Bulletin No. APLR-N
Drawing No. LP0118
Released 6/06
MODELS APLR - APOLLO 6-DIGIT RATE INDICATOR [TIME BASE] AND
PBLR - 4/6 DIGIT MODULE FOR USE WITH THE LARGE DIGIT DISPLAY (LDD)
z 6-DIGIT, 0.56" (14.2 mm) HIGH LED DISPLAY (APLR)
z CRYSTAL-CONTROLLED TIME-BASE PROGRAMMABLE UP TO
32.764 SECONDS PROVIDES DIRECT-READING FOR ANY RATE
UNITS
z 0.02% ACCURACY
z PROGRAMMABLE DECIMAL POINTS
z FREQUENCY DOUBLING
z PROGRAMMABLE INPUT CIRCUIT, ACCEPTS OUTPUTS FROM
A WIDE VARIETY OF SENSORS
z LEADING ZERO BLANKING
z POWER-UP SELF-TEST
z NEMA 4/IP65 SEALED FRONT METAL BEZEL
DESCRIPTION
SAFETY SUMMARY
The Apollo Time Base Rate Indicators (Model APLR) and Module (Model
PBLR), provide the versatility and flexibility needed to accommodate virtually
any rate measuring need. Based on Micro-processor technology, this unit
represents the optimum in cost/performance ratio.
This unit has the ability to scale for direct readout in terms of the units being
measured. Whether a machine produces bottles, cloth, wire, or beverage mix,
operation is enhanced when the rate readout is expressed directly in
bottles/min., feet/min., gallons/hour, or whatever units are needed in plant
operations. The APLR/PBLR can provide this capability through its settable
time base, programmable decimal points, and frequency doubling functions.
The APLR/PBLR can also accommodate magnetic pickups, as well as logic
(sourcing output) sensors and NPN open collector (sinking output) sensors.
This unit also has a self-test feature, which checks all the micro-processor
and display driver circuitry after power-up (if enabled). This self-test also can
be used to test the time base select DIP switches and decimal point select DIP
switches, to make certain all switches are functioning properly.
Power and input connections are made via a removable terminal block,
located at the rear of the unit. Each terminal can accept one #14 AWG wire. DIP
switches at the side of the unit are used to program the input configuration.
The Apollo Rate Indicator has a sealed metal die-cast bezel which meets
NEMA 4/IP65 specifications for wash-down and/or dust, when properly
installed. Two mounting clips are provided for easy installation. The Time Base
Rate Indicator uses a 6-digit, 0.56" (14.2 mm) high LED display, which is
readable to 23 feet (7 M).
All safety related regulations, local codes and instructions that appear in the
manual or on equipment must be observed to ensure personal safety and to
prevent damage to either the instrument or equipment connected to it. If
equipment is used in a manner not specified by the manufacturer, the protection
provided by the equipment may be impaired.
CAUTION: Risk of Danger.
Read complete instructions prior to
installation and operation of the unit.
SPECIFICATIONS
1. DISPLAY: 6-Digit, 0.56" (14.2 mm) high LED display. (APLR)
2. POWER REQUIREMENTS:
APLR
AC Operation: Available in two voltages.
115 VAC, ±10%, 50/60 Hz, 14 VA or
230 VAC, ±10%, 50/60 Hz, 14 VA
DC Operation:
24 VDC, 10% @ 0.6 A max.
Note: All available units can be powered at Terminal #3 from a 11 to 14
VDC, 0.6 A max. power supply.
PBLR
AC Operation: Switch selected via the LDD power supply board,
115/230 (+/-10%), 50/60 Hz, 10 VA for 4-digit, 15 VA for 6 digit
(including LDD).
3. SENSOR POWER: +12 VDC, ±25% @ 100 mA max.
4. MAXIMUM OPERATING FREQUENCY: 10 KHz, 50% duty cycle.
10,000 cps with min. pulse width “ON” and “OFF” times of 50 µsec.
5. TIME BASE SELECTION RANGE: 0.004 to 32.764 seconds.
6. ACCURACY: 0.02%
7. MAXIMUM INPUT VOLTAGE AND CURRENT: When the “SIG. IN”
(Terminal 5) is driven from external signal voltages, max. voltage swing is
±50 V peak. Input voltage can be dropped by an external series resistance that
limits input current to ±5 mA. (These ratings are for S3 “OFF”.)
CAUTION: Risk of electric shock.
DIMENSIONS In inches (mm)
Note: Recommended minimum clearance (behind the panel) for
mounting clip installation is 2.1" (53.4) H x 5.5" (140) W.
1
PANEL CUT-OUT
SPECIFICATIONS (Con’t)
INPUT SET-UP
8. INPUT IMPEDANCE: With S1 and S3 “OFF”, the resistive input
impedance exceeds 1megohm as long as the “SIG. IN” (Terminal 5) input
voltage is between zero and +12 VDC. Beyond these levels, the high and low
clamping diode will start to conduct, thus decreasing the input impedance.
With S3 “ON” the maximum input voltage to Terminal 5 must be limited to
28 VDC.
9. PARALLELING WITH APOLLO TOTALIZER (RLC standard count
input) INPUTS: Apollo Rate Indicators may be parallel connected with
counters having the RLC standard count input circuitry. These can operate
from a common current sink or source sensor, by connecting the appropriate
terminals in common. S3 on the Rate Indicator should be turned “OFF”
since pull-up or pull-down resistors are already present in the counter. The
Rate Indicator will not add appreciable sensor load with this arrangement.
Note: Rate Indicator cannot be operated in parallel with standard input
counters when 2-wire proximity sensors are used.
10. INPUT AND POWER CONNECTIONS: There is a plug-in,
compression-type, terminal block located at the rear of the unit. This block
can be removed from the rear of the unit for ease of wiring. After wiring is
complete, the connector can be plugged back onto the unit.
11. CERTIFICATIONS AND COMPLIANCES:
SAFETY
IEC 61010-1, EN 61010-1: Safety requirements for electrical equipment
for measurement, control, and laboratory use. Part 1.
IP65 Enclosure rating (Face only), IEC 529
Type 4 Enclosure rating (Face only), UL50
ELECTROMAGNETIC COMPATIBILITY
Immunity to EN 50082-2
Electrostatic discharge
EN 61000-4-2 Level 2; 4 Kv contact1
Level 3; 8 Kv air
Electromagnetic RF fields
EN 61000-4-3 Level 3; 10 V/m
80 MHz - 1 GHz
Fast transients (burst)
EN 61000-4-4 Level 4; 2 Kv I/O2
Level 3; 2 Kv power
RF conducted interference
EN 61000-4-6 Level 3; 10 V/rms
150 KHz - 80 MHz
Power frequency magnetic fields EN 61000-4-8 Level 4; 10 A/m
Simulation of cordless telephone ENV 50204
Level 3; 10 V/m
900 MHz ± 5 MHz
200 Hz, 50% duty cycle
Emissions to EN 50081-2
RF interference
EN 55011
Enclosure class A
Power mains class A
The selection of input set-up is accomplished by the first three of six DIP
switches, located along the side of the unit. DIP switches 1-3 are used to
configure the input. Each of these switches are discussed below.
Note: Rate indicators frequently use magnetic pickups for input devices, while
contact input is never used due to speed and contact bounce limitations.
Consequently, there are basic differences between counter and rate-indicator
input circuits. In the Model APLR/PBLR input circuit, the hysteresis level is
quite small and the bias levels are significantly different to accommodate
both magnetic pickup inputs, as well as the +5 V and higher logic levels.
S1 - ON [MAG.PKUP.]: Connects a 0.1 µf damping input capacitor from input
to common. This capacitor is used only with magnetic pickup inputs and
serves to filter out high frequency noise. S1 should be set in the “OFF”
position when using inputs other than magnetic pickups.
S2 - ON [LOGIC]: Sets the bias reference so that input logic signals trigger
count pulses as they cross a level of approximately +2.5 V.
OFF: Sets the bias reference so that a signal of 150 mV or more will trigger
count pulses. This provides the sensitivity required for low speed
magnetic pickup sensors.
Note: Hysteresis for both S2 “ON” and “OFF” conditions is about 25 mV.
This means the difference between VIL and VIH with logic inputs (S2) is
almost insignificant and only a very small swing about the 2.5 V bias
level will trigger the input.
S3 - ON [NPN O.C.]: Connects a 3.9 K pull-up load resistor for sensors or
circuits with current sink output. Sensor output must sink 4 mA @ VOL
of 1 V or less.
DECIMAL POINT SELECTION
The selection of Decimal Point is accomplished
by DIP switches 4 and 5. The table at the right
shows what combination of switches is needed to
obtain the desired decimal point location. The unit
always has leading zero blanking. Note: D.P. will
change only at the normal display update time of
the unit.
Notes for APLR only:
1. Metal bezel of unit connected to earth ground (protective earth) at the
mounting panel.
2. EMI filter placed on the DC power supply, when DC powered: Corcom
#1VB3 or Schaffner #FN610-1/07 (RLC #LFIL0000).
Refer to the EMC Installation Guidelines section of this bulletin for
additional information.
12.ENVIRONMENTAL CONDITIONS:
Operating Temperature Range: 0 to 50°C
Storage Temperature Range: -40 to 70°C
Operating and Storage Humidity: 85% max. relative humidity (noncondensing) from 0°C to 50°C.
Altitude: Up to 2000 meters
13. CONSTRUCTION: Die-cast metal front bezel with black, high impact
plastic insert. Front panel meets NEMA 4/IP65 requirements for indoor use
when properly installed. Installation Category II, Pollution Degree 2. (Panel
gasket and mounting clips included with unit.)
14. WEIGHT:
APLR: 1.5 lbs (0.8 Kgs)
PBLR: 0.4 lbs (0.18 Kgs)
D.P.
LOCATION
SW 4
SW 5
↓(0)
↓(0)
0
↑(1)
↓(0)
0.0
↓(0)
↑(1)
0.00
↑(1)
↑(1)
0.000
REAR PANEL DIP SWITCHES
As can be seen from the rear of the unit, there is a row of 14 DIP switches
located beside the input and power terminal block. DIP switches 1 through 13
are Time Base Increments. When the switch is “ON”, it will add time to the
Time Base Increment total.
DIP switch 14 is the Frequency Doubling DIP switch. When it is “ON”, twice
the number of input pulses are registered in the unit. Doubling the input rate
allows the Time Base Increment total to be halved, thus allowing faster update
times with the same value displayed.
SELF-TEST
This unit has a built-in self-test feature which can only be activated
immediately after power-up (the unit will not count while in self-test). To
activate self-test, set the self-test DIP switch (D.S. 6) to the enable position.
Then power the unit up. With this test, all digits are cycled through starting with
a string of six zeros. This will be shown for about half a second, then a string of
ones will appear for about the same time duration. Following these, a string of
twos and so on, up to nines will be displayed. After the nines are shown, a string
of decimal points will appear. Next an interlace pattern of 1, 0, 1, 0, 1, 0, then
1, 2, 1, 2, 1, 2, and so on, until all digits from zero to nine have been displayed.
2
WIRING CONNECTIONS
The next portion of self-test will display four groups of zeros and/or ones.
(The first two digits from the left, in each group, will always show a zero.) In
the first group, the third digit represents the 13th (X4096) DIP switch setting.
The fourth and fifth digits show the setting for the Decimal Point select DIP
switches. (The fourth position digit represents DIP switch 4 and the fifth
position digit represents DIP switch 5.) The state of these digits coincide with
the table under the “Decimal Point Selection” section. The last digit will always
show a one.
The next three groups are shown
9 10 11 12 (DIP SWITCH)
on the right, and correspond to the Group 2: 0 0 X X X X
5 6 7 8 (DIP SWITCH)
DIP switch shown directly above it.
(Note: The first two digits in each Group 3: 0 0 X X X X
1 2 3 4 (DIP SWITCH)
group are always shown as zeros.)
The X’s represent a zero or one Group 4: 0 0 X X X X
(depending on the setting of the DIP
switch) in the display. Self-test is
automatically exited 8 seconds after the last DIP switch change is made.
As depicted in the drawing showing the rear view of the Apollo Rate
Indicator, there is a terminal block where all wiring connections are made. All
conductors should meet voltage and current ratings for each terminal. Also
cabling should conform to appropriate standards of good installation, local
codes and regulations. It is recommended that power supplied to the unit (AC
or DC) be protected by a fuse or circuit breaker. Remove the block for easy
access to the terminal screws. To remove the block, pull from the back of the
block until it slides clear of the terminal block shroud.
Enclosed with the PBLR module is an adhesive backed label(s) showing the
terminal block pin-out. This label is for wiring reference only, do not use for
specifications. This label should be applied to the appropriate location by the user.
CAUTION: The terminal block should NOT be removed with
power applied to the unit. The module should not be removed from
the LDD with power applied to the LDD or the module.
Terminal 3 is the “DC” (+12 V) terminal. This terminal is for sensor supply
and can provide up to 100 mA of current. An external +11 V to +14 VDC can
also be applied to this terminal to power the unit in the absence of A.C. power.
Terminal 4 is the “COMM.” (common) terminal, which is the common line
to which the sensor and other input commons are connected.
Terminal 5 is the “SIG. IN” (signal in) terminal. When the signal at this
terminal goes low, a count will be registered in the unit. (See “Input Ratings”
under “Specifications” section.)
EMC INSTALLATION GUIDELINES
Although this unit is designed with a high degree of immunity to
ElectroMagnetic Interference (EMI), proper installation and wiring methods
must be followed to ensure compatibility in each application. The type of the
electrical noise, source or coupling method into the unit may be different for
various installations. Cable length, routing and shield termination are very
important and can mean the difference between a successful installation or a
troublesome installation. Listed below are some EMC guidelines for successful
installation in an industrial environment.
1. The unit should be mounted in a metal enclosure, that is properly connected
to protective earth.
a. If the bezel is exposed to high Electro-Static Discharge (ESD) levels, above
4 Kv, it should be connected to protective earth. This can be done by making
sure the metal bezel makes proper contact to the panel cut-out or connecting
the bezel screw with a spade terminal and wire to protective earth.
2. Use shielded (screened) cables for all Signal and Control inputs. The shield
(screen) pigtail connection should be made as short as possible. The
connection point for the shield depends somewhat upon the application.
Listed below are the recommended methods of connecting the shield, in order
of their effectiveness.
a. Connect the shield only at the panel where the unit is mounted to earth
ground (protective earth).
b. Connect the shield to earth ground at both ends of the cable, usually when
the noise source frequency is above 1 MHz.
c. Connect the shield to common of the unit and leave the other end of the
shield unconnected and insulated from earth ground.
3. Never run Signal or Control cables in the same conduit or raceway with AC
power lines, conductors feeding motors, solenoids, SCR controls, and
heaters, etc. The cables should be run in metal conduit that is properly
grounded. This is especially useful in applications where cable runs are long
and portable two-way radios are used in close proximity or if the installation
is near a commercial radio transmitter.
4. Signal or Control cables within an enclosure should be routed as far away as
possible from contactors, control relays, transformers, and other noisy
components.
5. In extremely high EMI environments, the use of external EMI suppression
devices, such as ferrite suppression cores, is effective. Install them on Signal
and Control cables as close to the unit as possible. Loop the cable through the
core several times or use multiple cores on each cable for additional protection.
Install line filters on the power input cable to the unit to suppress power line
interference. Install them near the power entry point of the enclosure. The
following EMI suppression devices (or equivalent) are recommended:
Ferrite Suppression Cores for signal and control cables:
Fair-Rite # 0443167251 (RLC #FCOR0000)
TDK # ZCAT3035-1330A
Steward #28B2029-0A0
Line Filters for input power cables:
Schaffner # FN610-1/07 (RLC #LFIL0000)
Schaffner # FN670-1.8/07
Corcom #1VB3
Corcom #1VR3
Note: Reference manufacturer’s instructions when installing a line filter.
6. Long cable runs are more susceptible to EMI pickup than short cable runs.
Therefore, keep cable runs as short as possible.
POWER WIRING (A.C. Version)
Primary AC power is connected to Terminals 1 and 2 (marked VAC 50/60 Hz,
located on the left-hand side of the block). For best results, the AC power should
be relatively “clean” and within the specified ±10% variation limit. Drawing
power from heavily loaded circuits or from circuits that also power loads that
cycle on and off, should be avoided.
POWER WIRING (APLR D.C. Version only)
The DC Version unit will operate from a 24 VDC power supply. The positive
wire of the DC power source connects to Terminal #1 and the minus “-” to
Terminal #2.
3
CONNECTIONS & CONFIGURATION SWITCH SET-UP FOR VARIOUS SENSOR OUTPUTS
COUNT SWITCH OR ISOLATED TRANSISTOR OUTPUTS
SENSORS WITH CURRENT SINK OUTPUT (NPN O.C.)
[Includes ASTC, LMPC, PSAC, RPGC, (RPGB, RPGH) * , LSC]
RECOMMENDED RULES FOR MAGNETIC PICKUP CONNECTIONS
1. Use 2-wire shielded cable for magnetic pickup signal leads.
2. Never run signal cable in conduit, troughs, or cable bundles with power carrying
conductors.
3. Connect the shield to the common Terminal “4” at the input of the instrument. Do
NOT connect the shield at the pickup end, leave it “open” and insulate the exposed
shield to prevent electrical contact with the frame or case. (Shielded cable, supplied
on most RLC magnetic pickups, has open shield on pickup end.)
TWO WIRE PROXIMITY SENSORS
OLDER STYLE, SENSORS WITH
-EF OUTPUT
A.C. INPUTS FROM TACH.
GENERATORS, INVERTERS,
ETC.
SENSORS WITH CURRENT SOURCE OUTPUT (PNP O.C.)
INPUT FROM CMOS & OTHER
BI-POLAR OUTPUTS
INPUT FROM TTL
INSTALLATION ENVIRONMENT
INSTALLATION
The unit should be installed in a location that does not exceed the
maximum operating temperature and provides good air circulation. Placing
the unit near devices that generate excessive heat should be avoided.
The bezel should be cleaned only with a soft cloth and neutral soap
product. Do NOT use solvents.
Continuous exposure to direct sunlight may accelerate the aging process of
the bezel.
Do not use tools of any kind (screwdrivers, pens, pencils, etc.) to operate
the keypad of the unit.
PBLR installation information is contained in the LDD bulletin. Refer to
that bulletin for instructions on installing the module.
The unit meets NEMA 4/IP65 requirements for indoor use, when properly
installed. The units are intended to be mounted into an enclosed panel with a
gasket to provide a water-tight seal. Two mounting clips and screws are
provided for easy installation. Consideration should be given to the thickness
of the panel. A panel which is too thin may distort and not provide a watertight seal. (Recommended minimum panel thickness is 1/8".)
Cut the panel opening to the specified dimensions. Remove burrs and clean
around the panel opening. Slide the panel gasket over the rear of the unit to
the back of the bezel. Insert the unit into the panel. As depicted in the drawing,
install the screws into the narrow end of the mounting clips. Thread the
screws into the clips until the pointed end just protrudes through the other
side. Install each of the mounting clips by inserting the wide lip of the clips
into the wide end of the hole, located on either side of the case. Then snap the
clip onto the case.
Tighten the screws evenly to apply uniform compression, thus providing a
water-tight seal. CAUTION: Only minimum pressure is required to seal panel.
Do NOT overtighten screws.
4
TIME BASE SETTING PROCEDURE
FLOW RATE INDICATION APPLICATION
The Apollo Time Base Rate Indicator has a time base selection range of
0.004 sec. to 32.764 sec. For a minimum time base (0.004 sec.), the X1 DIP
switch is set to “ON”. For the maximum time base, all the DIP switches would
be set to “ON” (these add up to 8191). Therefore, a specific time base is
achieved by adding up the appropriate individual time base increments.
The time base increment total is computed according to the following
formula:
A positive displacement pump is driven by a gear reducer and an AC motor.
An ARCJ NEMA C FLANGE is mounted to the end of this AC motor.
The magnetic pickup (which senses the gear) of the ARCJ adapter kit feeds
pulses to the APLR. The sensing gear, in combination with the pump and
reducer, provides 560 pulses for every gallon of fluid passing through the pump.
The Model APLR is used to read directly in tenths of gallons/min. in flow rates
up to 45 gallons/min. The following logical steps can be used to determine the
time base value required for direct readout. At 45 GPM, the number of output
pulses would be as follows:
TIME BASE INCREMENT = (Display Readout Desired) x DDP x (15,000)
TOTAL (TBIT)
[(Known RPM) x (Known PPR)] *
45 gallons/min. x 560 pulses/gallon = 25,200 pulses/min.
* - Input Pulse Rate Per Minute.
Using the TBIT formula:
DDP: Use one of the following numbers in the above formula for the Display
Decimal Point (DDP) position.
0
= 1
0.0
= 10
0.00 = 100
DISPLAY READOUT DESIRED
REVOLUTIONS PER MINUTE
PULSES PER REVOLUTION
x (10)* x 15,000
TBIT = (45)
25,200**
= 267.857
* - For Tenths Position
= 1800 (Direct Readout in RPM)
= 1800
= 60
1,800 × 1 × 15,000
TBIT = = 250
1,800 × 60
to the nearest
[ round
whole number ]
** - Input Pulse Rate Per Minute
TBIT = 268
DIP switch 9 . . . . . 256
DIP switch 4 . . . . . 8
DIP switch 3 . . . . . 4
to the nearest
[ round
whole number ]
The appropriate Time Base switches, which together add up to 250, are then
set “ON”. Start by selecting the first increment which is greater than half the
desired TBIT, and add subsequent increments that are more than half the
difference needed.
TBIT = 250
DIP switch 8. . . . . 128
Needed =
122
DIP switch 7. . . . . 64
Needed =
58
DIP switch 6. . . . . 32
Needed =
26
DIP switch 5. . . . . 16
Needed =
10
DIP switch 4. . . . . 8
Needed =
2
DIP switch 2. . . . . 2
Needed =
Needed =
12
4
From the above calculation, DIP switches 3, 4, and 9, would be set to the
“ON” position. The tenths position decimal point must also be set to “ON”. So
the display will show 45.0 when 45 gallons are passing through the pump every
minute.
As shown above, DIP switches 2 and 4-8 are all set to “ON”. If it is desired
to know what the time is in seconds, multiply 250 x 0.004 sec. = 1 sec.
Note: This is the set-up for a one-second time base, which allows for direct
readout of RPM.
5
WEB SPEED INDICATION APPLICATION
A newspaper publishing company wants to know the rate at which their
printing press is operating. A fifty-tooth timing sprocket is mounted to the shaft
of one of the press rollers. An MP-62TA magnetic pickup is used to sense the
moving teeth. Direct readout is obtained by setting the time base to a period in
which the number of teeth passing the pickup is numerically equal to the desired
readout. Using the TBIT formula, the following calculations are performed:
TIME BASE INCREMENT = (Display Readout Desired) x (15,000)
TOTAL (TBIT)
[(Known RPM) x (Known PPR)] *
(632) x (15,000)
=
(1419) x (50)
= 133.6
to the nearest
[ round
whole number ]
* - Input Pulse Rate Per Minute.
TBIT = 134
DIP switch 8 . . . . . 128
DIP switch 3 . . . . . 4
DIP switch 2 . . . . . 2
Needed =
Needed =
6
2
Now DIP switches, 4, 5, 6, 9, and 11, are set to “ON”. Also, the tenths
position decimal point would be set to “ON”. (Note: If the time base is now too
long, approximately 5.3 sec. the “FRQ. DBL.” DIP switch can be set to “ON”,
then only half the time base will be necessary.
DIP switches 2, 3, and 8, are set to “ON”. If the rounding error introduced
above is unacceptable, the display could be scaled up by a factor of 10 and then
a decimal point turned on in the tenths position. The calculations would be as
follows:
(6320) x (15,000)
TBIT =
(1419) x (2) x (50)
TBIT = (Display Readout Desired x 10) x 15,000
(6320) x (15,000)
=
(1419) x (50)
DIP switch 11
DIP switch 9
DIP switch 6
DIP switch 5
DIP switch 4
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
TBIT = 1336
- 1024
256
32
16
8
Needed
Needed
Needed
Needed
=
=
=
=
DIP switch 10
DIP switch 8
DIP switch 5
DIP switch 4
DIP switch 3
312
56
24
8
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
TBIT = 668
512
128
16
8
4
Needed
Needed
Needed
Needed
For further technical assistance, contact technical support at the appropriate company numbers listed.
ORDERING INFORMATION
DESCRIPTION
APLR
Apollo Time Base Rate Indicator
PART NUMBERS FOR AVAILABLE SUPPLY VOLTAGES
230 VAC
115 VAC
24 VDC
APLR0610
APLR0600
APLR0630
For more information on Pricing, Enclosures & Panel Mount Kits refer to the RLC Catalog or contact your local RLC distributor.
PERSONALITY MODULE
MODEL NO.
PART NUMBERS
DESCRIPTION
115/230 VAC
PBLR *
156
28
12
4
DIP switches 3, 4, 5, 8, and 10, are all set to “ON” along with the tens
position decimal point. The time base, in seconds, is 668 x 0.004 = 2.67 sec.
TROUBLESHOOTING
MODEL NO.
=
=
=
=
Apollo Time Base Rate Module for use with
the 4 or 6 digit Large Digit Display
* Requires an LDD for use.
6
PBLR0600
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7
LIMITED WARRANTY
The Company warrants the products it manufactures against defects in materials and workmanship
for a period limited to two years from the date of shipment, provided the products have been stored,
handled, installed, and used under proper conditions. The Company’s liability under this limited
warranty shall extend only to the repair or replacement of a defective product, at The Company’s
option. The Company disclaims all liability for any affirmation, promise or representation with
respect to the products.
The customer agrees to hold Red Lion Controls harmless from, defend, and indemnify RLC against
damages, claims, and expenses arising out of subsequent sales of RLC products or products
containing components manufactured by RLC and based upon personal injuries, deaths, property
damage, lost profits, and other matters which Buyer, its employees, or sub-contractors are or may be
to any extent liable, including without limitation penalties imposed by the Consumer Product Safety
Act (P.L. 92-573) and liability imposed upon any person pursuant to the Magnuson-Moss Warranty
Act (P.L. 93-637), as now in effect or as amended hereafter.
No warranties expressed or implied are created with respect to The Company’s products except those
expressly contained herein. The Customer acknowledges the disclaimers and limitations contained
herein and relies on no other warranties or affirmations.
Red Lion Controls AP
Red Lion Controls
20 Willow Springs Circle
Red Lion Controls BV
Basicweg 11b
31, Kaki Bukit Road 3,
#06-04/05 TechLink
York PA 17406
NL - 3821 BR Amersfoort
Singapore 417818
Tel +1 (717) 767-6511
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