DP5D0000

Bulletin No.  DP5-G Drawing No.  LP0546 red @ ® Released  08/17 Tel +1 (717) 767-6511 Fax +1 (717) 764-0839 lion ~~a~~ www.redlion.net **MODEL DP5 – 1/8 DIN ANALOG INPUT PANEL METERS** 

- _PROCESS, VOLTAGE, CURRENT, AND TEMPERATURE INPUTS_ 

-   5-DIGIT 0 _.56" HIGH LED DISPLAY_ 

- _PROGRAMMABLE FUNCTION KEYS/USER INPUT_ 

- _9 DIGIT TOTALIZER (INTEGRATOR) WITH BATCHING_ 

- _OPTIONAL CUSTOM UNITS OVERLAY W/BACKLIGHT_ 

- _NEMA 4X/IP65 SEALED FRONT BEZEL_ 

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C ULR US LISTED<br>PROC. CONT. EQ.<br>3RSD<br>**----- End of picture text -----**<br>


## **GENERAL DESCRIPTION** 

The DP5 Panel Meters offer many features and performance capabilities to suit a wide range of industrial applications. These meters are available in three different models to handle various analog inputs, including DC Voltage/Current, Process, and Temperature Inputs. Refer to pages 4 and 5 for the details on the specific models. 

## **SAFETY SUMMARY** 

All safety related regulations, local codes and instructions that appear in this literature 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. 

The meters provide a MAX and MIN reading memory with programmable capture time. The capture time is used to prevent detection of false max or min readings which may occur during start-up or unusual process events. 

The signal totalizer (integrator) can be used to compute a time-input product. This can be used to provide a readout of totalized flow, calculate service intervals of motors or pumps, etc. The totalizer can also accumulate batch weighing operations. 

**CAUTION: Risk of Danger. CAUTION: Risk of electric shock.** Read complete instructions prior to installation and operation of the unit. 

Once the meters have been initially configured, the parameter list may be locked out from further modification. 

The meters have been specifically designed for harsh industrial environments. With NEMA 4X/IP65 sealed bezel and extensive testing of noise effects to CE requirements, the meter provides a tough yet reliable application solution. 

## **DIMENSIONS  In inches (mm)** 

Note: Recommended minimum clearance (behind the panel) for mounting clip installation is 2.1" (53.4) H x 5.0" (127) W. 

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12 16 20<br>MAX 13 17 21<br>TMOINT 8.8.8.8.8 V 1.95 1.75 1415 1819 2322 1.75<br>(49.5) (44.5) 1 2 3 4 5 6 7 8 9 10 11 2425 (44.5)<br>DSP PAR F1 F2 RST<br>CICICICY) |<br>3.80 .10 = 4.10 =<br>3.60 (91.4)<br>(96.5) (2.5) (104.1)<br>**----- End of picture text -----**<br>


_1_ 

## **Table Of COnTenTs** 

Ordering Information . . . . . . . . . . . . . . . . . . . . 2 General Meter Specifications  . . . . . . . . . . . . . 3 Universal DC Input Panel Meter . . . . . . . . . . . 4 Process Input Panel Meter . . . . . . . . . . . . . . . 4 Thermocouple and RTD Input Meter . . . . . . . . 5 Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Installing the Meter . . . . . . . . . . . . . . . . . . . . . 6 

Setting the Jumpers  . . . . . . . . . . . . . . . . . . . . 6 Wiring the Meter . . . . . . . . . . . . . . . . . . . . . . . 7 Reviewing the Front Buttons and Display . . . . 9 Programming the Meter. . . . . . . . . . . . . . . . . 10 Factory Service Operations . . . . . . . . . . . . . . 17 Parameter Value Chart . . . . . . . . . . . . . . . . . 19 Programming Overview . . . . . . . . . . . . . . . . . 20 

## **Ordering infOrmaTiOn** 

## **Meter Part Numbers** 

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DP5 0 0<br>D - DC Volt/Current Input<br>P - Process Input<br>T - Thermocouple and RTD Input<br>0 - Red LED Display<br>0 - 85 to 250 VAC<br>1 - 11 to 36 VDC, 24 VAC<br>**----- End of picture text -----**<br>


## **Accessories Part Number** 

|**TYPE**|**MODEL NO.**|**DESCRIPTION**|**PART NUMBERS**|
|---|---|---|---|
|**Accessories**|PAXLBK|Units Label Kit Accessory (Not required for DP5T)|PAXLBK10|



_2_ 

## **general meTer speCifiCaTiOns** 

1. **DISPLAY** : 5 digit, 0.56" (14.2 mm) red LED, (-19999 to 99999) 

## 2. **POWER** : 

AC Versions: 

AC Power: 85 to 250 VAC, 50/60 Hz, 10 VA Isolation: 2300 Vrms for 1 min. to all inputs. DC Versions: 

DC Power: 11 to 36 VDC, 11 W 

AC Power: 24 VAC, ± 10%, 50/60 Hz, 10 VA 

Isolation: 500 Vrms for 1 min. to all inputs (50 V working). 

## 3. **ANNUNCIATORS** : 

MAX - maximum readout selected 

MIN - minimum readout selected 

TOT - totalizer readout selected, flashes when total overflows Units Label - optional units label backlight 

4. **KEYPAD** : 3 programmable function keys, 5 keys total 

5. **A/D CONVERTER** : 16 bit resolution 

## 6. **UPDATE RATES** : 

A/D conversion rate: 10 readings/sec. 

- Step response: 200 msec. max. to within 99% of final readout value 

(digital filter and internal zero correction disabled) 

700 msec. max. (digital filter disabled, internal zero correction enabled) Display update rate: 1 to 10 updates/sec. Max./Min. capture delay time: 0 to 3275 sec. 

## 7. **DISPLAY MESSAGES** : 

“OLOL” - Appears when measurement exceeds + signal range. 

“ULUL” - Appears when measurement exceeds - signal range DP5T: “OPEN” -  Appears when open sensor is detected. DP5T: “SHrt” -  Appears when shorted sensor is detected _(RTD only)_ 

- “. . . .” - Appears when display values exceed + display range. 

- “- . . .” - Appears when display values exceed - display range. 

8. **INPUT CAPABILITIES** : See specific product specifications, pages 4-5 

9. **EXCITATION POWER** : See specific product specifications, pages 4-5 

## 14. **ENVIRONMENTAL CONDITIONS** : 

Operating Temperature Range: 0 to 50°C 

Storage Temperature Range: -40 to 60°C 

- Vibration to IEC 68-2-6: Operational 5-150 Hz, 2 g Shock to IEC 68-2-27: Operational 25 g. 

Operating and Storage Humidity: 0 to 85% max. RH non-condensing Altitude: Up to 2000 meters 

15. **CERTIFICATIONS AND COMPLIANCES** : **CE Approved** 

- EN 61326-1 Immunity to Industrial Locations Emission CISPR 11 Class A 

- Safety requirements for electrical equipment for measurement, control, and laboratory use: 

- EN 61010-1: General Requirements 

- EN 61010-2-030: Particular Requirements for Testing and Measuring Circuits 

RoHS Compliant 

- UL Listed: File #E179259 

Type 4X Enclosure rating (Face only) IP65 Enclosure rating (Face only) 

IP20 Enclosure rating (Rear of unit) 

_Refer to EMC Installation Guidelines section of the bulletin for additional information._ 

16. **CONNECTIONS** : High compression cage-clamp terminal block Wire Strip Length: 0.3" (7.5 mm) Wire Gage: 30-14 AWG copper wire 

- Torque: 4.4-5.3 inch-lbs (0.5-0.6 N-m) 

17. **CONSTRUCTION** : This unit is rated for NEMA 4X/IP65 outdoor use. IP20 Touch safe. Installation Category II, Pollution Degree 2. One piece bezel/case. Flame resistant. Synthetic rubber keypad. Panel gasket and mounting clip included. 

18. **WEIGHT** : 7 oz. (200 g) 

## 10. **LOW FREQUENCY NOISE REJECTION** : 

- Normal Mode: > 60 dB @ 50 or 60 Hz ±1%, digital filter off Common Mode: >100 dB, DC to 120 Hz 

11. **USER INPUT** : One software defined user input 

Max. Continuous Input: 30 VDC 

Isolation To Sensor Input Common: Not isolated. Do not tie commons together. Response Time : 50 msec. max. 

Logic State: Jumper selectable for sink/source logic 

|**INPUT STATE**|**SINKING INPUTS**<br>**22 K**Ω**pull-up to +5 V**|**SOURCING INPUTS**<br>**22 K**Ω**pull-down**|
|---|---|---|
|Active|VIN< 0.9 VDC|VIN> 3.6 VDC|
|Inactive|VIN> 3.6 VDC|VIN< 0.9 VDC|



## 12. **TOTALIZER** : 

Time Base: second, minute, hour, or day Time Accuracy: 0.01% typical Decimal Point: 0 to 0.0000 Scale Factor: 0.001 to 65.000 

Low Signal Cut-out: -19,999 to 99,999 

Total: 9 digits, display alternates between high order and low order readouts 

13. **MEMORY** : Nonvolatile E[2] PROM retains all programmable parameters and display values. 

_3_ 

## **mOdel dp5d - Universal dC inpUT** 

>  _FOUR VOLTAGE RANGES (300 VDC Max)_ 

>  _FIVE CURRENT RANGES (2A DC Max)_ 

>  _24 VDC TRANSMITTER POWER_ 

## **DP5D SPECIFICATIONS** 

## **INPUT RANGES:** 

|**INPUT**<br>**RANGE**|**ACCURACY***<br>**(18 to 28°C)**|**ACCURACY***<br>**(0 to 50°C)**|**IMPEDANCE/**<br>**COMPLIANCE**|**MAX**<br>**CONTINUOUS**<br>**OVERLOAD**|**RESOLUTION**|
|---|---|---|---|---|---|
|±200µADC|0.03% of reading<br>+0.03µA|0.12% of reading<br>+0.04µA|1.11 Kohm|15 mA|10 nA|
|±2 mADC|0.03% of reading<br>+0.3µA|0.12% of reading<br>+0.4µA|111 ohm|50 mA|0.1µA|
|±20 mADC|0.03% of reading<br>+3µA|0.12% of reading<br>+4µA|11.1 ohm|150 mA|1µA|
|±200 mADC|0.05% of reading<br>+30µA|0.15% of reading<br>+40µA|1.1 ohm|500 mA|10µA|
|±2 ADC|0.5% of reading<br>+0.3 mA|0.7% of reading<br>+0.4 mA|0.1 ohm|3 A|0.1 mA|
|±200 mVDC|0.03% of reading<br>+30µV|0.12% of reading<br>+40µV|1.066 Mohm|100 V|10µV|
|±2 VDC|0.03% of reading<br>+0.3 mV|0.12% of reading<br>+0.4 mV|1.066 Mohm|300 V|0.1 mV|
|±20 VDC|0.03% of reading<br>+3 mV|0.12% of reading<br>+4 mV|1.066 Mohm|300 V|1 mV|
|±300 VDC|0.05% of reading<br>+30 mV|0.15% of reading<br>+40 mV|1.066 Mohm|300 V|10 mV|



- After 20 minute warm-up. Accuracy is specified in two ways: Accuracy over an 18 to 28 ° C and 10 to 75% RH environment; and accuracy over a 0 to 50 ° C and 0 to 85%RH (non-condensing environment). Accuracy over the 0 to 50 ° C range includes the temperature coefficient effect of the meter. 

## **EXCITATION POWER** : 

Transmitter Power: 24 VDC, ± 5%, regulated, 50 mA max. 

## **mOdel dp5p - prOCess inpUT** 

>  _DUAL RANGE INPUT (20 mA or 10 VDC)_ 

>  _24 VDC TRANSMITTER POWER_ 

## **DP5P SPECIFICATIONS** 

## **SENSOR INPUTS** : 

|**INPUT**<br>**(RANGE)**|**ACCURACY***<br>**(18 to 28°C)**|**ACCURACY***<br>**(0 to 50°C)**|**IMPEDANCE/**<br>**COMPLIANCE**|**MAX**<br>**CONTINUOUS**<br>**OVERLOAD**|**DISPLAY**<br>**RESOLUTION**|
|---|---|---|---|---|---|
|20 mA<br>(-2 to 26 mA)|0.03% of<br>reading +2µA|0.12% of<br>reading +3µA|20 ohm|150 mA|1µA|
|10 VDC<br>(-1 to 13 VDC)|0.03% of<br>reading +2 mV|0.12% of<br>reading +3 mV|500 Kohm|300 V|1 mV|



- After 20 minute warm-up. Accuracy is specified in two ways: Accuracy over an 18 to 28 ° C and 10 to 75% RH environment; and accuracy over a 0 to 50 ° C and 0 to 85%RH (non-condensing environment). Accuracy over the 0 to 50 ° C range includes the temperature coefficient effect of the meter. 

## **EXCITATION POWER** : 

Transmitter Power: 24 VDC, ± 5%, regulated, 50 mA max. 

_4_ 

## **mOdel dp5T - ThermOCOUple and rTd inpUT** 

 _THERMOCOUPLE AND RTD INPUTS_ 

>  _CONFORMS TO ITS-90 STANDARDS_ 

>  _TIME-TEMPERATURE INTEGRATOR_ 

## **DP5T SPECIFICATIONS** 

## **READOUT** : 

Resolution: Variable: 0.1, 0.2, 0.5, or 1, 2, or 5 degree Scale: F or C Offset Range: -19,999 to 99,999 display units 

## **THERMOCOUPLE INPUTS** : 

Input Impedance: 20 M Ω Lead Resistance Effect: 0.03 µ V/ohm Max. Continuous Overvoltage: 30 V 

|**INPUT**<br>**TYPE**|**RANGE**|**ACCURACY***<br>**(18 to 28°C)**|**ACCURACY***<br>|<br>**STANDARD**|**WIRE COLOR**|**WIRE COLOR**|
|---|---|---|---|---|---|---|
||||**(0 to 50°C)**||**ANSI**|**BS 1843**|
|T|-200 to 400°C<br>-270 to -200°C|1.2°C<br>**|2.1°C|ITS-90|(+) blue<br>(-) red|(+) white<br>(-) blue|
|E|-200 to 871°C<br>-270 to -200°C|1.0°C<br>**|2.4°C|ITS-90|(+) purple<br>(-) red|(+) brown<br>(-) blue|
|J|-200 to 760°C|1.1°C|2.3°C|ITS-90|(+) white<br>(-) red|(+) yellow<br>(-) blue|
|K|-200 to 1372°C<br>-270 to -200°C|<br>1.3°C<br>**|3.4°C|ITS-90|(+) yellow<br>(-) red|(+) brown<br>(-) blue|
|R|-50 to 1768°C|1.9°C|4.0°C|ITS-90|no<br>standard|(+) white<br>(-) blue|
|S|-50 to 1768°C|1.9°C|4.0°C|ITS-90|no<br>standard|(+) white<br>(-) blue|
|B|100 to 300°C<br>300 to 1820°C|3.9°C<br>2.8°C|5.7°C<br>4.4°C|ITS-90|no<br>standard|no<br>standard|
|N|-200 to 1300°C<br>-270 to -200°C|<br>1.3°C<br>**|3.1°C|ITS-90|(+) orange<br>(-) red|(+) orange<br>(-) blue|
|C<br>(W5/W26)|0 to 2315°C|1.9°C|6.1°C|ASTM<br>E988-90***|no<br>standard|no<br>standard|



*After 20 min. warm-up. Accuracy is specified in two ways: Accuracy over an 18 to 28°C and 15 to 75% RH environment; and Accuracy over a 0 to 50°C and 0 to 85% RH (non condensing) environment. Accuracy specified over the 0 to 50°C operating range includes meter tempco and ice point tracking effects. The specification includes the A/D conversion errors, linearization conformity, and thermocouple ice point compensation. Total system accuracy is the sum of meter and probe errors. Accuracy may be improved by field calibrating the meter readout at the temperature of interest. 

## **RTD INPUTS** : 

Type: 3 or 4 wire, 2 wire can be compensated for lead wire resistance Excitation current: 100 ohm range: 165 µ A 10 ohm range:  2.6 mA Lead resistance: 100 ohm range: 10 ohm/lead max. 

Max. continuous overload: 30 V 

|**DIRECT READO**<br>Input range: -10<br> <br>**INPUT TYPE**|**UT**:<br>to 65 mV<br> <br>**RANGE**|<br>**ACCURACY***<br>**(18 to 28°C)**|**ACCURACY***<br>**(0 to 50°C)**|**STANDARD**<br>*******|
|---|---|---|---|---|
|0<br>0<br>100 ohm Pt<br>alpha = .00385|to 400 ohms, hi<br>to 25 ohms, low<br>-200 to 850°C|gh range<br>range<br>0.4°C|1.6°C|IEC 751|
|Display range: -<br>100 ohm Pt<br>alpha = .003919|19999 to 99999<br>-200 to 850°C|0.4°C|1.6°C|no official<br>standard|
|120 ohm Nickel<br>alpha = .00672|-80 to 260°C|0.2°C|0.5°C|no official<br>standard|
|10 ohm Copper<br>alpha = .00427|-100 to 260°C|0.4°C|0.9°C|no official<br>standard|



|**INPUT TYPE**|**RANGE**|**ACCURACY***<br>**(18 to 28°C)**|**ACCURACY***|
|---|---|---|---|
||||**(0 to 50°C)**|
|Direct<br>mV range|-10 to 65mV<br>(1µV res.)|0.02% of reading<br>+ 4µV|0.12% of reading<br>+ 5µV|
|Direct<br>100 ohm range|0 to 400Ω<br>(10 MΩres.)|0.02% of reading<br>+ 0.04Ω|0.12% of reading<br>+ 0.05Ω|
|Direct<br>10 ohm range|0 to 25Ω<br>(1 MΩres.)|0.04% of reading<br>+ 0.005Ω|0.20% of reading<br>+ 0.007Ω|



** The accuracy over the interval -270 to -200°C is a function of temperature, ranging from 1°C at -200°C and degrading to 7°C at -270°C. Accuracy may be improved by field calibrating the meter readout at the temperature of interest. 

*** These curves have been corrected to ITS-90. 

## **aCCessOries** 

## **UNITS LABEL KIT (PAXLBK) - Not required for DP5T** 

Each meter has a units indicator with backlighting that can be customized using the Units Label Kit. The backlight is controlled in the programming. 

Each DP5T meter is shipped with ° F and ° C overlay labels which can be installed into the meter’s bezel display assembly. 

_5_ 

## **1.0 insTalling The meTer** Ce ~~—~~ _**Installation**_ While holding the unit in place, push the panel latch over the rear of the 

While holding the unit in place, push the panel latch over the rear of the unit so that the tabs of the panel latch engage in the slots on the case. The panel latch should be engaged in the farthest forward slot possible. To achieve a proper seal, tighten the latch screws evenly until the unit is snug in the panel (Torque to approximately 7 in-lbs [79N-cm]). Do not over-tighten the screws. 

The DP5 meets NEMA 4X/IP65 requirements when properly installed. The unit is intended to be mounted into an enclosed panel. Prepare the panel cutout to the dimensions shown. Remove the panel latch from the unit. Slide the panel gasket over the rear of the unit to the back of the bezel. The unit should be installed fully assembled. Insert the unit into the panel cutout. 

## _**Installation Environment**_ 

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PANEL<br>BEZEL<br>LATCHING<br>PANEL<br>SLOTS<br>LATCH<br>LATCHING<br>TABS<br>PANEL<br>GASKET<br>PANEL<br>MOUNTING<br>SCREWS<br>**----- End of picture text -----**<br>


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. 

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PANEL CUT-OUT<br>3.62 [+.03] -.00<br>+.8<br>(92    )-.0 1.77+.02-.00<br>+.5<br>(45    )-.0<br>**----- End of picture text -----**<br>


## **2.0 seTTing The JUmpers** ~~TT~~ 

The meter can have up to two jumpers that must be checked and / or changed prior to applying power. The two jumpers are: Input Range and User Input Logic. The following Jumper Selection Figures show an enlargement of the jumper area. 

## **User Input Logic Jumper** 

This jumper selects the logic state of the user input. If the user input is not used, it is not necessary to check or move this jumper. 

To access the jumpers, remove the meter base from the case by firmly squeezing and pulling back on the side rear finger tabs. This should lower the latch below the case slot (which is located just in front of the finger tabs). It is recommended to release the latch on one side, then start the other side latch. 

## **DP5D Jumper Selection** 

## **Input Range Jumper** 

One jumper is used for voltage or current input ranges. Select the proper input range high enough to avoid input signal overload. Only one jumper is allowed in this area. Do not have a jumper in both the voltage and current ranges at the same time. Avoid placing the jumper across two ranges. 

JUMPER SELECTIONS The indicates factory setting. 

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INPUT RANGE JUMPER<br>CURRENT<br>±2A<br>±200mA<br>——<br>±20mA<br>±2mA<br>±200µA<br>VOLT<br>±300V<br>±20V USER INPUT LOGIC JUMPER<br>±2V<br>±200mV SOURCE<br>SINK<br>**----- End of picture text -----**<br>


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Main<br>Circuit<br>Board<br>o f<br>JUMPER LOCATIONS<br>CURRENT<br>VOLT/<br>OHM USER INPUT<br>**----- End of picture text -----**<br>


_6_ 

**DP5P Jumper Selection** 

## JUMPER SELECTIONS 

The indicates factory setting. 

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USER INPUT LOGIC JUMPER<br>|<br>SINK<br>} !<br>SOURCE<br>REAR TERMINALS b o<br>**----- End of picture text -----**<br>


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Main<br>Circuit<br>Board<br>es<br>o e oF<br>USER INPUT<br>JUMPER<br>LOCATION<br>**----- End of picture text -----**<br>


## **DP5T Jumper Selection** 

## **RTD Input Jumper** 

One jumper is used for RTD input ranges. Select the proper range to match the RTD probe being used. It is not necessary to remove this jumper when not using RTD probes. 

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Main probe being used. It is not necessary to remove this jumper when not using RTD probes.<br>Circuit<br>Board JUMPER SELECTIONS<br>The   indicates factory setting.<br>a l :<br>ce a<br>RTD INPUT JUMPER USER INPUT LOGIC JUMPER<br>6 JUMPERLOCATION JUMPERLOCATION / po 100 ohms ET SINK<br>_ 10 ohms SOURCE<br>RTD USER INPUT | a1) 8 |<br>INPUT<br>PoE<br>REAR TERMINALS<br>**----- End of picture text -----**<br>


## **3.0 Wiring The meTer** 

## **WIRING OVERVIEW** 

Electrical connections are made via screw-clamp terminals located on the back of the meter. All conductors should conform to the meter’s voltage and current ratings. All cabling should conform to appropriate standards of good installation, local codes and regulations. It is recommended that power supplied to the meter (DC or AC) be protected by a fuse or circuit breaker. 

When wiring the meter, compare the numbers embossed on the back of the meter case against those shown in wiring drawings for proper wire position. Strip the wire, leaving approximately 0.3" (7.5 mm) bare lead exposed (stranded wires should be tinned with solder). Insert the lead under the correct screwclamp terminal and tighten until the wire is secure. (Pull wire to verify tightness.) Each terminal can accept up to one #14 AWG (2.55 mm) wire, two #18 AWG (1.02 mm), or four #20 AWG (0.61 mm). 

## **EMC INSTALLATION GUIDELINES** 

Although Red Lion Controls products are 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 a unit may be different for various installations. Cable length, routing, and shield termination are very important and can mean the difference between a successful or troublesome installation. Listed are some EMI guidelines for a successful installation in an industrial environment. 

1. A unit should be mounted in a metal enclosure, which is properly connected to protective earth. 

2. Use shielded cables for all Signal and Control inputs. The shield 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 to earth ground (protective earth) at one end where the unit is mounted. 

- b. Connect the shield to earth ground at both ends of the cable, usually when the noise source frequency is over 1 MHz. 

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 through 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. Also, Signal or Control cables within an enclosure should be routed as far away as possible from contactors, control relays, transformers, and other noisy components. 

4. Long cable runs are more susceptible to EMI pickup than short cable runs. 

5. In extremely high EMI environments, the use of external EMI suppression devices such as Ferrite Suppression Cores for signal and control cables is effective. The following EMI suppression devices (or equivalent) are recommended: 

- Fair-Rite part number 0443167251 (Red Lion Controls #FCOR0000) Line Filters for input power cables: Schaffner # FN2010-1/07 (Red Lion Controls #LFIL0000) 

6. To protect relay contacts that control inductive loads and to minimize radiated and conducted noise (EMI), some type of contact protection network is normally installed across the load, the contacts or both. The most effective location is across the load. 

- a. Using a snubber, which is a resistor-capacitor (RC) network or metal oxide varistor (MOV) across an AC inductive load is very effective at reducing EMI and increasing relay contact life. 

- b. If a DC inductive load (such as a DC relay coil) is controlled by a transistor switch, care must be taken not to exceed the breakdown voltage of the transistor when the load is switched. One of the most effective ways is to place a diode across the inductive load. Most Red Lion products with solid state outputs have internal zener diode protection. However external diode protection at the load is always a good design practice to limit EMI. Although the use of a snubber or varistor could be used. Red Lion part numbers: Snubber: SNUB0000 

   - Varistor: ILS11500 or ILS23000 

7. Care should be taken when connecting input and output devices to the instrument. When a separate input and output common is provided, they should not be mixed. Therefore a sensor common should NOT be connected to an output common. This would cause EMI on the sensitive input common, which could affect the instrument’s operation. 

- Visit http://www.redlion.net/emi for more information on EMI guidelines, 

- Safety and CE issues as they relate to Red Lion products. 

_7_ 

## **3.1  POWER WIRING** 

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AC Power DC Power<br>Terminal 1: VAC AC AC Terminal 1: +VDC + _<br>1 2<br>Terminal 2: VAC Terminal 2: -VDC 1 2<br>+ -<br>WBF<br>**----- End of picture text -----**<br>


## **3.2  INPUT SIGNAL WIRING** 

## **DP5D INPUT SIGNAL WIRING** 

Before connecting signal wires, the Input Range Jumper should be verified for proper position. 

**==> picture [519 x 493] intentionally omitted <==**

**----- Start of picture text -----**<br>
Voltage Signal  Current Signal   Current Signal (2 wire  Current Signal (3 wire<br> (self powered) (self powered)  requiring excitation)  requiring excitation)<br>Terminal 3: +VDC Terminal 4: +ADC Terminal 4: -ADC Terminal 4: +ADC (signal)<br>Terminal 5: -VDC Terminal 5: -ADC Terminal 6: +ADC Terminal 5: -ADC (common)<br>Terminal 6: +Volt supply<br>Voltage Signal (3 wire  3 4 5 6<br>requiring excitation)<br>3 5 4 5 Terminal 3: +VDC (signal)<br>+ - 4 6 Terminal 5: -VDC (common) Vout Iout COMM.<br>+ - Load +24V Terminal 6: +Volt supply 3 WIRE TRANSMITTER<br>300VDC MAX.  2 WIRE +Vs<br>- TRANSMITTER +<br>ree 2A DC MAX. f eg Go<br>Potentiometer Signal<br>CAUTION:  Sensor input common is NOT isolated from user  (3 wire requiring excitation)<br>input common. In order to preserve the safety of the meter  Terminal 3: Wiper<br>application, the sensor input common must be suitably isolated<br>- Terminal 5: Low end of pot.<br>from hazardous live earth referenced voltages; or input<br>Terminal 6: High end of pot.<br>common must be at protective earth ground potential. If not,<br>hazardous live voltage may be present at the User Input and  Input Range Jumper: 300 Volt 3 5 6<br>User Input Common terminals. Appropriate considerations  Module 1 Input Range: 300 Volt<br>must then be given to the potential of the user input common  Note: The Apply signal scaling style  300V<br>with respect to earth common. should be used because the signal will  INPUT<br>be in volts. R=1K to 10K<br>its<br>DP5P INPUT SIGNAL WIRING<br>Voltage Signal  Current Signal   Current Signal (2 wire  Current Signal (3 wire<br> (self powered) (self powered)  requiring excitation)  requiring excitation)<br>Terminal 3: +VDC Terminal 4: +ADC Terminal 4: -ADC Terminal 4: +ADC (signal)<br>Terminal 5: -VDC Terminal 5: -ADC Terminal 6: +ADC Terminal 5: -ADC (common)<br>Terminal 6: +Volt supply<br>3 4 5 6<br>Voltage Signal (3 wire<br>requiring excitation)  Vout Iout COMM.<br>3 4 5 4 5<br>+ - 4 5 6 Terminal 3: +VDC (signal)Terminal 5: -VDC (common) 3 WIRE TRANSMITTER +Vs<br>+ - +24V Terminal 6: +Volt supply<br>LOAD 2 WIRE<br>1 10 VDC MAX. Tie 20 mA DC MAX. k e FS - TRANSMITTER + ot<br>VOLT COMM CURRENT COMM VOLT CURRENT COMM +24V EXC<br>CURRENT +24V EXC<br>VOLT COMM +24V EXC<br>10 V 20 mA COMM +24 EXC<br>10 V 20 mA COMM 20 mA COMM<br>20 mA COMM +24 EXC<br>**----- End of picture text -----**<br>


## **DP5P INPUT SIGNAL WIRING** 

_**CAUTION:** Sensor input common is NOT isolated from user input common. In order to preserve the safety of the meter application, the sensor input common must be suitably isolated from hazardous live earth referenced voltages; or input common must be at protective earth ground potential. If not, hazardous live voltage may be present at the User Input and User Input Common terminals. Appropriate considerations must then be given to the potential of the user input common with respect to earth common._ 

_8_ 

## **DP5T INPUT SIGNAL WIRING** 

**==> picture [530 x 117] intentionally omitted <==**

**----- Start of picture text -----**<br>
Thermocouple 3-Wire RTD 2-Wire RTD CAUTION : Sensor input common is NOT isolated<br>from user input common. In order to preserve the<br>safety of the meter application, the sensor input<br>A<br>common must be suitably isolated from hazardous<br>live earth referenced voltages; or input common<br>must be at protective earth ground potential. If<br>3 4 5 3 4 5 3 4 5 not, hazardous live voltage may be present at the<br>User Input and User Input Common terminals.<br>+ - Appropriate considerations must then be given to<br>Sense Lead Sense Lead the potential of the user input common with<br>respect to earth common.<br>ye RTD (Excitation) Jumper<br>RTD TC+ COMM RTD TC+ COMM RTD TC+ COMM<br>**----- End of picture text -----**<br>


## **3.3  USER INPUT WIRING** 

Before connecting the wires, the User Input Logic Jumper should be verified for proper position.  If not using the User Input then skip this section. 

**==> picture [524 x 151] intentionally omitted <==**

**----- Start of picture text -----**<br>
Sinking Logic  Sourcing Logic<br>Terminal 8: Connect external switching device between the Terminal 8: + VDC thru external switching device<br>Terminal 7:    } User Input terminal and User Comm. Terminal 7: -VDC thru external switching device<br>In this logic, the user input of the meter is<br>In this logic, the user input of  the meter<br>internally pulled down to 0 V with 22 K<br>is internally pulled up to +5 V with 22 K<br>resistance. The input is active when a voltage<br>resistance. The input is active when it is<br>greater than 3.6 VDC is applied.<br>pulled low (<0 .9 V).<br>7 8<br>7 8<br>- +<br>V SUPPLY (30 V max.)<br>Lats i oe<br>COMM USER INPUT<br>COMM USER INPUT<br>**----- End of picture text -----**<br>


## **4.0 revieWing The frOnT bUTTOns and display** ~~PR~~ 

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**----- Start of picture text -----**<br>
Display<br>Readout MAX<br>MIN<br>V<br>Legends * TOT<br>[8.8.8.8.8] DSP PAR F1 F2 RST<br>**----- End of picture text -----**<br>


Optional Custom Units Overlay 

|**KEY**|**DISPLAY MODE OPERATION**|**PROGRAMMING MODE OPERATION**|
|---|---|---|
|**DSP**|Index display through max/min/total/input readouts|Quit programming and return to display mode|
|**PAR**|Access parameter list|Store selected parameter and index to next parameter|
|**F1**|Function key 1; hold for 3 seconds for Second Function 1**|Increment selected parameter value|
|**F2**|Function key 2; hold for 3 seconds for Second Function 2**|Decrement selected parameter value|
|**RST**|Reset (Function key)**|Hold with F1, F2to scroll value by x1000|



* Display Readout Legends may be locked out in Factory Settings. 

** Factory setting for the F1, F2, and RST keys is NO mode. 

_9_ 

## **5.0 prOgramming The meTer** 

## _**OVERVIEW**_ 

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**----- Start of picture text -----**<br>
DISPLAY<br>MODE<br>PAR PROGRAMMING MENU<br>NO<br>User Input/ Display/<br>Signal Function Program Secondary Totalizer Factory<br>Input Key Lock-out Function (Integrator) Service<br>Parameters Parameters Parameters Parameters Parameters Operations<br>Pro<br>F1/F2<br>Keys<br>PAR PAR PAR PAR PAR PAR<br>1-INP 2-FNC 3-LOC 4-SEC 5-tOt 9-FCS<br>**----- End of picture text -----**<br>


## **DISPLAY MODE** 

The meter normally operates in the Display Mode. In this mode, the meter displays can be viewed consecutively by pressing the **DSP** key. The annunciators to the left of the display indicate which display is currently shown; Max Value (MAX), Min Value (MIN), or Totalizer Value (TOT). Each of these displays can be locked from view through programming. (See Module 3) The Input Display Value is shown with no annunciator. 

## **PROGRAMMING MODE** 

Two programming modes are available. 

**Full Programming Mode** permits all parameters to be viewed and modified. Upon entering this mode, the front panel keys change to Programming Mode operations. This mode should not be entered while a process is running, since the meter functions and User Input response may not operate properly while in Full Programming Mode. 

**Quick Programming Mode** permits only certain parameters to be viewed and/ or modified. When entering this mode, the front panel keys change to Programming Mode operations, and all meter functions continue to operate properly. Quick Programming Mode is configured in Module 3. Throughout this document, Programming Mode (without Quick in front) always refers to “Full” Programming Mode. 

## _**STEP BY STEP PROGRAMMING INSTRUCTIONS:**_ 

## **PROGRAMMING MODE ENTRY (PAR KEY)** 

The Programming Mode is entered by pressing the **PAR** key. If this mode is not accessible, then meter programming is locked by either a security code or a hardware lock. (See Modules 2 and 3 for programming lock-out details.) 

## **MODULE ENTRY (ARROW & PAR KEYS)** 

Upon entering the Programming Mode, the display alternates between  and the present module (initially ). The arrow keys ( **F1**  and **F2**  ) are used to select the desired module, which is then entered by pressing the **PAR** key. 

## **PARAMETER (MODULE) MENU (PAR KEY)** 

Each module has a separate parameter menu. These menus are shown at the start of each module description section which follows. The **PAR** key is pressed to advance to a particular parameter to be changed, without changing the programming of preceding parameters. After completing a module, the display will return to  . From this point, programming may continue by selecting and entering additional modules. (See **MODULE ENTRY** above.) 

## **PARAMETER SELECTION  ENTRY (ARROW & PAR KEYS)** 

## **PROGRAMMING TIPS** 

The Programming Menu is organized into nine modules (See above). These modules group together parameters that are related in function. It is recommended to begin programming with Module 1 and proceed through each module in sequence. If lost or confused while programming, press the **DSP** key to exit programming mode and start over. When programming is complete, it is recommended to record the meter settings on the Parameter Value Chart and lock-out parameter programming with a User Input or lock-out code. (See Modules 2 and 3 for lock-out details.) 

## **FACTORY SETTINGS** 

Factory Settings may be completely restored in Module 9. This is a good starting point if encountering programming problems. Throughout the module description sections which follow, the factory setting for each parameter is shown below the parameter display. In addition, all factory settings are listed on the Parameter Value Chart following the programming section. 

## **ALTERNATING SELECTION DISPLAY** 

In the module description sections which follow, the dual display with arrows appears for each programming parameter. This is used to illustrate the display alternating between the parameter (top display) and the parameter's Factory Setting (bottom display). In most cases, selections or value ranges for the parameter will be listed on the right. 

For each parameter, the display alternates between the parameter and the present selection or value for that parameter. For parameters which have a list of selections, the arrow keys ( **F1**  and **F2**  ) are used to sequence through the list until the desired selection is displayed. Pressing the **PAR** key stores and activates the displayed selection, and also advances the meter to the next parameter. 

## **NUMERICAL VALUE ENTRY (ARROW, RST & PAR KEYS)** 

For parameters which require a numerical value entry, the arrow keys can be used to increment or decrement the display to the desired value. When an arrow key is pressed and held, the display automatically scrolls up or scrolls down. The longer the key is held, the faster the display scrolls. 

The **RST** key can be used in combination with the arrow keys to enter large numerical values, when the **RST** key is pressed along with an arrow key, the display scrolls by 1000’s. Pressing the **PAR** key stores and activates the displayed value, and also advances the meter to the next parameter. 

## **PROGRAMMING MODE EXIT (DSP KEY or PAR KEY at**   **)** 

The Programming Mode is exited by pressing the **DSP** key (from anywhere in the Programming Mode) or the **PAR** key (with   displayed). This will commit any stored parameter changes to memory and return the meter to the Display Mode. If a parameter was just changed, the **PAR** key should be pressed to store the change before pressing the **DSP** key. (If power loss occurs before returning to the Display Mode, verify recent parameter changes.) 

**Indicates Program Mode Alternating Display Parameter**   **Selection/Value**   

_10_ 

## **5.1  mOdUle 1 - signal inpUT parameTers (**  **)** 

**==> picture [420 x 149] intentionally omitted <==**

**----- Start of picture text -----**<br>
1-INP PARAMETER MENU Pro<br>PAR<br>rAN6E dECPt round FILtr  bANd StYLE INP x dSP x<br>Input  Display Display  Filter  Filter  Scaling  Input x  Display x<br>Range Decimal Point Rounding Setting Band Style Value Value<br>em DP5T PARAMETER MENU<br>PAR<br>_EYP E-— SCAL E-— | dEEP E— | rou nd— OFF SE—F fLt e-— _bARd<br>Input  Temperature Display  Display  Display Filter  Filter<br>Type Scale Decimal  Rounding Offset Setting Band<br>Point<br>**----- End of picture text -----**<br>


Refer to the appropriate Input Range for the selected meter. Use only one Input Range, then proceed to Display Decimal Point. 

## **DP5D INPUT RANGE** 

|**DP5D INPUT RANGE**||
|---|---|
|<br><br><br><br>**SELECTION**<br><br><br>[|||**SELECTION**<br>**RANGE**<br>**RESOLUTION**<br>**RANGE**<br>**RESOLUTION**<br><br><br>±2.0000 V<br>±200.00 mV<br>±2.0000 mA<br>±200.00 µA|
||<br>±20.000 V<br>±20.000 mA|
||<br>±300.00 V<br>±200.00 mA|
||±2.0000 A|
|Select the input range that corresponds to the external signal. This selection||
|should be high enough to avoid input signal overload but low enough for the|should be high enough to avoid input signal overload but low enough for the|
|desired input resolution. This selection and the position of the Input Range||
|Jumper must match.||



## **TEMPERATURE SCALE** 

## [|    |  

  

Select the temperature scale. This selection applies for Input, MAX, MIN, and TOT displays. This does not change the user installed Custom Units Overlay display. If changed, those parameters that relate to the temperature scale should be checked. 

## **DISPLAY DECIMAL POINT** 

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**----- Start of picture text -----**<br>
[|       <br> |  These selections are not<br>available for DP5T.<br> <br>**----- End of picture text -----**<br>


Select the decimal point location for the Input, **MAX** and **MIN** displays. (The **TOT** display decimal point is a separate parameter.) This selection also affects ,  and  parameters. 

## **DP5P INPUT RANGE** 

|<br><br><br><br>[|<br>|||±10.000 V<br><br>±20.000 mA<br><br>**RANGE**<br>**RESOLUTION**<br>**SELECTION**|
|---|---|
|Select the input range that corresponds to the external signal.|Select the input range that corresponds to the external signal.|



## **DP5T INPUT TYPE** 

|<br><br><br><br>[|||<br><br><br><br>[|||<br><br><br><br>[|||<br><br><br><br>[|||**SELECTION**<br><br><br>|**TYPE**<br>J TC<br>E TC<br>T TC|**SELECTION**<br><br><br>|**TYPE**<br>RTD platinum 392<br>RTD platinum 385<br>C TC|
|---|---|---|---|---|---|---|---|
||||||K TC||RTD nickel 672|
||||||R TC||RTD copper 10Ω|
||||||S TC||Direct mV range|
||||||B TC||Direct ohms range high|
||||||N TC||Direct ohms range low|



Select the input type that corresponds to the input sensor. For RTD types, check the RTD Input Jumper for matching selection. For sensor verification and testing, use the direct readout modes. 

**==> picture [222 x 70] intentionally omitted <==**

**----- Start of picture text -----**<br>
DISPLAY ROUNDING*<br>ro     <br>   <br> <br>Td<br>Bottom row selections are not<br>available for DP5T.<br> <br>**----- End of picture text -----**<br>


Rounding selections other than one, cause the Input Display to ‘round’ to the rounding increment selected (ie. rounding of ‘5’ causes 121 to round to 120 and 124 to round to 125). Rounding starts at the least significant digit of the Input Display. Remaining parameter entries (scaling point values, etc.) are not automatically adjusted to this display rounding selection. 

## **DP5T: TEMPERATURE DISPLAY OFFSET*** 

## a    to  |  |  

The temperature display can be corrected with an offset value. This can be used to compensate for probe errors, errors due to variances in probe placement or adjusting the readout to a reference thermometer. This value is automatically updated after a Zero Display to show how far the display is offset. A value of zero will remove the affects of offset. 

_11_ 

**INPUT VALUE FOR SCALING POINT 2** 

## **FILTER SETTING*** 

[|    |  

##  to  seconds 

The input filter setting is a time constant expressed in tenths of a second. The filter settles to 99% of the final display value within approximately 3 time constants. This is an Adaptive Digital Filter which is designed to steady the Input Display reading. A value of ‘0’ disables filtering. 

## **FILTER BAND*** 

## Cd    to  display units   1 

The digital filter will adapt to variations in the input signal. When the variation exceeds the input filter band value, the digital filter disengages. When the variation becomes less than the band value, the filter engages again. This allows for a stable readout, but permits the display to settle rapidly after a large process change. The value of the band is in display units. A band setting of ‘0’ keeps the digital filter permanently engaged. 

##     to   [|  

For Key-in (), enter the known second Input Value by using the arrow keys. For Apply (), adjust the signal source externally until the next desired Input Value appears. 

## **DISPLAY VALUE FOR SCALING POINT 2** 

##     to  [|  |  

Enter the second coordinating Display Value by using the arrow keys. This is the same for  and   scaling styles. 

## **General Notes on Scaling** 

1. Input Values for scaling points should be confined to the limits of the Input Range. 

The remaining parameters in Module 1 do not apply to the DP5T. 

## **SCALING STYLE** 

## [|    key-in data  apply signal   

If Input Values and corresponding Display Values are known, the Key-in () scaling style can be used. This allows scaling without the presence or changing of the input signal. If Input Values have to be derived from the actual input signal source or simulator, the Apply () scaling style must be used. After using the Apply () scaling style, this parameter will default back to  but the scaling values will be shown from the previous applied method. 

## **INPUT VALUE FOR SCALING POINT 1** 

2. The same Input Value should not correspond to more than one Display Value. (Example: 20 mA can not equal 0 and 10.) This is referred to as read out jumps (vertical scaled segments). 

3. The same Display Value can correspond to more than one Input Value. (Example: 0 mA and 20 mA can equal 10.) This is referred to as readout dead zones (horizontal scaled segments). 

4. The maximum scaled Display Value spread between range maximum and minimum is limited to 65,535. For example using +20 mA range the maximum +20 mA can be scaled to is 32,767 with 0 mA being 0 and Display Rounding of 1. (Decimal points are ignored.) The other half of 65,535 is for the lower half of the range 0 to -20 mA even if it is not used. With Display Rounding of 2, +20 mA can be scaled for 65,535 (32,767 x 2) but with even Input Display values shown. 

5. For input levels beyond the first programmed Input Value, the meter extends the Display Value by calculating the slope from the first two coordinate pairs ( /  &  / ). If  = 4 mA and  = 0, then 0 mA would be some negative Display Value. The calculations stop at the  limits of the Input Range. 

6. For input levels beyond the last programmed Input Value, the meter extends the Display Value by calculating the slope from the two sequential coordinate pairs. The calculations stop at the limits of the Input Range. 

[|     to   |  

For Key-in (), enter the known first Input Value by using the arrow keys. The Input Range selection sets up the decimal location for the Input Value. With 0.02A Input Range, 4 mA would be entered as 4.000. For Apply (), apply the input signal to the meter, adjust the signal source externally until the desired Input Value appears. In either method, press the **PAR** key to enter the value being displayed. 

_Note:_  _style - Pressing the_ **RST** _key will advance the display to the next scaling display point without storing the input value._ 

## **DISPLAY VALUE FOR SCALING POINT 1** 

[|     to   |  

Enter the first coordinating Display Value by using the arrow keys. This is the same for  and  scaling styles. The decimal point follows the  selection. 

***** _Factory Setting can be used without affecting basic start-up._ 

_12_ 

## **5.2  mOdUle 2 - User inpUT and frOnT panel fUnCTiOn Key** 

## **parameTers**  **( )** 

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**----- Start of picture text -----**<br>
2-FNC Pro<br>PARAMETER MENU<br>PAR<br>USr-1    F1    F2   rSt Sc-F1 Sc-F2<br>USER<br>FUNCTION KEYS<br>INPUT<br>**----- End of picture text -----**<br>


The user input is programmable to perform specific meter control functions. While in the Display Mode or Program Mode, the function is executed the instant the user input transitions to the active state. 

The front panel function keys are also individually programmable to perform specific meter control functions. While in the Display Mode, the primary function is executed the instant the key is pressed. Holding the function key for three seconds executes a secondary function. It is possible to program a secondary function without a primary function. 

In most cases, if the user input and/or one of the function keys is programmed for the same function, the maintained (level trigger) actions will be performed while the user input or at least one of the function keys are activated. The momentary (edge trigger) actions will be performed every time the user input or function keys transition to the active state. 

_**Note** : In the following explanations, not all selections are available for both the user input and front panel function keys. Alternating displays are shown with each selection. Those selections showing both displays are available for both. If a display is not shown, it is not available for that selection._  _will represent the user input._  _will represent all five function keys._ 

## **RELATIVE/ABSOLUTE DISPLAY** 

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**----- Start of picture text -----**<br>
   <br>   <br>**----- End of picture text -----**<br>


This function will switch the Input Display between Relative and Absolute. The Relative is a net value that includes the Display Offset Value. The Input Display will normally show the Relative unless switched by this function. Regardless of the display selected, all meter functions continue to operate based on relative values. The Absolute is a gross value (based on Module 1 **DSP** and **INP** entries) without the Display Offset Value. The Absolute display is selected as long as the user input is activated (maintained action) or at the transition of the function key (momentary action). When the user input is released, or the function key is pressed again, the input display switches back to Relative display.  (absolute) or  (relative) is momentarily displayed at transition to indicate which display is active. 

## **HOLD DISPLAY** 

## **NO FUNCTION** 

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 <br> <br>**----- End of picture text -----**<br>


    

No function is performed if activated. This is the factory setting for the user input and all function keys. No function can be selected without affecting basic start-up. 

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 <br> <br>**----- End of picture text -----**<br>


    

The shown display is held but all other meter functions continue as long as activated (maintained action). 

## **HOLD ALL FUNCTIONS** 

The meter disables processing the input and holds all display contents as long as activated (maintained action). 

## **PROGRAMMING MODE LOCK-OUT** 

  Programming Mode is locked-out, as long as activated (maintained action). A security code can be configured to   allow programming access during lock-out. 

## **SYNCHRONIZE METER READING** 

The meter suspends all functions as long as activated (maintained action). When the user input is released, the meter synchronizes the restart of the A/D with other processes or timing events. 

    

## **ZERO (TARE) DISPLAY** 

    

    

The Zero (Tare) Display provides a way to zero the Input Display value at various input levels, causing future Display readings to be offset. This function is useful in weighing applications where the container or material on the scale should not be included in the next measurement value. When activated (momentary action),  flashes and the Display is set to zero. At the same time, the Display value (that was on the display before the Zero Display) is subtracted from the Display Offset Value and is automatically stored as the new Display Offset Value (). If another Zero (tare) Display is performed, the display will again change to zero and the Display reading will shift accordingly. 

## **STORE BATCH READING IN TOTALIZER** 

        

The Input Display value is one time added (batched) to the Totalizer at transition to activate (momentary action). The Totalizer retains a running sum of each batch operation until the Totalizer is reset. When this function is selected, the normal operation of the Totalizer is overridden. 

## **SELECT TOTALIZER DISPLAY** 

    

The Totalizer display is selected as long as activated (maintained action). When the user input is released, the Input Display is returned. The **DSP** key overrides the active user input. The Totalizer continues to function independent of being displayed. 

_13_ 

## **RESET TOTALIZER** 

    

    

When activated (momentary action),  flashes and the Totalizer resets to zero. The Totalizer then continues to operate as it is configured. This selection functions independent of the selected display. 

## **RESET, SELECT, ENABLE MAXIMUM DISPLAY** 

When activated (momentary action), the Maximum value   is set to the present Input Display value. Maximum continues   from that value while active (maintained action). When the user input is released, Maximum detection stops and holds its value. This selection functions independent of the selected display. The **DSP** key overrides the active user input display but not the Maximum function. 

## **RESET AND ENABLE TOTALIZER** 

  the Totalizer resets to zero. The Totalizer continues to When activated (momentary action),  flashes and   operate while active (maintained action). When the user input is released, the Totalizer stops and holds its value. This selection functions independent of the selected display. 

>   

    

## **SELECT MINIMUM DISPLAY** 

The Minimum display is selected as long as activated (maintained action). When the user input is released, the Input Display is returned. The **DSP** key overrides the active user input. The Minimum continues to function independent of being displayed. 

## **RESET MINIMUM** 

## **ENABLE TOTALIZER** 

  The Totalizer continues to operate as long as activated (maintained action). When the user input is released, the   Totalizer stops and holds its value. This selection functions independent of the selected display. 

the Minimum reading is set to the present Input Display When activated (momentary action),  flashes and   value. The Minimum function then continues from that value.   This selection functions independent of the selected display. 

## **RESET, SELECT, ENABLE MINIMUM DISPLAY** 

## **SELECT MAXIMUM DISPLAY** 

The Maximum display is selected as long as activated   (maintained action). When the user input is released, the   Input Display returns. The **DSP** key overrides the active user input. The Maximum continues to function independent of being displayed. 

  is set to the present Input Display value. Minimum continues When activated (momentary action), the Minimum value   from that value while active (maintained action). When the user input is released, Minimum detection stops and holds its value. This selection  functions independent of the selected display. The **DSP** key overrides the active user input display but not the Minimum function. 

## **RESET MAXIMUM** 

> When activated (momentary action),  flashes and   the Maximum resets to the present Input Display value. The 

> Maximum function then continues from that value. This   selection functions independent of the selected display. 

## **RESET MAXIMUM AND MINIMUM** 

        

When activated (momentary action),  flashes and the Maximum and Minimum readings are set to the present Input Display value. The Maximum and Minimum function then continues from that value. This selection functions independent of the selected display. 

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5.3  mOdUle 3 - display and prOgram lOCK-OUT<br>    parameTers <br> ( )<br>����� PARAMETER MENU ���<br>PAR<br>   ��    ��   ���  ����<br>Max Display Min Display  Total Display  Security<br>Lock-out Lock-out Lock-out Code<br>MAXIMUM DISPLAY LOCK-OUT* PROGRAM MODE SECURITY CODE*<br>MINIMUM DISPLAY LOCK-OUT*<br>TOTALIZER DISPLAY LOCK-OUT*    to <br>       <br>**----- End of picture text -----**<br>


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MAXIMUM DISPLAY LOCK-OUT*<br>MINIMUM DISPLAY LOCK-OUT*<br>TOTALIZER DISPLAY LOCK-OUT*<br>     <br>     <br>**----- End of picture text -----**<br>


By entering any non-zero value, the prompt   will appear when trying to access the Program Mode. Access will only be allowed after entering a matching security code or universal code of . With this lock-out, a user input would not have to be configured for Program Lock-out. However, this lock-out is overridden by an inactive user input configured for Program Lock-out. 

These displays can be programmed for  or . When programmed for , the display will not be shown when the **DSP** key is pressed regardless of Program Lock-out status. It is suggested to lock-out the display if it is not needed. The associated function will continue to operate even if its display is locked-out. 

***** _Factory Setting can be used without affecting basic start-up._ 

_14_ 

**5.4  mOdUle 4 - seCOndary fUnCTiOn parameTers (**  **) PARAMETER MENU** 4-SEC Pro **NOT DP5T PAR DP5T ONLY** HI-t LO-t dSP-t b-LIt OFFSt ICE Max. Capture Min. Capture Display Update Units Label Display Offset Ice Point Delay Time Delay Time Time BackLight Value Compensation ~~ee~~ **MAX CAPTURE DELAY TIME* DISPLAY OFFSET VALUE***    to  sec. This parameter does not apply for the DP5T.   | | r—    to  When the Input Display is above the present MAX value for the entered delay time, the meter will capture that display value as the new MAX reading.  |  A delay time helps to avoid false captures of sudden short spikes. Unless a Zero Display was performed or an offset from Module 1 scaling is desired, this parameter can be skipped. The Display Offset Value is the difference from the Absolute (gross) Display value to the Relative (net) Display **MIN CAPTURE DELAY TIME*** value for the same input level. The meter will automatically update this Display   Offset Value after each Zero Display. The Display Offset Value can be directly  to  sec. keyed-in to intentionally add or remove display offset. See Relative / Absolute |  |  Display and Zero Display explanations in Module 2. 

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**----- Start of picture text -----**<br>
This parameter does not apply for the DP5T.<br>r—    to <br> | <br>Display and Zero Display explanations in Module 2.<br>DP5T: ICE POINT COMPENSATION*<br>a  <br> <br> | <br>|<br>**----- End of picture text -----**<br>


Unless a Zero Display was performed or an offset from Module 1 scaling is desired, this parameter can be skipped. The Display Offset Value is the difference from the Absolute (gross) Display value to the Relative (net) Display value for the same input level. The meter will automatically update this Display Offset Value after each Zero Display. The Display Offset Value can be directly keyed-in to intentionally add or remove display offset. See Relative / Absolute Display and Zero Display explanations in Module 2. 

When the Input Display is below the present MIN value for the entered delay time, the meter will capture that display value as the new MIN reading. A delay time helps to avoid false captures of sudden short spikes. 

**DISPLAY UPDATE RATE***   rc     updates/sec.  |  This parameter determines the rate of display update. When set to 10 updates/second, the internal re-zero compensation is disabled, allowing for the fastest possible output response. 

This parameter turns the internal ice point compensation on or off. Normally, the ice point compensation is on. If using external compensation, set this parameter to off. In this case, use copper leads from the external compensation point to the meter. 

***** _Factory Setting can be used without affecting basic start-up._ 

## **UNITS LABEL BACKLIGHT*** 

##     |  |  

The Units Label Kit Accessory contains a sheet of custom unit overlays which can be installed in to the meter’s bezel display assembly. The backlight for these custom units is activated by this parameter. 

_15_ 

## **5.5  mOdUle 5 - TOTalizer (inTegraTOr) parameTers (**  **)** 

5-tOt Pro **PARAMETER MENU** PAR dECPt tbASE SCFAC Locut P-UP Totalizer Totalizer Totalizer Totalizer Low Totalizer Power Decimal Point Time Base Scale Factor Cut Value Up Reset 

The totalizer accumulates (integrates) the Input Display value using one of two modes. The first is using a time base. This can be used to compute a timetemperature product. The second is through a user input or function key programmed for Batch (one time add on demand). This can be used to provide a readout of temperature integration, useful in curing and sterilization applications. If the Totalizer is not needed, its display can be locked-out and this module can be skipped during programming. 

## **TOTALIZER DECIMAL POINT*** 

 

##  

 

    

>   

For most applications, this matches the Input Display Decimal Point (). If a different location is desired, refer to Totalizer Scale Factor. 

## **TOTALIZER TIME BASE** 

  - seconds (÷ 1)  - hours (÷ 3600)  - minutes (÷ 60)  - days (÷ 86400) 

##  

>   

This is the time base used in Totalizer accumulations. If the Totalizer is being accumulated through a user input programmed for Batch, then this parameter does not apply. 

## **TOTALIZER SCALE FACTOR*** 

##     

##  to  

For most applications, the Totalizer reflects the same decimal point location and engineering units as the Input Display. In these cases, the Totalizer Scale Factor is 1.000. The Totalizer Scale Factor can be used to scale the Totalizer to a different value than the Input Display. Common possibilities are: 

1. Changing decimal point location (example tenths to whole) 

2. Changing engineering units (example inches to meters) 

3. Changing both decimal point location and engineering units. 

4. Average over a controlled time frame. 

Details on calculating the scale factor are shown later. 

If the Totalizer is being accumulated through a user input programmed for Batch, then this parameter does not apply. 

## **TOTALIZER LOW CUT VALUE*** 

 

##  

##  to  

>   

A low cut value disables Totalizer when the Input Display value falls below the value programmed. 

The resolution of this parameter will be affected by the input rounding factor (1-INP, round). 

## **TOTALIZER POWER UP RESET*** 

    

 Do not reset buffer  Reset buffer 

The Totalizer can be reset to zero on each meter power-up by setting this parameter to reset. 

***** _Factory Setting can be used without affecting basic start-up._ 

## **TOTALIZER HIGH ORDER DISPLAY** 

When the total exceeds 5 digits, the front panel annunciator **TOT** flashes. In this case, the meter continues to totalize up to a 9 digit value. The high order 4 digits and the low order 5 digits of the total are displayed alternately. The letter “” denotes the high order display. When the total exceeds a 9 digit value, the Totalizer will show “E . . .” and will stop. 

## **TOTALIZER BATCHING** 

The Totalizer Time Base and scale factor are overridden when a user input or function key is programmed for store batch (). In this mode, when the user input or function key is activated, the Input Display reading is one time added to the Totalizer (batch). The Totalizer retains a running sum of each batch operation until the Totalizer is reset. This is useful in weighing operations, when the value to be added is not based on time but after a filling event. 

## **TOTALIZER USING TIME BASE** 

Totalizer accumulates as defined by: 

Input Display x Totalizer Scale Factor Totalizer Time Base 

Where: 

Input Display - the present input reading Totalizer Scale Factor - 0.001 to 65.000 

Totalizer Time Base -  (the division factor of  ) 

Example: The input reading is at an average of 10.0 ° C per hour. The Totalizer is used to verify this average reading in a controlled time frame of 4 hours. Because the Input Display and Totalizer are both in tenths of ° C, the Totalizer Scale Factor is 1. However, the Totalizer Time Base is hours (3600) divided by the 4 hours in the controlled time frame to yield a Totalizer Scale Factor of 0.250. By placing these values in the equation, the Totalizer will accumulate every second as follows: 

10.0 x 0.250  = 0.00069 accumulates each second 3600 

This results in: 

- 0.04167 accumulates each minute 

- 2.5 accumulates each hour 

- 10.0 reached at the end of 4 hours 

## **TOTALIZER SCALE FACTOR CALCULATION EXAMPLES** 

1. When changing the Totalizer Decimal Point () location from the Input Display Decimal Point (), the required Totalizer Scale Factor is multiplied by a power of ten. 

Example:  Input  () = 0    Input  () = 0.0    Input () = 0.00 

|**Totalizer**<br>|**Scale**<br>**Factor**||**Totalizer**<br>|**Scale**<br>**Factor**||**Totalizer**<br>|**Scale**<br>**Factor**|
|---|---|---|---|---|---|---|---|
|0.0|10||0.00|10||0.000|10|
|0|1||0.0|1||0.00|1|
|x10|0.1||0|0.1||0.0|0.1|
|x100|0.01||x10|0.01||0|0.01|
|x1000|0.001||x100|0.001||x10|0.001|



- _(x = Totalizer display is round by tens or hundreds)_ 

2. When changing the Totalizer engineering units, the Totalizer Scale Factor is the known conversion multiplier from Input Display units to Totalizer units. Example: If Input Display is feet and the Totalizer needs to be in yards, the conversion multiplier from feet to yards is 0.333. Enter 0.333 as the Totalizer scale factor. 

3. When changing both the Totalizer engineering units and Totalizer Decimal Point the two calculations are multiplied together. Example: Input Display = feet in tenths (0.0) with Totalizer = whole yards (0), the scale factor would be 0.033. 

4. To obtain an average reading within a controlled time frame, the selected Totalizer Time Base is divided by the given time period expressed in the same timing units. 

- Example: Average temperature per hour in a 4 hour period, the scale factor would be 0.250. To achieve a controlled time frame, connect an external timer to a user input programmed for . The timer will control the start (reset) and the stopping (hold) of the totalizer. 

_16_ 

## **5.9 mOdUle 9 - faCTOry serviCe OperaTiOns (**  **)** 

9-FCS Pro PAR COdE Factory Service Code 

## **PARAMETER MENU** 

## **RESTORE FACTORY DEFAULTS** 

  Use the arrow keys to display   and press **PAR** . The meter will display  and then return to  .   Press **DSP** key to return to Display Mode. This will To overwrite all user settings with the factory settings. 

**DP5P - Input Calibration** _**WARNING**_ A 

_**WARNING** : Calibration of this meter requires a signal source with an accuracy of 0.01% or better._ 

Before starting, verify that the precision signal source is connected to the correct terminals and ready. Allow a 30 minute warm-up period before calibrating the meter.   and **PAR** can be chosen to exit the calibration mode without any changes taking place. 

## **CALIBRATION** 

  The meter has been fully calibrated at the factory. Scaling to convert the input signal to a desired display   value is performed in Module 1. If the meter appears to be [ [| indicating incorrectly or inaccurately, refer to Troubleshooting before attempting to calibrate the meter. When recalibration is required (generally every 2 years), it should only be performed by qualified technicians using appropriate equipment. Calibration does not change any user programmed parameters. However, it may affect the accuracy of the input signal values previously stored using the Apply () Scaling Style. 

Calibration may be aborted by disconnecting power to the meter before exiting Module 9. In this case, the existing calibration settings remain in effect. 

Then perform the following procedure: 

1. Use the arrow keys to display   and press **PAR** . 

2. Choose the range to be calibrated by using the arrow keys and press **PAR** . 

3. When the zero range limit appears on the display, apply the appropriate: 

- Voltage range: dead short applied 

- Current range: open circuit 

4. Press **PAR** and  will appear on the display for about 10 seconds. 

5. When the top range limit appears on the display, apply the appropriate: -  Voltage range: 10 VDC 

- Current range: 20 mADC 

6. Press **PAR** and  will appear on the display for about 10 seconds. 

7. When  appears, press **PAR** twice. 

8. If the meter is not field scaled, then the input display should match the value of the input signal. 

9. Repeat the above procedure for each input range to be calibrated. 

## **DP5D - Input Calibration** 

_**WARNING** : Calibration of this meter requires a signal source with an accuracy of 0.01% or better._ 

## **DP5T - Input Calibration** 

A 

_Warning: Calibration of this meter requires precision instrumentation operated by qualified technicians. It is recommended that a calibration service calibrates the meter._ 

Before starting, verify that the Input Ranger Jumper is set for the range to be calibrated. Also verify that the precision signal source is connected and ready. Allow a 30 minute warm-up period before calibrating the meter.   and **PAR** can be chosen to exit the calibration mode without any changes taking place. Then perform the following procedure: 

1. Use the arrow keys to display   and press **PAR** . 

2. Choose the range to be calibrated by using the arrow keys and press **PAR** . 

3. When the zero range limit appears on the display, apply the appropriate: 

- Voltage ranges: dead short applied 

- Current ranges: open circuit 

4. Press **PAR** and  will appear on the display for about 10 seconds. 

5. When the top range limit appears on the display, apply the appropriate: 

- Voltage ranges: top range value applied (The 300 V range is the exception. It is calibrated with a 100 V signal.) 

- Current ranges: top range value 

Before selecting any of the calibration procedures, the input to the meter must be at 0 mV or 0 ohms. Set the digital filer in Module 1 to 1 second. Allow a 30 minute warm-up period before calibrating the meter.  The  and **PAR** can be chosen to exit calibration mode without any changes taking place. 

## **10 OHM RTD Range Calibration** 

   1. Set the Input Range Jumper to 10 ohm. 

   2. Use the arrow keys to display   and press **PAR** . Then choose  

   - and press **PAR** . 

   3. At  , apply a direct short to input terminals 3, 4 and 5 using a three wire link. Wait 10 seconds, then press **PAR** . 

   4. At  , apply a precision resistance of 15 ohms (with an accuracy of 0.01% or better) using a three wire link, to input terminals 3, 4 and 5. Wait 10 seconds, then press **PAR** . 

   5. Connect the RTD, return to the Display Mode and verify the input reading (with 0 Display Offset) is correct. If not correct repeat calibration. 

6. Press **PAR** and  will appear on the display for about 10 seconds. 

7. When  appears, press **PAR** twice. 

8. If the meter is not field scaled, then the input display should match the value of the input signal. 

9. Repeat the above procedure for each input range to be calibrated. 

## **100 OHM RTD Range Calibration** 

1. Set the Input Range Jumper to 100 ohm. 

2. Use the arrow keys to display   and press **PAR** . Then choose  

- and press **PAR** . 

3. At  , apply a direct short to input terminals 3, 4 and 5 using a three wire link. Wait 10 seconds, then press **PAR** . 

4. At  , apply a precision resistance of 300 ohms (with an accuracy of 0.01% or better) using a three wire link, to terminals 3, 4 and 5. Wait 10 seconds, press **PAR** . 

5. Connect the RTD, return to the Display Mode and verify the input reading (with 0 Display Offset) is correct. If not correct repeat calibration. 

_17_ 

## **THERMOCOUPLE Range Calibration** 

1. Use the arrow keys to display   and press **PAR** . Then choose  and press **PAR** . 

2. At  , apply a dead short or set calibrator to zero to input terminals 4 and 5. Wait 10 seconds, then press **PAR** . 

3. At  , apply 50.000 mV input signal (with an accuracy of 0.01% or better) to input terminals 4 and 5. Wait 10 seconds, then press **PAR** . 

4. Return to the Display Mode. 

5. Continue with Ice Point Calibration. 

## **ICE POINT Calibration** 

1. The ambient temperature must be within 20 ° C to 30 ° C. 

2. Connect a thermocouple (types T, E, J, K, or N only) with an accuracy of 1 ° C or better to the meter. 

3. Verify the readout Display Offset is 0, Temperature Scale is ° C, Display Resolution is 0.0, and the Input Range is set for the connected thermocouple. 

4. Place the thermocouple in close thermal contact to a reference thermometer probe. (Use a reference thermometer with an accuracy of 0.25 ° C or better.) The two probes should be shielded from air movement and allowed sufficient time to equalize in temperature. (A calibration bath could be used in place of the thermometer.) 

5. In the Normal Display mode, compare the readouts. 

6. If a difference exists then continue with the calibration. 

7. Enter Module 9, use the arrow keys to display   and press **PAR** . Then choose  and press **PAR** . 

8. Calculate a new Ice Point value using: existing Ice Point value + (reference temperature - Display Mode reading). All values are based on ° C. 

9. Enter the new Ice Point value. 

10. Return to the Display Mode and verify the input reading (with 0 Display Offset) is correct. If not correct repeat steps 8 through 10. 

## **PARAMETER VALUE CHART** 

## **PARAMETER VALUE CHART Programmer ________________   Date ________ DP5   Model Number   _______ Meter# _____________   Security Code __________** 

##  **Signal Input Parameters** 

| **Signal Input Parameters**||
|---|---|
|**DISPLAY**<br>**PARAMETER**<br>**FACTORY**<br>**SETTING**|**USER SETTING**|
|<br>INPUT RANGE||
|<br><br>DP5T: INPUT TYPE<br> <br>||
|DP5T: TEMPERATURE SCALE<br><br><br> <br><br>||
|<br><br><br><br>*  DISPLAY RESOLUTION<br>||
|<br><br><br>DISPLAY ROUNDING INCREMENT<br>||
|<br><br>DP5T: DISPLAY OFFSET<br> <br><br>||
|<br>FILTER SETTING<br><br><br><br>FILTER ENABLE BAND||
|||
|<br>SCALING STYLE - NOT DP5T<br>||
| <br>*  INPUT VALUE 1<br> <br>||
|<br> <br><br> <br>*  DISPLAY VALUE 1<br>||
|<br> <br>*  INPUT VALUE 2<br>||
|<br><br> <br>*  DISPLAY VALUE 2<br>||
|<br>||



##  **User Input and Function Key Parameters** 

##  **Secondary Function Parameters** 

|**Secondary Function Parameters**||
|---|---|
|**FACTORY**<br>**SETTING**<br>**PARAMETER**<br>**DISPLAY**|<br>**USER SETTING**|
|<br>MAX CAPTURE DELAY TIME<br>||
|<br>MIN CAPTURE DELAY TIME<br>||
|<br>DISPLAY UPDATE TIME<br>||
|<br>UNITS LABEL BACKLIGHT  -  DP5T<br>||
|<br>DISPLAY OFFSET - NOT DP5T<br>||
|<br><br>DP5T: ICE POINT COMPENSATION||



##  **Totalizer (Integrator) Parameters** 

|**Totalizer (Integrator) Parameters**||
|---|---|
|**DISPLAY**<br>**PARAMETER**<br>**FACTORY**<br>**SETTING**|<br>**USER SETTING**|
|<br>*  TOTALIZER DECIMAL POINT<br>||
|<br><br>TOTALIZER TIME BASE<br>||
|<br>TOTALIZER SCALE FACTOR<br>||
|<br><br>*  TOTALIZER LOW CUT VALUE<br>||
|<br><br>TOTALIZER POWER-UP RESET<br>||
|||



|**DISPLAY**<br>**PARAMETER**<br>**FACTORY**<br>**SETTING**|**USER SETTING**<br>|
|---|---|
|<br>USER INPUT 1<br>||
|<br><br>FUNCTION KEY 1<br>||
|<br><br>FUNCTION KEY 2<br>||
|<br><br>RESET KEY<br>||
|<br><br>2nd FUNCTION KEY 1<br>||
|<br><br>2nd FUNCTION KEY 2<br>||
|||



*  Decimal point location is model dependent. 

##  **Display and Program Lockout Parameters** 

|**FACTORY**<br>**SETTING**<br>**PARAMETER**<br>**DISPLAY**|<br>**USER SETTING**|
|---|---|
|<br>MAX DISPLAY LOCKOUT<br>||
|MIN DISPLAY LOCKOUT<br><br> <br>||
|TOTAL DISPLAY LOCKOUT<br> <br><br>||
|<br><br>SECURITY CODE<br>||
|||



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## **TROUBLESHOOTING** 

|**TROUBLESHOOTING**||
|---|---|
|**PROBLEM**|**REMEDIES**|
|NO DISPLAY|CHECK: Power level, power connections|
|PROGRAM LOCKED-OUT|CHECK: Active (lock-out) user input<br>ENTER: Security code requested|
|MAX, MIN, TOT LOCKED-OUT|CHECK: Module 3 programming|
|INCORRECT INPUT DISPLAY VALUE|CHECK: Module 1 programming, Input Range Jumper position, input connections, input signal level,<br>Module 4 Display Offset is zero, press DSP for Input Display<br>PERFORM: Module 9 Calibration (If the above does not correct the problem.)|
|“OLOL” in DISPLAY (SIGNAL HIGH)|CHECK: Module 1 programming, Input Range Jumper position, input connections, input signal level|
|“ULUL” in DISPLAY (SIGNAL LOW)|CHECK: Module 1 programming, Input Range Jumper position, input connections, input signal level|
|JITTERY DISPLAY|INCREASE: Module 1 filtering, rounding, input range<br>CHECK: Wiring is per EMC installation guidelines|
|ERROR CODE (Err 1-4)|PRESS: Reset KEY (If cannot clear contact factory.)|



If for any reason you have trouble operating, connecting, or simply have questions concerning your new unit, contact Red Lion’s technical support. 

Email: support@redlion.net Website: www.redlion.net Inside US: +1 (877) 432-9908 Outside US: +1 (717) 767-6511 

## **LIMITED WARRANTY** 

(a) Red Lion Controls Inc. (the “Company”) warrants that all Products shall be free from defects in material and workmanship under normal use for the period of time provided in “Statement of Warranty Periods” (available at www.redlion.net) current at the time of shipment of the Products (the “Warranty Period”). **EXCEPT FOR THE ABOVE-STATED WARRANTY, COMPANY MAKES NO WARRANTY WHATSOEVER WITH RESPECT TO THE PRODUCTS, INCLUDING ANY (A) WARRANTY OF MERCHANTABILITY; (B) WARRANTY OF FITNESS FOR A PARTICULAR PURPOSE; OR (C) WARRANTY AGAINST INFRINGEMENT OF INTELLECTUAL PROPERTY RIGHTS OF A THIRD PARTY; WHETHER EXPRESS OR IMPLIED BY LAW, COURSE OF DEALING, COURSE OF PERFORMANCE, USAGE OF TRADE OR OTHERWISE.** Customer shall be responsible for determining that a Product is suitable for Customer’s use and that such use complies with any applicable local, state or federal law. (b) The Company shall not be liable for a breach of the warranty set forth in paragraph (a) if (i) the defect is a result of Customer’s failure to store, install, commission or maintain the Product according to specifications; (ii) Customer alters or repairs such Product without the prior written consent of Company. (c) Subject to paragraph (b), with respect to any such Product during the Warranty Period, Company shall, in its sole discretion, either (i) repair or replace the Product; or (ii) credit or refund the price of Product provided that, if Company so requests, Customer shall, at Company’s expense, return such Product to Company. (d) **THE REMEDIES SET FORTH IN PARAGRAPH (c) SHALL BE THE CUSTOMER’S SOLE AND EXCLUSIVE REMEDY AND COMPANY’S ENTIRE LIABILITY FOR ANY BREACH OF THE LIMITED WARRANTY SET FORTH IN PARAGRAPH (a).** 

_19_ 

## **dp5 prOgramming QUiCK OvervieW** 

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