Milnor 42032 User manual
Published Manual Number/ECN: ME6HEXT1CE/2009145A
• Publishing System: TPAS
• Access date: 4/15/2009
• Document ECN's: Latest Available
Schematic/Electrical Parts—
42032, 48040M7V, M9V
MMV4232C & MXV4232C
Centrifugal Extractor
Mark 5 Controls
PELLERIN MILNOR CORPORATION POST OFFICE BOX 400, KENNER, LOUISIANA 70063-0400, U.S.A.
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Table of Contents
for ME6HEXT1CE/2009145A
42032, 48040M7V, M9V MMV4232C & MXV4232C Centrifugal Extractor Mark 5 Controls
Page Description Document/ECN
1 Component Parts List W6EX5PL/2008146N
5 Limited Standard Warranty BMP720097/2008272A
6 How to Get the Necessary Repair Components BIUUUD19/20081231
7 Special Load Interface Requirements for the
Milnor Centrifugal Extractor BICXUI01/20021226
10 Milnor Allied Interface Specifications and Signals,
Centrifugal Extractor BICALC02/20031016
20 How to Use Milnor® Electrical Schematic Diagrams BIUUUK01/20080311
32 Sample Schematic BMP010012/2001503N
34 Wiring Safety Fence Gate Interlocks BISUUI02/20070507
36 Customer Safety Gate Interlock W6SYSSG/2007192B
38 3 Phase Motor Connection Diagram BMP850029/99362B
39 3P Motor Diagram-Multivolt W80008/2001253A
40 Control Box Layouts Sheet 1 W6EX5TG1/2009145B
42 Control Box Layouts Sheet 2 W6EX5TG2/2009145B
44 Board to Board Wiring W6EX5BWA/2008046B
46 Electronic Balance W6EX5EC/2007122B
48 Return Pump Interface Wiring W6EX5EP/2001092B
50 Electrical Valves W6EX5EV/2003425B
52 Hydraulic Controls W6EX5HYP/2005112B
54 Microprocessor Inputs W6EX5IA/2005112B
56 Dry Contact Data Pass I/O #2 W6EX5IDP2/2001092B
58 Dry Contact Data Pass I/O #3 W6EX5IDP3/2002222B
60 Microprocessor Keypad W6EX5KP/2000203B
62 Drive Motor Contactors W6EX5MCA/2005112B
64 600 to 480 Volt 3Ph Step Down Transformers W6EX5MT6/2001092B
66 Drive Motor Connections W6EX5MTA/2000203B
68 Dry Contact Data Pass Output Bd #2 W6EX5ODP/2001092B
70 Source to 110/120V Control Circuit W6EX5PS/2000203B
72 Start Circuit W6EX5S+/2007192B
74 Microprocessor Display W6EX5SD/2000203B
76 Variable Speed Inverter W6EX5VPA/2005115B
78 High Volt Braking Modules W6EX5VPBR/2009145B
80 Low Volt Braking Modules W6EX5VPBS/2009145B
C O M P O N E N T P A R T S L I S T W6EX5PL/2008146N
COMPONENT FUNCTION OF WHERE TO FIND
NUMBER THIS COMPONENT THIS COMPONENT MILNOR P/N DESCRIPTION LOCATION
>>>CONTROL BOX LAYOUTS
001 LAYOUT-INVERTER CONTROL BOX W6EX5TG1 B2T2000001 EXTRACTOR INVERTER BOX SEE FUNCTION
002 LAYOUT-VALVE SET M#V W6EX5TG1 BTAG92069 EXTRACTOR VALVE SET BOX <> SEE FUNCTION
003 LAYOUT-LOW VOLTAGE CONTROL BOX W6EX5TG2 B2T2000010 M7/9V LOW VOLTAGE C-BOX SEE FUNCTION
004 LAYOUT-CONNECTION BOX RIGHT W6EX5TG2 B2T2000009 1MTR EXTRACTOR CONN RT SEE FUNCTION
005 LAYOUT-DYNAMIC BRAKE RESISTOR BOX W6EX5TG2 B2T2003017 TAG:M7/9 EXTRACTOR RESISTOR BOX SEE FUNCTION
A>>>ACCELEROMETER
ACBA ACCELEROMETER-BALANCE W6F3SEC EACCLRM5 ASSY:ACCEL 1-5G ADXL 105+TEST DOOR LATCH
BA >>PRINTED CIRCUIT BOARDS
BBB-1 BOARD-BATTERY BACKUP BOARD W6EX5BWA 08BSBB1T BOARD: SER BATT BACKUP-TEST PROCESSOR BX
BBAD-1 BOARD- A TO D CONVERTER W6EX5EC 08BSBADCTE SR BALANCE A-D BD EXTACTR-TEST CONTROL BOX
BDVFD BOARD-SERIAL DISPLAY W6EX5SD 08BSEVFD5V BD:SER VFD.2LINE-19200B-TEST SWITCH PANEL
BIO-1 BOARD-8-OUTPUT, 16-INPUT BOARD 1 W6EX5BWA 08BS816CT SERIAL 8OUT-16INPUT-TESTED LOW VOLT BOX
BIO-2 BOARD-8-OUTPUT, 16-INPUT BOARD 2 W6EX5IDP2 08BS816CT SERIAL 8OUT-16INPUT-TESTED LOW VOLT BOX
BIO-3 BOARD-8-OUTPUT, 16-INPUT BOARD 3 W6EX5IDP3 08BS816CT SERIAL 8OUT-16INPUT-TESTED LOW VOLT BOX
BIO-4 BOARD-8-OUTPUT, 16-INPUT BOARD 4 W6EX5BWA O8BS816CHT BD 8OUT-16IN HIGH SPD->TESTD LOW VOLT BOX
BO24-1 BOARD-24-OUTPUT BOARD W6EX5BWA 08BSO24AT BD:SERIAL 24 OUTPUT->TEST LOW VOLT BOX
BO24-2 BOARD-24-OUTPUT BOARD W6EX5OPA 08BSO24AT BD:SERIAL 24 OUTPUT->TEST LOW VOLT BOX
BPB BOARD-PROCESSOR BOARD W6EX5BWA 08BSPE2T 186 PROC BD+FP->TEST PROCESSOR BX
BRS1 BOARD-SPEED SENSING W6EX5BWA 08BNDSR1T BD:EXTRACTOR ROTATION->TEST LOW VOLT BOX
CP >>PHOTOEYES
CPCBM PHOTOEYE-BELT B LOAD END EYE BL0CK W6EX5IA 09RPE004 SENSOR DARK OPERATE AC N/O-OUT BELT B SIDE
CPCCR PHOTOEYE-RECEIVER LOAD CHUTE W6EX5S+ 09RPE010R PHOTOEYE RECEIVER AC ON LD CHUTE
CPCCS PHOTOEYE-SENDER LOAD CHUTE W6EX5S+ 09RPE010E P.E. EMITTER AC #SM303E W/30" ON LD CHUTE
CPCPL PHOTOEYE-BELT B IS LOADED W6EX5IA 09RPE004 SENSOR DARK OPERATE AC N/O-OUT BELT B SIDE
CPHTGC PHOTOEYE-BELT A HAS GOODS W6EX5HYP 09RPE004 SENSOR DARK OPERATE AC N/O-OUT BELT A SIDE
CPHTGCA PHOTOEYE-BELT A HAS GOODS 2ND EYE W6EX5HYP 09RPE004 SENSOR DARK OPERATE AC N/O-OUT BELT A SIDE
CPPSP PHOTOEYE-SPEED W6EX5BWA 09RPE013Q SENSOR E-Z BEAM QUICK CONN DC DRIVE PULLEY
CR >>RELAY-PILOT OR CONTROL
CRBR RELAY-DYNAMIC BRAKE W6EX5EV 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CRCBM RELAY-BELT B LOAD END EYE BLOCKED W6EX5IA 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CRCCR RELAY-LOAD CHUTE BLOCKED W6EX5S+ 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CRCU RELAY-CONVEYOR SIDE FULL UP W6EX5HYP 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
Page 1 of 4
1
C O M P O N E N T P A R T S L I S T W6EX5PL/2008146N
COMPONENT FUNCTION OF WHERE TO FIND
NUMBER THIS COMPONENT THIS COMPONENT MILNOR P/N DESCRIPTION LOCATION
CRHTD RELAY-HYDRAULIC TILT DOWN W6EX5HYP 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CRHTG RELAY-BELT A HAS GOODS W6EX5HYP 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CRHTGA RELAY-BELT A HAS GOODS 2ND EYE W6EX5HYP 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CROL RELAY:BRAKING OVERLOAD/HEAT SENSOR W6EX5VPBR 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CROL RELAY-BRAKING OVERLOAD/HEAT SENSOR W6EX5VPBS 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CRS+ RELAY-3-WIRE W6EX5S+ 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CRWRD RELAY-REAR IS DOWN W6EX5S+ 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CRWRT RELAY-REAR IS AT INTERMED. POSIT. W6EX5HYP 09C024D37 4PDT "KH" 110/120V LOW VOLT BOX
CS >>CONTACTOR-MOTOR STARTER
CS1 CONTACTOR-INVERTER FAN W6EX5MCA 09MC04B337 12A CP CON. NR. 120V5/6 IEC HIGH VOLT BOX
CSBL CONTACTOR-CONVEYOR UNDER EXT W6EX5MCA 09MC04B337 12A CP CON. NR. 120V5/6 IEC HIGH VOLT BOX
CSBL2 CONTACTOR-CONVEYOR OUTSIDE EXT. W6EX5MCA 09MC04B337 12A CP CON. NR. 120V5/6 IEC HIGH VOLT BOX
CSERP CONTACTOR-EXT.RETURN PUMP CNTCT W6EX5EP 09MC04B337 12A CP CON. NR. 120V5/6 IEC HIGH VOLT BOX
CSHYP CONTACTOR-HYDRAULIC PUMP MOTOR W6EX5HYP 09MC04B337 12A CP CON. NR. 120V5/6 IEC HIGH VOLT BOX
EB >>BUZZER OR AUDIBLE SIGNAL
EBSG BUZZER-SIGNAL W6EX5S+ 09H015 BUZZ.115V W/6-32 CTR+6"LEADS LOW VOLT BOX
EL >>LIGHT PILOT OR INDICATOR
ELERP LIGHT-EXT. RETURN PUMP RUNNING W6EX5EP 09J060A37 LAMP 1/2" AMB 125V IDI 1050QC3 SWITCH PANEL
ELETT LIGHT-EXT. RETURN PMP DID NOT RUN W6EX5EP 09J060A37 LAMP 1/2" AMB 125V IDI 1050QC3 SWITCH PANEL
ELSG LIGHT-SIGNAL W6EX5S+ 09J060WH37 LAMP 1/2" WHITE 120V TAB LOW VOLT BOX
ELSGR LIGHT-FLASHING LIGHT W6EX5S+ 09H025V37 BEACON ROT.120V 5.5"DIA AMB #MV110 LOW VOLT BOX
EM >>SWITCH ASSY EMERGENCY STOP
EMSPA SWITCH-EMERGENCY STOP SWITCH PNL W6EX5S+ 09N505 SW ASSY EMER STOP MOUNTONMACH
EMSPB SWITCH-EMERGENCY STOP LEFT W6EX5S+ 09N505 SW ASSY EMER STOP MOUNTONMACH
EMSPC SWITHC-EMERGENCY STOP RIGHT W6EX5S+ 09N505 SW ASSY EMER STOP MOUNTONMACH
ES >>POWER SUPPLY TESTED
ESPS POWER SUPPLY-MICPROCESSOR W6EX5BWA 08PSS3401T 40 WATT POWER SUPPLY TESTED LOW VOLT BOX
EX >>TRANSFORMERS
EX37-1 TRANSFORMER-208/240VAC TO 120VAC W6EX5PS 09U249AA37 XFMR 200-240 PRI/120SEC 250VA HIGH VOLT BOX
EX37-2 TRANSFORMER-380/480VAC TO 120VAC W6EX5PS 09U200AAB XFMR 380-480/240-120V 250VA HIGH VOLT BOX
EX37-3 TRANSFORMER-600VAC TO 120VAC W6EX5PS 09U251AB37 XFMR 600VPRI/120VSC-250VA 3%REG HIGH VOLT BOX
F>>FAN
FAN1 FAN-INVERTER COOLING W6EX5MCA 13AF100A37 FAN 92CFM115V60 NEWARK#90F6921 HIGH VOLT BOX
Page 2 of 4
2
C O M P O N E N T P A R T S L I S T W6EX5PL/2008146N
COMPONENT FUNCTION OF WHERE TO FIND
NUMBER THIS COMPONENT THIS COMPONENT MILNOR P/N DESCRIPTION LOCATION
EMCFB FAN-RESISTOR BOX W6EX5VPBR 13AF235A37 FAN 235CFM 115V 50/60 RESISTOR BOX
EMCFB FAN-RESISTOR BOX W6EX5VPBS 13AF235A37 FAN 235CFM 115V 50/60 RESISTOR BOX
KB >>KEYBOARD-ELECTRONIC
KBM KEYPAD-MICROPROCESSOR W6EX5KP 08MD5X6WE KEYPAD:5X6MATRIX WASHER-EXT LOW VOLT BOX
MT >>MOTORS
MTD MOTOR-DRIVE >250 VAC W6EX5VPA 39G840AAHD 20HP 4P 208/240/60 ODP INV TOP OF MACH
MTD MOTOR-DRIVE <250VAC W6EX5VPA 39G840AATD 20HP 4P 200/400/60 ODP INV TOP OF MACH
MV >>VARIABLE SPEED INVERTER
MVD INVERTER-DRIVE MOTOR->250VAC W6EX5VPA 09MV068A74 VARSPEED 68 AMPS 230V HIGH VOLT BOX
MVD INVERTER-DRIVE MOTOR-<250VAC W6EX5VPA 09MV034A96 VARSPEED 34 AMPS 460V HIGH VOLT BOX
MVDR BRAKING MODULE-DRIVE MOTOR->250V W6EX5VPA 09MVBT25L BRAKING MODULE FOR INVERTERS HIGH VOLT BOX
PS24 POWER SUPPLY-MICPROCESSOR W6EX5BWA 08PSL1B224 PWR SUP 100-240VAC TO 24VDC LOW VOLT BOX
PX >>PROXIMITY SWITCH
PXCD PROX SW-CONVEYOR SIDE IS DOWN W6EX5IA 09RPS30ADS PRXSW QK CONN 30M NO-DC SHLD CONVEYOR
PXDD PROX SW-LOAD DOOR IS DOWN W6EX5IA 09RPS30ADS PRXSW QK CONN 30M NO-DC SHLD LOAD DOOR
PXDU PROX SW-LOAD DOOR IS UP W6EX5IA 09RPS30ADS PRXSW QK CONN 30M NO-DC SHLD LOAD DOOR
PXLCD PROX SW-LOAD CHUTE IS DOWN W6EX5IA 09RPS30ADS PRXSW QK CONN 30M NO-DC SHLD LOAD CHUTE
PXLCU PROX SW-LOAD CHUTE IS UP W6EX5IA 09RPS30ADS PRXSW QK CONN 30M NO-DC SHLD LOAD CHUTE
PXRDI PROX SW-REAR IS AT INTERMEDIATE W6EX5HYP 09RPS30AAS PRXSW QK CONN 30M NO-AC SHLD SIDE OF MACH
PXSFU PROX SW-CONVEYOR SIDE UP W6EX5HYP 09RPS30AAS PRXSW QK CONN 30M NO-AC SHLD CONVEYOR SDE
SH >>SWITCH-HAND OPERATED
SHBL1 SWITCH-MOVE CONV.FRWRD UNDER EX W6EX5MCA 09N405M210 SWASS M2W 1NO SWITCH PANEL
SHBL2 SWITCH-MOVE CONV.FRWRD OUTSIDE EX W6EX5MCA 09N405M210 SWASS M2W 1NO SWITCH PANEL
SHERP SWITCH-EXTRACTOR RETURN PUMP W6EX5EP 09N405M210 SWASS M2W 1NO SWITCH PANEL
SHMD SWITCH-MILDATA W6EX5IA 09N405M210 SWASS M2W 1NO SWITCH PANEL
SHS+ SWITCH-START W6EX5S+ 09N405PB10 SWASS PBBK 1NO SWITCH PANEL
SHSG SWITCH-SIGNAL CANCEL W6EX5IA 09N405PY10 SWASS PB YELLOW 1NO SWITCH PANEL
SHSMA SWITCH-MASTER W6EX5S+ 09N405M220 SWASS M2W 2NO SWITCH PANEL
SHSO SWITCH-STOP W6EX5S+ 09N404PR01 SWASS PBRD 1NC SWITCH PANEL
SK >>SWITCH-KEY OPERATED
SKCP SWITCH-ACCESS PANEL OVERRIDE W6EX5S+ 09N127C KEYSW SPST 7A120VAC SCREW TER SIDE OF MACH
SKPR SWITCH-PROGRAM W6EX5IA 09N127C KEYSW SPST 7A120VAC SCREW TER SWITCH PANEL
SL >>SWITCH-LEVEL
Page 3 of 4
3
C O M P O N E N T P A R T S L I S T W6EX5PL/2008146N
COMPONENT FUNCTION OF WHERE TO FIND
NUMBER THIS COMPONENT THIS COMPONENT MILNOR P/N DESCRIPTION LOCATION
SLEPH SWITCH-EXT. PUMP HIGH LEVEL SWITCH W6EX5EP 09RM01412S CAPSW 12" ROTARY ACTUATE SILVE SWITCH PANEL
SLEPL SWITCH-EXT. PUMP LOW LEVEL SWITCH W6EX5EP 09RM01412S CAPSW 12" ROTARY ACTUATE SILVE SWITCH PANEL
SM >>SWITCH-MECHANICAL
SMCP# SWITCH-ACCESS PANEL W6EX5S+ 09RM01418G CAPSW 18' ROTARY ACTUATE GOLD MOUNTONMACH
SMERB SWITCH-MACHINE EXCURSION W6EX5IA 09R008A MICSW SPDT BZE6-2RN183 MOUNTONMACH
SMPCL SWITCH-PULL CORD LEFT W6EX5S+ 09R014A MINI-SW SPDT STAKON #V15G1C26 MOUNTONMACH
SMPCR SWITCH-PULL CORD RIGHT W6EX5S+ 09R014A MINI-SW SPDT STAKON #V15G1C26 MOUNTONMACH
SMRD SWITCH-REAR IS DOWN W6EX5S+ 09RM01412S CAPSW 12" ROTARY ACTUATE SILVER RIGHT SIDE
SMRU SWITCH-REAR IS FULL UP W6EX5IA 09RM01412S CAPSW 12" ROTARY ACTUATE SILVER LEFT SIDE TOP
SP >>SWITCH-PRESSURE
SPBR SWITCH-BRAKE W6EX5IA 09N082A PRESSW NASON CLOSE @ 62LB. AIR VALVE BOX
VE >>VALVE-ELECTRIC
VECSD VALVE-CONVEYOR SIDE DOWN W6EX5HYP 09R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
VEDLG VALVE-DEFLECT LOAD GOODS W6EX5HYP 09R302B37 1/8" AIRPILOT 3W NO 120V50/60 AIR VALVE BOX
VEDO VALVE-OPEN LOAD DOOR W6EX5EV 09R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
VEDP VALVE-CLOSE LOAD DOOR W6EX5EV 09R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
VEFDD VALVE-FLAG DOWN DISCHARGE W6EX5EV 09R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
VEFDL VALVE-FLAG DOWN LOAD W6EX5EV 09R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
VEHTD VALVE-HYDRAULIC TILT DOWN W6EX5HYP 96RH707E37 VALVE MANIFOLD BLOCK ASSY HYDRAULIC UNIT
VEHTU VALVE-HYDRAULIC TILT UP W6EX5HYP 96RH707E37 VALVE MANIFOLD BLOCK ASSY HYDRAULIC UNIT
VELC VALVE-LOWER CHUTE W6EX5EV 96R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
VELD VALVE-LOWER CHUTE W6EX5EV 96R302B37 1/8" AIRPILOT 3W NO 120V50/60 AIR VALVE BOX
VESDS VALVE-DEFLATE SEAL W6EX5EV 96R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
VESIS VALVE-INFLATE SEAL W6EX5EV 96R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
VEWBR VALVE-BRAKE W6EX5EV 96R301B37 1/8" AIRPILOT 3W NC 120V50/60 AIR VALVE BOX
Page 4 of 4
4
PELLERIN MILNOR CORPORATION
LIMITED STANDARD WARRANTY
We warrant to the original purchaser that MILNOR machines including electronic
hardware/software (hereafter referred to as “equipment”), will be free from defects in material and
workmanship for a period of one year from the date of shipment (unless the time period is specifically
extended for certain parts pursuant to a specific MILNOR published extended warranty) from our
factory with no operating hour limitation. This warranty is contingent upon the equipment being
installed, operated and serviced as specified in the operating manual supplied with the equipment,
and operated under normal conditions by competent operators.
Providing we receive written notification of a warranted defect within 30 days of its discovery, we
will at our option repair or replace the defective part or parts, FOB our factory. We retain the right to
require inspection of the parts claimed defective in our factory prior to repairing or replacing same.
We will not be responsible, or in any way liable, for unauthorized repairs or service to our equipment,
and this warranty shall be void if the equipment is tampered with, modified, or abused, used for
purposes not intended in the design and construction of the machine, or is repaired or altered in any
way without MILNOR's written consent.
Parts damaged by exposure to weather, to aggressive water, or to chemical attack are not covered by
this warranty. For parts which require routine replacement due to normal wear such as gaskets,
contact points, brake and clutch linings, belts, hoses, and similar parts the warranty time period is 90
days.
We reserve the right to make changes in the design and/or construction of our equipment (including
purchased components) without obligation to change any equipment previously supplied.
ANY SALE OR FURNISHING OF ANY EQUIPMENT BY MILNOR IS MADE ONLY UPON
THE EXPRESS UNDERSTANDING THAT MILNOR MAKES NO EXPRESSED OR IMPLIED
WARRANTIES OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR USE OR
PURPOSE
. MILNOR WILL NOT BE RESPONSIBLE FOR ANY COSTS OR
DAMAGES ACTUALLY INCURRED OR REQUIRED AS A RESULT OF: THE FAILURE OF
ANY OTHER PERSON OR ENTITY TO PERFORM ITS RESPONSIBILITIES, FIRE OR
OTHER HAZARD, ACCIDENT, IMPROPER STORAGE, MIS-USE, NEGLECT, POWER OR
ENVIRONMENTAL CONTROL MALFUNCTIONS, DAMAGE FROM LIQUIDS, OR ANY
OTHER CAUSE BEYOND THE NORMAL RANGE OF USE. REGARDLESS OF HOW
CAUSED, IN NO EVENT SHALL MILNOR BE LIABLE FOR SPECIAL, INDIRECT,
PUNITIVE, LIQUIDATED, OR CONSEQUENTIAL COSTS OR DAMAGES, OR ANY COSTS
OR DAMAGES WHATSOEVER WHICH EXCEED THE PRICE PAID TO MILNOR FOR THE
EQUIPMENT IT SELLS OR FURNISHES.
THE PROVISIONS ON THIS PAGE REPRESENT THE ONLY WARRANTY FROM MILNOR
AND NO OTHER WARRANTY OR CONDITIONS, STATUTORY OR OTHERWISE, SHALL
BE IMPLIED.
WE NEITHER ASSUME, NOR AUTHORIZE ANY EMPLOYEE OR OTHER PERSON TO
ASSUME FOR US, ANY OTHER RESPONSIBILITY AND/OR LIABILITY IN CONNECTION
WITH THE SALE OR FURNISHING OF OUR EQUIPMENTTOANYBUYER.
OR ANY OTHER WARRANTY IMPLIED BY LAW INCLUDING BUT NOT
LIMITED TO REDHIBITION
BMP720097/2008272A
5
How to Get the Necessary Repair Components
PELLERIN MILNOR CORPORATION
BIUUUD19 (Published) Book specs- Dates: 20081231 / 20081231 / 20081231 Lang: ENG01 Applic: UUU
How to Get the Necessary Repair Components
This document uses Simplified Technical English.
Learn more at http://www.asd-ste100.org.
You can get components to repair your machine from the approved supplier where you got this
machine. Your supplier will usually have the necessary components in stock. You can also get
components from the Milnor®factory.
Tell the supplier the machine model and serial number and this data for each necessary component:
• The component number from this manual
• The component name if known
• The necessary quantity
• The necessary transportation requirements
• If the component is an electrical component, give the schematic number if known.
• If the component is a motor or an electrical control, give the nameplate data from the used
component.
To write to the Milnor factory:
Pellerin Milnor Corporation
Post Office Box 400
Kenner, LA 70063-0400
UNITED STATES
Telephone: 504-467-2787
Fax: 504-469-9777
— End of BIUUUD19 —
6
PELLERIN MILNOR CORPORATION
BICXUI01 (Published) Book specs- Dates: 20021226 / 20021226 / 20021226 Lang: ENG01 Applic: CXU
Special Load Interface Requirements for the Milnor®Centrifugal
Extractor
Regardless of what device loads a Milnor centrifugal extractor or what type of system the
extractor is in, communication between the extractor and the loading device requires one or more
allied interface connections (see Note 1). This document explains how to establish these
connections when:
• the centrifugal extractor is loaded by a Milnor CBW®or Milnor COBUC (wet goods shuttle)
and both devices communicate with Miltrac™(either the older Miltrac controller or PC
Miltrac software running on a MultiTrac PC),
• the centrifugal extractor is loaded by a Milnor CBW controlled by a Mentor®or Mark 8
Miltron™controller, but one or both of the devices do not communicate with Miltrac.
Unlikely and/or nonspecific loading devices (e.g., COBUC in a non-Miltrac system, CBW with
non-serial controls, allied tunnel) are not covered in this document. For such conditions, consult
with Milnor Technical Support.
Allied interface signals are referred to in this document by their common names only. Connection
points (terminal and pin number) are not provided. See the allied interface signals tables for this
information. These tables can be found both in manual MTPALI01 (see Note 1) and in the
schematic manuals for the individual machines.
Note 1: For a detailed explanation of allied interfaces, refer to manual MTPALR01 “Allied Interfaces for
Milnor Automated Laundering System Machines (Mark 5 Controls and Later).”
1. When the Devices Communicate Via Miltrac
If the CBW or COBUC and the centrifugal extractor communicate with Miltrac, all batch data
and most operational data are handled by the Miltrac controller. Only the start cycle allied input
to the extractor need be used in addition. This signal ensures proper distribution by causing the
extractor to begin the cycle, and hence, to go from loading speed to distribution speed, as soon as
the goods transfer, and before too much water has drained out. This timing cannot be reliably
achieved by Miltrac.
If the centrifugal extractor is loaded by a CBW, this extractor input must be triggered by a CBW
programmable output, as explained in Section 2.6 “The Start Cycle Signal”. If loaded by a
Milnor COBUC, use the COBUC finished unloading to Milnor output to close the extractor
input (see Note 2). The COBUC is used where two or more extraction devices receive batches
from the same tunnel. Wire this COBUC output to each centrifugal extractor that receives goods
from the COBUC. Only the extractor that is currently receiving from the COBUC will respond to
this signal.
Note 2: Two COBUC outputs perform similar functions: finished unloading to Milnor (TBC-1 and
TBC-2) and finished unloading (WCO-03 and WCO-04). The first is specifically for the Milnor
centrifugal extractor and closes when the bucket, tilting up to dump the goods, reaches its upper limit. The
second is for use by any other allied device.
2. When Devices Do Not Communicate Via Miltrac
If the CBW or the centrifugal extractor or both do not communicate with Miltrac, all
communication between the CBW and the centrifugal extractor is via an allied interface. This
requires that data passing is enabled on the Mentor or Miltron controller (Section 2.1). Batch data
passed from the CBW to the extractor includes the extract code (Section 2.3), the empty load
signal (Section 2.4), and may include other batch data, if available (Section 2.2). Operational
signals from the CBW to the extractor include the optional end extract (early call) signal and the
7
Special Load Interface Requirements for the Milnor®Centrifugal Extractor
PELLERIN MILNOR CORPORATION
required start extractor signal (Section 2.5), and the start cycle signal (Section 2.6).
Additionally, the extractor must pass a extractor says load allowed signal to the CBW (Section
2.7).
2.1. Enabling Allied Data Pass—Whether the CBW is Miltron- or Mentor-controlled, allied
data pass must be enabled and the module that supplies the batch data must be specified. On the
Miltron, allied data pass is enabled in Display N, Data Pass. On the Mentor, it is enabled in Data
Pass on the CBW Hardware Configuration page. The last module of the CBW supplies batch
data to the extractor. The number that identifies this module is one less than the number of
modules (for example, the last module on a 10 module CBW is module 9) because for this
purpose, counting starts at zero (the first module is module 0). On the Miltron, enter this value in
Display H, Page 01, in the NCPOS field. On the Mentor, enter it on the CBW Output Timers
page, in the Module Supplying Batch Data field.
2.2. Batch Data—Applicable CBWs can provide, via allied signals, and the centrifugal extractor
can read in: 16 dry codes, 256 customer codes, and the following signals: new formula, new
customer, and single cake. The extractor can also read in 128 goods codes and 16 destination
codes, but the CBW can only provide 8 destination codes. Refer to manual MTPALR01 (see
Note 1) or the machine schematic manuals for connection points for these signals.
The extractor can be programmed for 16 discrete extract codes. Some, but not all applicable
CBWs provide these. However, a work-around is available to handle extract codes, as explained
in Section 2.3, below. The extractor can also read in an empty load signal. This must be handled
as explained in Section 2.4, below.
2.3. Using Drycode for Extract Code on Certain CBW's—Some CBWs explicitly
provide 16 extract code output signals. The following CBW controllers do not:
• Miltron controller with a software version 9401C or earlier
• Mentor controller with Generation2 (G2) Mentor software version 97107 or earlier
• Mentor controller with any Generation3 (G3) Mentor software version
On CBW's with any of the controllers listed above, the four output signals for drycode must be
used instead for the extract code. If the CBW is Miltron-controlled, the extract codes would be
programmed in the Drycodes column of Miltron Display H, page 3, field B. If the CBW is
Mentor-controlled, they would be entered, instead of drycode, in the Post Wash Codes zone of the
Formula Programming page. Of course, this means that another method must be used to
introduce dry codes farther downstream in the system, if needed.
2.4. The Empty Load Signal—The CBW does not provide an explicit “empty load” (also
referred to as pass empty) allied output. However, the “don't main press goods” output, normally
used with the Milnor two-stage press, may be used for this purpose. Wire this output to the empty
load input on the extractor. Whether the CBW is Miltron or Mentor controlled, enable this output
for the “pass empty” formula by programming a value of 1 for press pressure. On the Mark 8
Miltron, this is Display H, Page 3, Field E. On the Mentor, this is the Pressure drop down box
(not the Pass Empty check box) in the Post-Wash Codes zone of the Formula Programming
page.
8
PELLERIN MILNOR CORPORATION
2.5. The End Extract (Early Call) and Start Extractor Signals—The end extract (early call)
(if used) and start extractor inputs on the extractor can both be enabled at the same time. Hence,
they can be served by a single output on the CBW. There is no explicit allied output provided for
this purpose. Rather, a programmable output (C-bit) assigned to the last module must be
allocated and wired to both the early call / end extract and loading mode / start extractor inputs on
the extractor. This output is programmed as follows (whether the CBW is Miltron or Mentor
controlled):
Compatibility = off
Op code = 09 (“Early Call”)
Hold code = N (or not checked)
Init code = A
On time = 255 (for every formula)
2.6. The Start Cycle Signal—Although the CBW does provide an explicit start press allied
output, this is only for use with the press, not the extractor. Rather, for proper timing, a
programmable output assigned to the last module must be allocated and wired to the to the
extractor start cycle input. Whether a Miltron or a Mentor, this output is programmed as follows:
Compatibility = off
Hold code = N (or not checked)
Op code = 00 (“Standard Timed”)
Init code = H
On time = 004 (for every formula)
2.7. The Extractor Says Load Allowed Si
g
nal—The extractor says load allowed output on the
extractor signals the CBW that it is free to receive a load. On a CBW with a Miltron controller or
a Generation2 (G2) Mentor controller, connect this output to the explicitly provided press free
allied input. The Generation3 (G3) Mentor controller does not provide an explicit press free
input. On these machines, allocate a programmable input for this purpose and assign it input op
code 11 (“Press Free”).
— End of BICXUI01 —
9
PELLERIN MILNOR CORPORATION
BICALC02 (Published) Book specs- Dates: 20031016 / 20031016 / 20031017 Lang: ENG01 Applic: CXU
Milnor®Allied Interface Specifications and Signals, Centrifugal
Extractor
An allied device that interfaces with the Milnor system machine equipped with Mark 5 or later
microprocessor controls must meet the electrical specifications and functional requirements given
in Section 1 “Electrical and Functional Specifications”.
The “Signals...” section(s) herein identify the allied interface signals and provide related
information (see Section 2 “How the Signals Tables Are Organized”).
This document also provides useful information for troubleshooting allied interfaces:
• The Display/code and Board/code values in the signals tables, are cross-references to the
output and input displays and to the output and input numbers on the I/O boards respectively.
Section 4 “Monitoring Allied Interface Outputs and Inputs”, explains how to use these cross-
references.
• As an aid in working with numeric signals, Section 5 “Decimal / Binary Conversion and
How It Applies to Allied Interfaces” explains how to determine, for any batch code, which
value (off or on) each signal in a group should pass.
1. Electrical and Functional Specifications
WARNING 1 : Electrocution and Electrical Burn Hazards—Contact with high voltage
will electrocute or burn you. Power switches on the machine and the control box do not eliminate
these hazards. High voltage is present at the machine unless the main machine power disconnect
is off.
• Do not service machine unless qualified and authorized.
• Lock out and tag out power at the main machine disconnect before opening electric boxes
and accessing electrical components.
For inputs from Milnor (Milnor outputs), the allied device must limit circuit load to that specified
in Section 1.1, below. For outputs to Milnor (Milnor inputs), the allied device must supply
circuitry that meets the specifications in Section 1.2, below. The functional requirements stated in
Section 1.3 must be met for proper coordination and data exchange between the devices.
1.1. Permissible Load for Milnor Outputs—For signals from Milnor to allied (Milnor
outputs/allied inputs), Milnor supplies potential-free contacts located on board-mounted relays.
The signals are conducted by traces on the board having the following capacity:
• Maximum voltage: 240V
• Maximum current: 0.5 amps
• Maximum VA: 3
CAUTION 2 : Risk of Damage/Malfunction—Traces on control boards may burn out,
requiring board replacement, if called upon to handle heavy currents. High voltages can cause
arcing across traces.
• Do not apply loads exceeding the specified capacity.
• Do not use allied interface outputs to operate motors or for any other unintended purpose.
These may, however, be used to operate relays that do not exceed the specified capacity.
10
Milnor®Allied Interface Specifications and Signals, Centrifugal Extractor
PELLERIN MILNOR CORPORATION
1.2. Component Requirements for Milnor Inputs—For signals from allied to Milnor
(allied outputs/Milnor inputs–which connect directly to control boards and are used to ground
Milnor control inputs), Milnor applies a low energy signal as follows:
• Voltage: 5VDC or 12VDC
• Minimum current: 5 milliamps
The potential-free contacts supplied by allied and the circuit wiring must be capable of faithfully
carrying these low energy signals.
CAUTION 3 : Risk of Bad Data—Resistance due to wire length or deteriorated contacts can
mask signals. Inadequate shielding against electrical noise can trigger false signals.
• Keep wire runs as short as possible.
• Use a digital signal ground connection (wire number 2G on the CBW; wire number 7 on
other Milnor devices), not merely chassis ground.
• Ground any spare wires.
• Pass all wires through a ferrite bead.
• Replace relays that have worn or corroded contacts.
• Do not run input wiring adjacent to, or in the same conduit with, any wires carrying AC.
For example, do not run input and output wiring in the same conduit if AC is used to
power Milnor output/allied input signals.
1.3. Functional Requirements
1. For numeric signals (batch codes) from allied to Milnor (allied loading interface), all signals
must be properly set when the operational signal indicating this data is valid occurs. Signals
must remain set for the longer of 5 seconds or through any subsequent operational signal
requiring this data (see “Loading Interface non-Numeric Signals...”). Milnor will read all
numeric signals during this time.
2. For numeric signals from Milnor to allied (allied discharge interface), allied must not read
signals until the data valid, or other operational signal indicating data is valid occurs (see
“Discharge Interface non-Numeric Signals...”).
3. Although not all the operational signals listed in the tables are necessarily required, (the
signals used will vary with specific machine models and with variations in the operating
cycle), those signals used, must occur in the order listed.
4. When connecting numeric signals between devices, ensure that signals are properly matched
up with respect to significance (least significant-to-least significant, next least significant-to-
next least significant, etc.).
2. How the Signals Tables Are Organized
For an allied device that loads the Milnor machine, Milnor provides an allied loading interface.
For an allied device that receives goods from (discharges) the Milnor machine, Milnor provides
an allied discharge interface. In both cases, some signals are used in groups to pass numeric
values in binary and some signals are used individually to pass non-numeric (on/off) values. The
receiving device can read the groups of numeric signals in any order as long as it reads this data
during the window of time within which it is valid. However, because each signal within a group
of numeric signals represents a specific digit of the binary number, the order of significance of
the signals (digit order) must be understood and must match on sending and receiving devices.
Most non-numeric signals provide operational information which must be exchanged according
to a predetermined “handshaking” scheme. Hence, the sequence in which operational signals
occur (enabling order) is critical. Accordingly, the signal information is presented in four tables:
11
PELLERIN MILNOR CORPORATION
1. Loading interface numeric input signals and digit order—In this table, signals are
depicted in digit order, that is, the way they would be read as a binary number. The rightmost
column represents the signal that carries the least significant digit. Each adjacent column to
the left is the signal representing the digit of next higher significance. The table is divided
into row groups—one row group for each batch code provided. Each row group provides
pertinent information for the signals used with that batch code. In an allied loading interface,
all numeric signals pass from allied to Milnor and are therefore, inputs to Milnor.
2. Loading interface non-numeric signals and enabling order—In this table, each row
represents a signal and each column provides pertinent information for that signal. Generally,
these signals must be exchanged by the interfaced devices in the order listed. The labels given
to operational signals in the schematics can vary from device to device. However, the
document “Summary of Milnor Allied Interface Capability” provides generic names for
these. The right-hand column of this table provides both the generic (function) name and the
signal name as shown in the schematic, except where these are the same.
3. Discharge interface numeric output signals and digit order—This table is arranged the
same as the “loading interface numeric...” table. However, in an allied discharge interface, all
numeric signals pass from Milnor to allied and are therefore, outputs from Milnor.
4. Discharge interface non-numeric signals and enabling order—This table is arranged the
same as the “loading interface non-numeric...” table. As with a loading interface, the devices
need to exchange these signals in the order shown.
12
Milnor®Allied Interface Specifications and Signals, Centrifugal Extractor
PELLERIN MILNOR CORPORATION
3. Signals—Centrifugal Extractors With Mark 5 Controls[Document
BICALC05]
Table 1: Loading Interface Numeric Input Signals and Digit Order—Centrifugal Extractor
Common
Conn.
Most
Significant Dedicated Connections (Binary Data Signals) Least
Significant
Signal name on schematic
(e.g., Drycode A, B, etc.)--> J I H G F E D C B A
Multi-
terminal TBA WC2 WC2 WC2 WC2
Pin Number 7 8 7 6 5
Wire Number 7231 232 233 234
Display/code -- i3/H i3/G i3/F i3/E
16 Drycodes
(00 - 15)
Board/code -- io2/7 io2/6 io2/5 io2/4
Multi-
terminal TBA WC1 WC1 WC1 WC1
Pin Number 712 11 10 9
Wire Number 7347 348 349 340
Display/code -- i4/L i4/K i4/J i4/I
16 Destina-
tion Codes
(00-15)
Board/code -- io3/11 io3/10 io3/9 io3/8
Multi-
terminal TBA WC1 WC2 WC2 WC2 WC2 WC2 WC2 WC2
Pin Number 7 1 16 15 14 13 12 11 10
Wire Number 7330 241 242 243 244 247 248 249
Display/code -- i4/A i3/P i3/O i3/N i3/M i3/L i3/K i3/J
256 Custo-
mer Codes
(000-255)
Board/code -- io3/0 io2/15 io2/14 io2/13 io2/12 io2/11 io2/10 io2/9
Multi-
terminal TBA WC1 WC1 WC1 WC1 WC1 WC1 WC1
Pin Number 7 8 7 6 5 4 3 2
Wire Number 7331 332 333 334 337 338 339
Display/code -- i4/H i4/G i4/F i4/E i4/D i4/C i4/B
128 Goods
Codes (000-
127)
Board/code -- io3/7 io3/6 io3/5 io3/4 io3/3 io3/2 io3/1
Multi-
terminal TBA WC2 WC2 WC2 WC2
Pin Number 7 4 3 2 1
Wire Number 7237 238 239 230
Display/code -- i3/D i3/C i3/B i3/A
16 Extract
Formula
Codes (00-
15)
Board/code -- io2/3 io2/2 io2/1 io2/0
13
PELLERIN MILNOR CORPORATION
Table 2: Loading Interface non-Numeric Signals and Enabling Order—Centrifugal Extractor
Common Connection* Dedicated Connection
Signal
Direc-
tion
Multi-
terminal Pin Wire Multi-
terminal Pin Wire
Display
/ code
Board /
code Function Name / Signal Name
Although Milnor reads the batch data (previous table and next four signals) when it receives the "loading mode / start extractor"
signal, these signals should be set before the "early call / end extract" signal (if used) is enabled.
Input TBA 7 7 WC1 13 344 i4/M io3/12 new formula
Input TBA 7 7 WC1 14 343 i4/N io3/13 new customer
Input TBA 7 7 WC1 15 342 i4/O io3/14 empty load
Input TBA 7 7 WC2 9240 i3/I io2/8 single cake
Input TBA 7 7 TBA 71 71 i1/D ** early call / end extract
Output* TBA 100 100 TBA 99 99 o1/n o1/5 load desired / extractor desires load
Input TBA 7 7 TBA 88 88 i2/K io1/11 loading mode / start extractor
Output* TBA 109 109 TBA 101 101 o1/d io1/3 load allowed / extractor says load allowed
Input TBA 7 7 TBA 91 91 i2/L io1/12 transfer complete / start cycle
* For outputs from Milnor, Milnor does not normally assign either pin of the potential-free contact as the common. Hence, both pins
have unique pin and wire numbers.
** This signal uses a direct input on the processor board, not an input on a peripherial board.
14
Milnor®Allied Interface Specifications and Signals, Centrifugal Extractor
PELLERIN MILNOR CORPORATION
Table 3: Discharge Interface Numeric Output Signals and Digit Order—Centrifugal Extractor
Common
Conn.*
Most
Significant Dedicated Connections (Binary Data Signals) Least
Significant
Signal name on schematic
(e.g., Drycode A, B, etc.)--> J I H G F E D C B A
Multi-terminal n/a WCZ WCZ WCZ WCZ
Pin Number n/a 7 • 8 5 • 6 3 • 4 1 • 2
Wire Number n/a 452 •
460
454 •
453
456 •
455
459 •
458
Display/code -- o3/d o3/c o3/b o3/a
16 Drycodes
(00 - 15)
Board/code -- io2/3 io2/2 io2/1 io2/0
Multi-terminal n/a WCD WCD WCD WCD
Pin Number n/a 21** •
22
21** •
24 25 • 26 27 • 28
Wire Number n/a 267 •
274
267 •
275
268 •
276
269 •
277
Display/code -- o4/n o4/m o4/l o4/k
16 Destina-
tion Codes
(00-15)
Board/code -- o2/13 o2/12 o2/11 o2/10
Mulit-terminal n/a WCX WCX WCX WCX WCX WCX WCX WCX
Pin Number n/a 15 • 16 13 • 14 11 • 12 9 • 10 7 • 8 5 • 6 3 • 4 1 • 2
Wire Number n/a 368 •
369
366 •
367
364 •
365
361 •
362
352 •
360
354 •
353
356 •
355
359 •
358
Display/code -- o3/p o3/o o3/n o3/m o3/l o3/k o3/j o3/i
256
Customer
Codes (000-
255)
Board/code -- io3/7 io3/6 io3/5 io3/4 io3/3 io3/2 io3/1 io3/0
Mulit-terminal n/a WCD WCD WCD WCD WCD WCD WCD
Pin Number n/a 31 • 32 15 • 16 13 • 14 11 • 12 9 • 10 7 • 8 5 • 6
Wire Number n/a 271 •
279
257 •
265
256 •
264
255 •
263
254 •
262
253 •
261
252 •
260
Display/code -- o4/i o4/h o4/g o4/f o4/e o4/d o4/c
128 Goods
Codes (000-
127)
Board/code -- o2/8 o2/7 o2/6 o2/5 o2/4 o2/3 o2/2
Mulit-terminal n/a WCZ WCZ WCZ WCZ
Pin Number n/a 15 • 16 13 • 14 11 • 12 9 • 10
Wire Number n/a 468 •
469
466 •
467
464 •
465
461 •
462
Display/code -- o3/h o3/g o3/f o3/e
16 Formula
Codes (00-
15)
Board/code -- io2/7 io2/6 io2/5 io2/4
* For outputs from Milnor, Milnor does not normally assign either pin of the potential-free contact as the common. Hence, both pins
have unique pin and wire numbers. In this table these are listed together in the same cell, with a dot between (e.g., C • D)
** To provide 4 destination signals with limited available terminals, Destination Codes C and D had to share pin 21.
15
PELLERIN MILNOR CORPORATION
Table 4: Discharge Interface non-Numeric Signals and Enabling Order—Centrifugal Extractor
Common Connection* Dedicated Connection
Signal
Direc-
tion
Multi-
terminal Pin Wire Multi-
terminal Pin Wire
Display
/ code
Board /
code Function Name / Signal Name
Input TBA 7 7 TBA 94 94 i2/P io1/15 (no function name) / discharge allowed***
Output* TBA 96 96 TBA 95 95 o1/h io1/7 discharge desired / discharge desired
Milnor sets all batch data (previous table and next three signals) before it enables the "transfer complete / discharge finished" signal.
Output* WCD 3251 WCD 4259 o4/b o2/1 new formula
Output* WCD 29 270 WCD 30 278 o4/j o2/9 new customer
Output* WCD 1250 WCD 2258 o4/a o2/0 single cake
Input TBA 7 7 TBA 76 76 i1/J ** load allowed / start discharge
Output* TBA 98 98 TBA 97 97 o1/p o1/7 transfer complete / discharge finished
* For outputs from Milnor, Milnor does not normally assign either pin of the potential-free contact as the common. Hence, both pins
have unique pin and wire numbers.
** This signal uses a direct input on the processor board, not an input on a peripherial board.
*** The function of this input is to inable/disable discharging via a manually operated switch. This is not the "discharge allowed"
function.
4. Monitoring Allied Interface Outputs and Inputs
The status of outputs and inputs can be monitored on the machine display while the machine is in
operation, as explained in the machine reference manual (see Note 1 and Note 2). Beginning with
Mark 4 controls (Mark 9 on the CBW), output and input status can also be monitored on the I/O
boards. These boards contain LED's—one green LED for each input and one red LED for each
output (see Note 3). When the LED is illuminated, the circuit is made.
Note 1: It is also possible to actuate certain outputs for testing, as explained in the reference manual.
However, the “Display/code” values in the tables herein, refer only to the displays used to view
outputs/inputs.
Note 2: The outputs and inputs available for viewing on the display include some (but not all) allied
interface signals as well as signals for many other functions. See the reference manual for a listing of all
outputs and inputs that can be monitored during operation.
Note 3: Almost all allied interface outputs and inputs are passed via the I/O boards (peripheral boards) and
are therefore, represented by LED's on the boards. A few, however, are passed directly via the processor
board (direct outputs/inputs). The processor board does not contain LED's.
4.1. Identifying Outputs and Inputs on the Display Pages —On CBW's, some allied
inputs are available for viewing on the Mentor Direct and Standard Inputs page (as indicated in
the signals tables). It is fairly easy to identify signals on the Mentor because the signal names are
displayed.
The single stage press, two stage press, centrifugal extractor, shuttle, COBUC, and dryer use a
two or four line by 20 character LCD display (see Note 4). On these devices, each output or input
is represented by a character (lower or upper case letter) on the top line and a plus (+) or minus (-)
sign under the character indicating the on/off status of the signal. The outputs and inputs span
several display pages. Each page is accessed via the keypad and the procedures for doing so are
explained in the reference manual. The “Display/code” values listed in the tables herein tell you
which display page and character represent the indicated signal, as shown in the following
example:
16
This manual suits for next models
4
Other Milnor Scrubber manuals
