IIELEAIED P III DItH J JJ E B REVISED PER e O fJ 1007 F C V S D P R 00 1019 5 D EOI0956 I I I I I I I I I I I I I I IOIFllnIFlI DANA L IS INC I PCB ASSY DATA OUTPUT OPT I 4bOOA D2 q 403879 I ARTEKMEDIA 2012 ...

Page 128: ... O K 1111111111 I 1111 1111 I II I tf tl K L L t M __ r T N5FER 00 V __ 1 1 I EIIHTI GROUND I 2 DATA ffitINSFER G I DATA 5TP OBE l ADDRESS t I l 1 ADDRE55 B L ______ lu I 1 f I l U A S T R O B E C D H UNLESS OTHERWISE SPECIFIED I DIMENSIONS ARE IN INCHES AND INCLUDE THICKNESS OF PLATING FUNCTION CODE FUNCTION FI F l F4 Fa DEC DCY 0 0 0 0 DCV 0 0 0 0 I ACV I I 0 a 3 DCI I a I a 4 DCI 0 0 I a 5 ACl ...

Page 129: ... TO CONNEC TOR PIN USINC AMP TOLERANCES DECIMALS ANGLES HOLE lAND TOOL NO ctOZ1 2 1 NDT SUPPLIED WITH KIT X 03O o 30 DIAMETERS t C_HE_CK t _ _ _ _ t _ I SOLDER WIRE TO CONNECTOR PIN bOOeOq T BS MUST gro F MJD DESIGN DRAWN BE EITHER 5TRAIGI IT UP OR CRIMPED OVER BEFORE DIMENSIONS AND TOLERANCES g INSERTING INTO CONNECTOR WIRE NOT SUPPLIED PER USAS YlUS PROJ SHIPPING KIT Dt T OUTPUT 4 000 403 120 RE...

Page 130: ... REVISIONS LTR DESCRIPTION It RElEASm PER DRN 1 3 n B R V15ED PER E O 98 1 D E O 10948 BLK 403BE ll PCI ASSY l Ob4 BATTER 1 2 V 5 REQ o 4 l39l G SSIS SEE WIRING D 6RPo M 524 99 WIRE 24GA wHT SEE DETAIL TYP FOR tiLL mRIE S 4 S 5 EIO 403BB Ell PCB 83 1 2 1 1 BLK WIRlN6 DIAGR M VIEw t FOLD INSUL TOR i S 5 10WN 45 0 11 UNLESS OTHERWISE SPECIFIED DIMENSIONS ARE IN INCHES AND 101 INCLUDE THICKNESS OF P ...

Page 131: ...B BETWE EN Q COI LE CTOR AND SIDE OF C Dt De 7 0 2 TI 6 0 3 4 5 0 0 VIEW t OPTlONAL INST lLATlON bO024S JUMPER S INST LLED ON 6onoM SIDE OF MAIN LOE le PC B IITHRU II PI DDDDD PART OF MAIN PCB ASSY 600380 P8 110 8l U 13l U Schematic Battery Pack Main Logic PCB Interconnection 6 20 I I I I I I I I REMoVE I JUMP R W I I I I I I I I I I ARTEKMEDIA 2012 ...

Page 132: ... AND PI4 THIS DOCUMENT AND THE TECHNICAL DATA HERE INCLUDE IMlCKNESS OF PLATING IRVINE CALIFORNIA A PRODUCTION WlODELS t22 V 7V 15V I lV IDIRlnIRI I ON DISCLOSED ARE PROPRIETARY TO DANA DRAWN Rkh Ma j5 2 18 77 SCHEMATIC 4600 DMM LABORATORIES INC AND SHALL NOT WITHOUT RE SI TOR MAY BE OMITTED ON lA1U mnUCnOfJ MODELS 4 TRANSISTORS ARE 200100 3 0100E 5 ARE IN91b 1 CAPAC ITORS A E IN IJF I RE SISTORS ...

Page 133: ...RIGHT J jAND vWUNTING SHOWN UNLESS OTHERWISE SPECIFIED OIMENSIONS ARE IN INCHES ANO INCLUOE THICKNESS OF PLATING DECIMALS X Q30 XX 020 XXX OlO REVISIONS l TR DESCRIPTION IOIRlnlRI DANA LABORATORiES IRVINE CALIFORNIA r ACK 1Y10UNTIN OPTION 4foOO INC DWG NO MATE 7FINI it r i 403892 SHE T I OF 4 OD USED ON NEXT flNIL OWG ASSY NEXT DWG APPLICATION QTY REQD 6 22 I I I I I I I I I I I I I I I I I I I AR...

Page 134: ...d semiconductors For some of these standard commercial parts will serve as satisfactory replacements These Dana parts are identified in table 7 1 along with the commercial eqUivalent Table 7 1 Semiconductor Type Equivalent 018 Diode Fairchild IN916B Table 7 2 List of Suppliers FSC NAME FSC NAME 011 1 ALLEN BRADLEY CO 05391 UNION CARBIDE CORP MI LWAUKEE WISCONSI N Materials Systems Division CLEVELA...

Page 135: ...A FE SPRINGS CALIFORNIA GOULD NATIONAL BATTERIES 75915 LlTTELFUSE INC 31741 DES PLAINES ILLINOIS ST PAUL MINNESOTA 32293 INTERSI L INC 80131 ELECTRONICS INDUSTRIES ASSOC CUPERTINO CALIFORNIA WASHINGTON D C 32997 BOURNS 80294 BOURNS INC Trimpot Products Division RIVERSIDE CALIFORNIA RIVERSIDE CALIFORNIA 81349 MILITARY SPECIFICATION 34553 AMPER EX MEPCO E LECTRA Component 0 ivision HAUPPAUGE NEW YOR...

Page 136: ...ODULE REF DANA MANU DES PIN DESCRIPTION FSC PIN F101 920770 FUSE FAST BLOW 2 5 AMP 250V 75915 21202 5 F201 920769 FUSE FAST BLOW 25 AMP 250 V 75915 212 250 1201 600619 CONNECTOR RECEPTACLE 82389 EAC 301 7 3 ARTEKMEDIA 2012 ...

Page 137: ...12 CAP ELECT 470MFD 40V 34553 ET471X040A02 C18 110112 CAP ELECT 470MFD 40V 34553 ET471X040A02 C19 100071 CAP CERAM 001 MFD 1000V 20 56289 C023B 102E102M C20 120284 CAP MYLAR 068MFD 100V 20 73445 C281AH A68K C21 120342 CAP MYLAR 33 MFD 1 KV 10 27556 ZA2334K C22 110143 CAP TANTA 1 MFD 35 V 20 05397 T368A105M035AS C23 100071 CAP CERAM 001 MFD 1000 V 20 56289 C023B102E102M C24 100071 CAP CERAM 001 MFD...

Page 138: ...93 211083 CR26 211083 DIODE SILICO 018 21793 211083 CR27 211083 DIODE SILICO 018 21793 211083 CR28 211083 DIODE SILICO 018 21793 211083 K1 310128 RELAY 2 FORM C 1 KV 5VCOIL 21793 310128 K2 310125 RELAY REED 1 FORM A 5V 21793 310125 K3 310125 RELAY REED 1 FORM A 5V 21793 310125 K4 310125 RELAY REED 1 FORM A 5 21793 310125 K5 310125 RELAY REED 1 FORM A 5V 21793 310125 K6 310125 RELAY REED 1 FORM A 5...

Page 139: ... OHM 05 50PPM 22045 J 11O R19 020691 RES WW 90 OHM 05 50PPM 22045 J 11O R20 000471 RES CARBON 470 OHM 5 1 4W 81349 RC07GF471J R21 040197 POT CERMET 10K 20 11237 360TI03B R22 020692 RES WW 9 0225 OHM 25 1 2W 22045 M 16 R23 000470 RES CARBON 47 OHM 5 1 4W 81349 RC07GF470J R24 040196 POT CERMET 1 K 20 11237 360TI02B R2 020671 RES WW 9 OHM FSV 25 3 W 21793 020671 R26 001878 RES CARBON 4 7 OHM 5 1 4W 8...

Page 140: ...254 POT CERMET 2M 20 5 W 73138 72PX2M R60 001737 RES CARBON FSV 5 1 4W 21793 001737 R61 000302 RES CARBON 3K 5 1 4W 81349 RC07GF302J R62 000302 RES CARBON 3K 5 1 4W 81349 RC07GF302J R63 000912 RES CARBON 9 1 K 5 1 4W 81349 RC07GF912J R64 000911 RES CARBON 910 OHM 5 1 4W 81349 RC07GF911J R65 403891 ZENER KIT 21793 403891 R66 010987 RES METAL SET POSITIVE REF 21793 010987 R67 040187 POT CERMET 500 O...

Page 141: ...RN55C2490F R101 010600 RES METAL 249 OHM 1 l lOW 81349 RN55C2490F RI02 000203 RES CARBON 20K 5 1 4W 81349 RC07GF203J R103 000203 RES CARBON 20K 5 1 4W 81349 RC07GF203J RI04 001737 RES CARBON FSV 5 1 4W 21793 001737 R105 001737 RES CARBON FSV 5 1 4W 21793 001737 RI06 000203 RES CARBON 20K 5 1 4W 81349 RC07GF203J R107 000203 RES CARBON 20K 5 1 4W 81349 RC07GF203J R108 000103 RES CARBON 10K 5 1 4W 81...

Page 142: ...IRCUIT 21793 230247 Ul6 230247 INTEGRATED CIRCUIT 21793 230247 VRI 220007 DIODE SILICO ZENER 81349 IN751A VR2 220007 DIODE SILICO ZENER 81349 IN751A VR3 220007 DIODE SILICO ZENER 81349 IN751A VR4 220004 DIODE SILICO ZENER 81349 IN961B VR5 220004 DIODE SILICO ZENER 81349 IN961B VR6 220031 DIODE SILICO ZENER 3 3 V 04713 1 4M3 3AZ5 VR7 220007 DIODE SILICO ZENER 81349 IN751A VR8 403891 ZENER KIT 21793...

Page 143: ...ETI0IX025A5 C13 100017 CAP CERAM 01 MFD 100V 20 56289 C023BI0IFI03M C14 110043 CAP ELECT 22MFD 25 V 34553 ET220X025A3 CIS 111148 CAP ELECT 100MFD 25V 34553 ETlOIX025A5 C16 120298 CAP MYLAR 1 0MFD 100V 20 73445 C281AH AIM C17 120298 CAP MYLAR 1 0MFD 100 V 20 73445 C281AH AIM C18 100100 CAP CERAM FSV 21793 100100 C19 100017 CAP CERAM 01 MFD 100V 20 56289 C023BI01FI03M C20 110151 CAP TANTA lOMFD 35 V...

Page 144: ...04 RES CARBON lOOK 5 1 4W 81349 RC07GF1 O4J R12 000104 RES CARBON lOOK 5 1 4W 81349 RC07GF104J R13 000162 RES CARBON 1 6 K 5 1 4W 81349 RC07GF162J R14 000101 RES CARBON 100 OHM 5 1 4W 81349 RC07GFlOlJ R15 000133 RES CARBON 13K 5 1 4W 81349 RC07GF133J R16 000133 RES CARBON 13 K 5 1 4W 81349 RC07GF133J R17 000162 RES CARBON 1 6K 5 1 4W 81349 RC07GF162J R18 000101 RES CARBON 100 OHM 5 1 4W 81349 RC07...

Page 145: ...5100HM 5 1 4W 81349 RC07GF51lJ R5 000511 RES CARBON 5100HM 5 1 4W 81349 RC07GF51lJ R6 000111 RES CARBON 110 OHM 5 1 4W 81349 RC07GF11lJ R7 000111 RES CA BON 110 OHM 5 1 4W 81349 RC07GF11lJ R8 000111 RES CARBON lIOOHM 5 1 4W 81349 RC07GF11lJ R9 000111 RES CARBON 1IOOHM 5 1 4W 81349 RC07GF11lJ RIO 000111 RES CARBON 110 OHM 5 1 4W 81349 RC07GF11lJ Rll 000111 RES CARBON 110 OHM 5 1 4W 81349 RC07GF11lJ...

Page 146: ...ATOR LOGIC DRIVE 21793 250005 OCI 6 250005 OPTO ISOLATOR LOGIC DRIVE 21793 250005 Ql 200200 TRANS NPN 21793 200200 Q2 200200 TRANS NPN 21793 200200 Q3 200166 TRANS NPN 04713 MPSU05 Q4 200200 TRANS NPN 21793 200200 Rl 000331 RES CARBON 330 OHM 5 1 4W 81349 RC07GF331J R2 000331 RES CARBON 330 OHM 5 1 4W 81349 RC07GF331J R3 000331 RES CARBON 330 OHM 5 1 4W 81349 RC07GF331J R4 000331 RES CARBON 330 OH...

Page 147: ...49 RC07GF222J VI 230121 INTEGRATED CIRCUIT 14 PIN 01295 SN74L90N U2 230076 INTEGRATED CIRCUIT PLASTIC 07263 74LOO U3 230234 INTEGRATED CIRCUIT 14 DIP HEX INVERTER 01295 SN74LS04N U4 230239 INTEGRATED CIRCUIT 01295 SN74153 U5 230193 INTEGRATED CIRCUIT 14 DIP NAND GATE 01295 SN74LSOON U6 230239 INTEGRATED CIRCUIT 01295 SN74153 U7 230237 INTEGRATED CIRCUIT PLASTIC 01295 SN74LS123N U8 230234 INTEGRATE...

Page 148: ...LP W2 600245 JUMPER INSULATED L 2007 1LP W3 600245 JUMPER INSULATED L 2007 1LP W4 600245 JUMPER INSULATED L 2007 1LP W5 600245 JUMPER INSULATED L 2007 1LP 403888 Assy MODULE BATTERY PACK REF DANA MANU DES PIN DESCRIPTION FSC PIN Al 403887 PCB ASSY BATTERY PACK OPTION 21793 403887 Bl to B5 920643 BATTERY 5 Rechargeable 1 2 V 31741 4 0SCL Size D 7 15 ARTEKMEDIA 2012 ...

Page 149: ...R 2 Ql 200200 TRANS NPN 21793 200200 Q2 200200 TRANS NPN 21793 200200 Q3 200088 TRANS SILICO PNP 80131 2N4248 Q4 200166 TRANS NPN 04713 MPSU05 Q5 200166 TRANS NPN 04713 MPSU05 Q6 200115 TRANS POWER PNP 04713 MPSU51 Rl 000751 RES CARBON 750 OHM 5 1 4W 81349 RC07GF751J R2 000102 RES CARBON lK 5 1 4W 81349 RC07GFI02J R3 000512 RES CARBON 5 1 K 5 1 4W 81349 RC07GF512J R4 000102 RES CARBON lK 5 1 4W 81...

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