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0BINSTALLATION AND
INSTRUCTION MANUAL
FOR
TM-16 EMERGENCY WARNING SYSTEM
SPECIAL NOTE BOONE CABLE WORKS & ELECTRONICS, INC.
1773-219TH LANE – P.O. BOX 429 UREAD THIS ENTIRE BOOKLETU BOONE,
IOWA 50036 USA UBEFORE PROCEEDING WITHU PHONE (515) 432-2010 FAX
(515) 432-5262 UTHE INSTALLATIONU TOLL FREE NUMBER – 1–800–265-2010
Web Address: (rolfesatboone.com)
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TABLE OF CONTENTS
1. General 1. Instrument (Battery Powered) 1. Instrument (110
VAC Powered) 1. Wiring Runs, Color Coded and Splices 1. Sensors
�. Probe �. Belt Alignment �. Surface �. Fire Detection
1. Operating Instructions
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1. General
Boone Cable Works & Electronics, Inc. offers a comprehensive
line of temperature monitoring equipment. This complete product
range and our extensive systems experience allows us to offer
effective solutions for a wide range of solutions for your
individual system requirements. Our extensive background in
temperature monitoring along with a constant program of innovation
and technological development allows us to offer cost-effective and
user-orientated solutions.
Please read all the instructions for system installation before
beginning.
1. TM Instrument (Battery Powered)
The instrument is in a Nema 13 enclosure, which offers
protection against dust, spraying of water and oil in an indoor
environment. It features a hinged clear polycarbonate cover for
easy viewing and accessibility. Two locking screws are provided on
the cover to secure it in place. Refer to the Hoffman installation
instructions included with the unit before mounting the enclosure.
To mount, remove the instrument splice compartment cover that is
attached by two screws. (See drawing 180095-A) Disconnect the
battery pack. Remove the instrument panel, which is secured with
four screws. The instrument is mounted with three mounting holes.
Fasten the instrument using the top hole. Then level the instrument
and secure it with the mounting holes at either end of the splice
compartment cover. Reassemble the instrument.
Inside on the left side of the splice compartment there are two
TM 9 conductor wires, which have a black jacket. (Lead #1 is for
sensors 1 through 8 and lead #2 is for sensors 9 through 16). They
are spliced color to color with the TM wires from the sensors.
The unit is powered by a single 9 volt battery. The Battery
compartment is also located behind the splice compartment
cover.
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1. TM Instrument (110 VAC Powered)
The instrument is in Nema 13 enclosure, which offers protection
against dust, spraying of water and oil in an indoor environment.
It features a hinged clear polycarbonate cover for easy viewing and
accessibility. Two locking screws are provided on the cover to
secure it in place. Refer to the Hoffman installation instructions
included with the unit before mounting the enclosure. To mount,
remove the instrument splice compartment cover that is attached by
two screws. (See drawing 180095-A) Remove the instrument panel,
which is secured with four screws. The instrument is mounted with
three mounting holes. Fasten the instrument using the top hole.
Then level the instrument and secure it with the mounting holes at
either end of the splice compartment cover. Reassemble the
instrument.
Inside on the left side of the splice compartment there are two
TM 9 conductor wires, which have a black jacket. (Lead #1 is for
sensors 1 through 8 and lead #2 is for sensors 9 through 16). They
are spliced color to color with the TM wires from the sensors.
Located on the right side of the splice compartment are two
terminal blocks. Attach 110 VAC or 220 VAC depending on which
input/power voltage was selected when ordering. See serial number
decal if unsure. If the instrument is configured for 220 VAC then
attach one power line to N and the other power line to L. If the
instrument is configured for 110 VAC then attach the neutral line
to N and the power line to L. For both 110 VAC and 220 VAC attach
earth ground to GND. The second terminal block provides normally
open (NO) and normally closed (NC) contacts that change state when
the BF enters an alarm condition. Use either the common (C) to NO
or C to NC contact. Do not use both the NO and NC contacts. The
contacts are rated at 125 VAC at 1 amp, resistive load. At the
bottom of the enclosure are conduit knockouts that are removed to
run wires to the instrument.
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1. Wiring Runs, Color Coded and Splices
The Instrument, which can monitor 16 sensors, has two TM wires
in its splice compartment. The wire marked #1 is for zones 1
through 8. The wire marked #2 is for zones 9 through 16. The wire
is run from the instrument to within 5 feet of each sensor. Strap
and mount the wire so that it is exposed to the least amount of
physical and environmental stress. The most desirable method is to
enclose all wires in a dedicated conduit to provide mechanical
protection.
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Below is a table listing the color code for the BF 9-conductor
wire.
A typical TM system is shown in drawing #180096-A.
Wire #1 Zone Wire #2 Black Common Black Blue 1 Blue Green 2
Green Red 3 Red Yellow 4 Yellow Clear 5 Clear Purple 6 Purple White
7 White
Drawing #180096-A shows one sensor for each zone. Depending on
the application you may wish to use multiple sensors on each zone.
The TM wire from the sensors is spliced at the instrument in the
splice compartment. The 9 wires are spliced color to color using
grease crimps.
Brown 8 Brown
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“TM Series” Thermostat Style - Temperature Sensors
TM Series sensors are available in three standard styles:
1. Bearing Probes: consisting of a stainless steel .25” diameter
thermowell and hardware for mounting through 1/8” NPT threaded
grease zerk hole in the bearing housing. Bearing can still be
maintained with the probe in place.
2. Belt alignment sensor: consisting of a 5” x 1’’ half round
brass friction bar, a mounting plate and sensor. Surface mount
sensor: consisting of a thermostat imbedded in a plated brass
mounting lug with 10’ of stainless braided duplex.
3. Surface sensors have a plated copper, mounting lug with hole
in it for bolting directly to a piece of equipment. These sensors
are designed to be used on equipment that has no grease zerk or
where access to the grease zerk is limited.
UTM Bearing Probes:U All “TM” Probes are available in 1408,
1608, and 1808 standard sizes. All sensors use a single pole NC
bimetallic thermostat with a contact rating of 1 amp 24 VAC or DC
resistive. All probes come with mounting hardware to mount the
probe into the standard 1/8” NPT grease zerk hole in the bearing
housing. All probes come with a standard 10’ of stainless steel
overbraided splicing pigtail attached.
Model UTMP-140, 160 or 180U – Bearing probes (Complete)
Description: 140, 160 or 1808 thermostat imbedded in a 4” long by
¼” D stainless Steel thermowell, includes steel “T” grease zerk
fitting, Brass compression connector and 10’ of stainless
overbraided splicing pigtail. Components available as replacement
parts:
1. Probe style sensor with pigtail only. 2. Steel “T” grease
zerk fitting with brass ¼” compression fitting.
UTM Belt Alignment Sensors:U All “TM” belt alignment sensors are
available in 1408, 1608, and 1808 standard sizes. All sensors use a
single pole NC bimetallic thermostat with a contact rating of 1 amp
24 VAC or DC resistive. All belt alignment sensors come with brass
friction bar and rub mounting plate. All belt alignment sensors
come with a standard 10’ of stainless steel overbraided splicing
pigtail attached. Model UTMR-140, 160 or 180U – Belt alignment
sensor (Complete) Description: 140, 160 or 1808 thermostat imbedded
in a plated copper lug with a ¼” mounting hole, 5” x 1” half round
brass friction bar and Teflon insulator with mounting plate.
Sensors come with a standard 10’ of stainless overbraided splicing
pigtail attached. Components available as replacement parts:
1. Lug style surface mount sensor with pigtail only. 2.
Replacement 5” x 1” half round brass friction bar. 3. Teflon
spacer/insulator. 4. 3” x 7” mounting plate.
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UTM Surface Mount Sensors:U All “TM” surface mount sensors are
available in 1408, 1608, and 1808 standard sizes. All sensors use a
single pole NC bimetallic thermostat with a contact rating of 1 amp
24 VAC or DC resistive. All surface mount sensors come with a
standard 10’ of stainless steel overbraided splicing pigtail
attached. These sensors are designed to be used on bearings that
have small grease zerks, where probe style sensors can not be used.
Model UTMS-140, 160 or 180U – Surface mount sensor (Complete)
Description: 140, 160 or 1808 thermostat imbedded in a plated
copper lug with a ¼” mounting hole. Sensors come with a standard
10’ of stainless overbraided splicing pigtail attached.
TMS surface sensors are also available with a large washer style
lug that can accommodate being placed under the grease zerk. (NOTE:
The grease zerk must compress fully against the sensor to provide
good heat transfer from the bearing housing to the sensor.) It is
also recommended that you reduce the temperature range of the
surface sensor by 20 to 40 degrees in order to accommodate the
slower transfer of heat with this type of arrangement. Other sized
temperature sensors are available as special order only items.
Please contact Boone Cable Works & Electronics, Inc. for price,
availability, and lead-time on all special orders. 1. Standard
Sensors
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The sensor is designed to be inserted into the grease zerk hole
of a bea (See Drawing #180090) Heat is transferred from the bearing
race to the sensor. Below are directions for proper probe
installation.
1. Cle ound bearing and grease zerk to avoid getting any dirt
into the
bea
Remove the existing zerk.
tall the brass nippe, tee and 1/8’ copression
connectorassembly.
Reinstall thzerk intthe sidof the tee.
the bearnginto thecompressioconnecassemat the top of
thesteemounting“T”.
that it isapoximate1/8” fromthbearngraceantighten the
compresionconnectonut.
Run the probe sensor wire into a splice fitting and attach the
sensor into the system.
Ins
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“WARNING – IF THE SENSOR IS NOT ATTACHED PROPERLY AND SECURELY
TO THE MONITORED PIECE OF EQUIPMENT, HEAT MAY FAIL TO TRANSFER TO
THE SENSOR CAUSING IT TO NOT OPERATE PROPERLY. CHECK THE SENSORS
REGULARLY TO SEE IF THEY ARE ATTACHED SECURELY.”
�. Belt Alignment
1BBelt alignment is accomplished by attaching the sensor to a
brass heat transfer plate (See Drawing #180091 and 180091-A for
conduit ready installations). The brass pad transfers the heat of
the belt rubbing against it and activates the sensor. Two style of
brass plates are available, as ½ moon and an optional round disk
style. The ½ moon offers a greater range of motion on the belt,
while the round disk is easier to install. It is important to
tighten the sensor securely for a good thermal bond. The sensor has
a thermostat attached to the housing with approximately 10 feet of
wire. See Drawing #180096-A when wiring the probe into the
system.
“WARNING – IF THE SENSOR IS NOT ATTACHED SECURELY TO THE
MONITORED PIECE OF EQUIPMENT, HEAT MAY FAIL TO TRANSFER TO THE
SENSOR CAUSING IT TO NOT OPERATE PROPERLY. CHECK THE SENOSRS
REGULARLY TO SEE IF THEY ARE ATTACHED SECURELY.”
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�. Surface Sensors
The sensor is a surface mount device with high thermal
conductivity. The sensor has a ¼” hole for mounting. This hole may
be drilled to the size required. When mounting the sensor on a
bearing with a zerk, remove the zerk. Place the zerk through the
sensor mounting hole and reinsert the zerk (See Drawing #180090).
The bearing may also be drilled and tapped. A bolt would be used to
go through the sensor and into the threaded hole. Heat is
transferred through the bearing housing to the sensor. It is
critical that the sensor and bearing are securely compressed
together, so that the bearing heat is transferred directly to the
sensor with no air gap. The surface sensor has a thermostat
attached to the bolting lug with approximately 10 feet of wire. See
Drawing #180096-A when wiring the sensor into the system.
“WARNING – IF THE SENSOR IS NOT ATTACHED SECURELY TO THE
MONITORED PIECE OF EQUIPMENT, HEAT MAY FAIL TO TRANSFER TO THE
SENSOR CAUSING IT TO NOT APERATE PROPERLY. CHECK THE SENSORS
REGULARLY TO SEE IF THEY ARE ATTACHED SECURELY.”
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�. Fire Detection
The quantity and location of fire detection sensors for the TM
Emergency Warning System are judgement calls and are best
determined by the user.
Some general recommendations are:
1. One determining factor on how many sensors per room is the
cubic volume of air in that room.
2. Always mount the sensor(s) as high as possible in the room.
Due to the fact that heat rises, the warmest place in a room is
near the ceiling.
3. Mount sensors securely in place. This is to ensure that
excessive heat will not cause the sensors to fall, before they
activate in an alarm situation.
Alarm pull stations should be located at exits or according to
code requirements. The normally closed contact of the pull station
is used. The pull station appears like any other sensor to the TM
System. Which means if the wire is inadvertently broken, the TM
System will issue an alarm. Accessories such as remote audible and
visual alarms and an auto dialer are available. These accessories
use the normally open or normally closed contacts on the TM
Instrument. The auto dialer offers one voice/pager message up to
four numbers.
“WARNING – THE CUSTOMER IS TOTALLY RESPONSIBLE FOR SENSOR LAYOUT
DESIGN. CHECK THE SENSORS REGULARLY TO SEE IF THEY ARE ATTACHED
SECURELY.”
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1. Operation Instructions
The TM Emergency Warning System Instrument has an on/off switch,
test button, alarm horn and 16 monitor zone LED’s respectively. To
operate the system, place the on/off switch in the on position.
Once the instrument is turned on, the test button activates all
LED’s and alarms. The monitor LED’s are for each sensor or zone.
They are normally off but light up for an alarm condition. The
alarm buzzer supplied with the instrument is an 85 decibel buzzer
that activates for an alarm condition. The alarm contacts for a
remote alarm are supplied with the 110 VAC unit. They can switch a
resistive load of 1A at 125 VAC. These contacts are activated in an
alarm condition. When the voltage output drops below 4 volts the
audible alarm is turned on, but no monitor LED’s will light. This
tells the operator that the batteries are low or the 110 VAC power
supply needs maintenance. The battery powered unit will run a
minimum of 4000 hours with no alarms and 100 hours with 1 alarm
condition. To replace the batteries, remove the two screws on the
splice compartment. Remove the old 9V battery from the holder and
replace with a new one. The sensors are normally closed thermostats
that open when the temperature goes above a preset point. The
wiring to and from the thermostats is also tested in this manner.
If the 9 conductor wiring is broken it will also cause an alarm on
the sensor with damaged wire. TM-16 instruments are also available
with an optional external alarm shutoff switch. This switch is
located below the unit alarm on the left side of the instrument.
(See drawing #180093-A) Be sure to correct the problem associated
tothe alarm condition immediately and restore the alarm to the
normal on position. All monitored equipment should be taken out of
service until the alarm condition has been corrected and the alarm
switch has been returned to the on position. Use the test button on
the front of the instrument to confirm that the system is operating
properly.
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INSTALLATION Belt alignment is accomplished by attaching the
sensor to a brass heat transfer plate (See Drawing #180091 and
180091-A for conduit ready installations). The brass pad transfers
the heat of the belt rubbing against it and activates the sensor.
Two style of brass plates are available, as ½ moon and an optional
round disk style. The ½ moon offers a greater range of motion on
the belt, while the round disk is easier to install. It is
important to tighten the sensor securely for a good thermal
bond.
