Unigas RN510 Installation, Use & Maintenance Manual

Progressive, fully-modulating heavy oil burners

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Manual of installation - use - maintenance (45 pages)

Manual of installation - use - maintenance (48 pages)

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RN510 - RN515

RN520 - RN525

Progressive, Fully-modulating

Heavy oil Burners

MANUAL OF INSTALLATION - USE - MAINTENANCE

BURNERS - BRUCIATORI - BRULERS - BRENNER - QUEMADORES - ГОРЕЛКИ

M039215CB REL. 1.6 12/2021

Table of Contents

Summary of Contents for Unigas RN510

Page 1 RN510 - RN515 RN520 - RN525 Progressive, Fully-modulating Heavy oil Burners MANUAL OF INSTALLATION - USE - MAINTENANCE BURNERS - BRUCIATORI - BRULERS - BRENNER - QUEMADORES - ГОРЕЛКИ M039215CB REL. 1.6 12/2021...
Page 2: General Introduction
DANGERS, WARNINGS AND NOTES OF CAUTION THIS MANUAL IS SUPPLIED AS AN INTEGRAL AND ESSENTIAL PART OF THE PRODUCT AND MUST BE DELIVERED TO THE USER. INFORMATION INCLUDED IN THIS SECTION ARE DEDICATED BOTH TO THE USER AND TO PERSONNEL FOLLOWING PRODUCT INSTALLATION AND MAINTENANCE.
Page 3: Directives And Standards
3b) FIRING WITH GAS, LIGHT OIL OR OTHER FUELS DIRECTIVES AND STANDARDS Gas burners GENERAL European directives  The burner shall be installed by qualified personnel and in compliance -Regulation 2016/426/UE (appliances burning gaseous fuels) with regulations and provisions in force; wrong installation can cause -2014/35/UE (Low Tension Directive) injuries to people and animals, or damage to property, for which the -2014/30/UE (Electromagnetic compatibility Directive)
Page 4: Symbols Used
Burner data plate Type Model Gas - Light oil burners For the following information, please refer to Year European Directives the data plate: S.Number -Regulation 2016/426/UE (appliances burning gaseous fuels) Output burner type and burner model: must be  Oil Flow -2014/35/UE (Low Tension Directive) reported in any communication with the Fuel...
Page 5: Burner Model Identification
Burners are identified by burner type and model. Burner model identification is described as follows. Type RN520 Model (1) BURNER TYPE RN510 - RN515 - RN520 - RN525  N - Heavy oil, viscosity 50cSt (7° E) @ 50° C ...
Page 6: Performance Curves
Performance Curves RN510 RN515 1200 2000 2800 3600 4400 5200 1000 1800 2600 3400 4200 RN520 RN525 1600 2400 3200 4000 4800 5600 6400 7200 8000 1500 2500 3500 4500 5500 6500 7500 8500 To get the input in kcal/h, multiply value in kW by 860.
Page 7 Overall dimensions (mm) Boiler recommended boiler drilling template A(S*) A(L*) B(S*) B(L*) DD** EE** RN510 RN515 1502 1682 1152 1285 RN520 RN525 *S = measure referred to standard blast tube *L = measure referred to extended blast tube ** RN515-520-525:...
Page 8: Installing The Burner
Packing Burners are despatched in wooden crates whose dimensions are: RN510-515-520: 1720 x 1500 x 1210 (L x P x H) RN525: 1800 x 1500 x 1300 (L x P x H) Packing cases of this kind are affected by humidity and are not suitable for stacking. The following are placed in each packing case: burner;...
Page 9: Mounting Position
MOUNTING POSITION SIDE UP SIDE DOWN Burner is designed to operate with horizontal flame axis. Set the upper side of the burner flange in a horizontal position, in order to obtain the correct inclination of the pre-heating tank. For different installations, please contact the Technical Department. 1 Burner flange (upper side indicated) 2 Bracket 3 Pre-heating tank on the burner...
Page 10 Electrical connections WARNING: The burner is provided with an electrical bridge between terminals 6 and 7; when connecting the high/low flame thermostat, remove this bridge before connecting the thermostat. IMPORTANT: Connecting electrical supply wires to the burner teminal block MA, be sure that the ground wire is longer than phase and neutral ones.
Page 11 RN515-520-525: As for the connection of the pump-preheating unit, see wiring diagrams. DANGER! Incorrect motor rotation can seriously damage property and injure people. Fan and pump motors direction Once the electrical connection of the burner is performed, remember to check the rotation of the motor. The motor should rotate in an counterclockwise direction looking at cooling fan.
Page 12: Oil Pumps
Bleeding in two-pipe operation is automatic : it is assured by a bleed flat on the piston. In one-pipe operation, the plug of a pressure gauge port must be loosened until the air is evacuated from the system. Oil pumps RN510: SUNTEC TA3 RN515: SUNTEC TA4 RN520 - RN525: SUNTEC TA5 Suntec TA..
Page 13 About the use of fuel pumps Make sure that the by-pass plug is not used in a single pipe installation, because the fuel unit will not function properly and damage  to the pump and burner motor could result. Do not use fuel with additives to avoid the possible formation over time of compounds which may deposit between the gear teeth, ...
Page 14 Connections to the oil gun Gun with the oil nozzle inside Oil manifold Inlet Return Gun opening Heating wire (only for high density oil burners) Cartdrige-type heater (only for oil with viscosity > 110 cSt) Recommendations to design heavy oil feeding plants This paragraph is intended to give some suggestions to make feeding plants for heavy oil burners.
Page 15 ning, the execution and the winding dimensioning and other construcitve details must be provided by the installer. Adjusting the supplying oil ring According to the heavy oil viscosity used, in the table below indicative temperature and pressure values to be set are shown. Note: the temperature and pressure range allowed by the supplying ring components must be checked in the specifications table of the components themselves.
Page 16 VISCOSITY vs TEMPERATURE DIAGRAM FOR COMBUSTIBLE OILS 1000 PUMPING LIMIT TEMPERATURE (°C) LIGHT OIL 1,3°E AT 20°C HEAVY OIL 2,4°E AT 50°C HEAVY OIL 4°E AT 50°C HEAVY OIL 7,5°E AT 50°C HEAVY OIL 10°E AT 50°C HEAVY OIL 13°E AT 50°C HEAVY OIL 22°E AT 50°C HEAVY OIL 50°C HEAVY OIL 47°E AT 50°C...
Page 17 sity, the oil temperature at the pump inlet should be 80°C (see diagram). OIL TEMPERATURE FOR PUMP FEEDING TEMPERATURE (°C) Fig. 10 Indicative diagram showing the oil pressure according to its temperature PRESSION D’ALIMENTATION POMPE PUMP FEEDING PRESSURE Max. for T and TA pumps Max.
Page 18 HYDRAULIC DIAGRAMS Fig. 13 3ID00014 v2 Hydraulic diagram - Two or more burners configuration BURNER 2 SEE THE BURNER 1 SEE THE BURNER P&ID BURNER P&ID HEATING MEDIUM INLET HEATING MEDIUM OUTLET PRESSURE GOVERNOR UNIT OIL PUMPING UNIT DAILY TANK UNIT OIL PUMPING UNIT HEATING MEDIUM INLET PIPE HEATING SYSTEM: SEE THE SPECIFIC...
Page 19 Fig. 14 - 3ID0023 v2 - Hydraulic diagram - Single burner configuration BURNER 1 SEE THE BURNER P&ID OIL TRAIN Main tank OIL PUMPING UNIT Manual valve Filter Pump coupled to electrical motor Safety valve HEATING MEDIUM INLET One-way valve Manual valve HEATING MEDIUM OUTLET Pressure gauge...
Page 20 Fig. 15 (as far as reading the pressure values, see next paragraphs). DELIVERY RETURN NOZZLE PRESSURE PRESSURE MIN. FLUIDICS WR2/UNIGAS M3 7 - 9 (indicative values) FLUIDICS NOZZLE: REFERENCE DIAGRAM (INDICATIVE ONLY) Atomisation angle FLOW RATE kg/h Indicative DIMENSIONS...
Page 21 trolled by thyristor. (for details refer to the attached technical documentation) Fig. 15 - Danfoss MCX Fig. 16 - Probe connections (Danfoss MCX)(for burners with 1 tank) Nafta TCN - TRS Nafta Fig. 17 - Probe connections (Danfoss MCX)(for burners with 2 tanks)
Page 22 Oil viscosity at 50 °C according to the letter shown in the burner model Menu path > 50 cSt > 110 cSt > 400 cSt 89 cSt < 50 cSt < 110 cSt < 400 cSt < 4000 cSt > 7 °E >...
Page 23 ADJUSTING AIR AND FUEL RATE ATTENTION: before starting the burner up, be sure that the manual cutoff valves are open. Be sure that the mains switch is closed. .ATTENTION: During commissioning operations, do not let the burner operate with insufficient air flow (danger of formation of carbon monoxide);...
Page 24 Oil Flow Rate Settings by means of Berger STM30../Siemens SQM40.. actuator Check the fan motor rotation. Prime the oil pump acting on the related contactor (CP - see next picture): check the pump motor rotation (see “Fan and pump motors direction” on page 11) and keep pressing for some seconds until the oil circuit is charged; bleed the air from the M pressure gauge port (Fig.
Page 25 SQM40.265 Actuator cams Version with flame control LMO 24.255 / 44.255 Version with flame control LAL 2.25 (RD) I High flame (RD) I High flame (BU) II Stand-by (BU) II Stand-by (OG) III Low flame (OG) III Low flame (YE) IV (YE) IV (BK) V (BK) V...
Page 26 ”MIN” position ”MAX” position Attention! if it is necessary to change the head position, repeat the air and gas adjustments described above. 13 as for the point-to-point regulation in order to set the cam foil shape, move the low flame microswitch (cam III) a little lower than the maximum position (90°);...
Page 27 Calibration of air pressure switch To calibrate the air pressure switch, proceed as follows: Remove the transparent plastic cap.  Once air and heavy oil setting have been accomplished, startup the burner.  During the pre-purge phase o the operation, turn slowly the adjusting ring nut VR in the ...
Page 28: Oil Circuit
Oil circuit The fuel is pushed into the pump 1 to the nozzle 3 at the delivery pressure set by the pressure governor. The solenoid valve 2 stops the fuel immission into the combustion chamber. The fuel flow rate that is not burnt goes back to the tank through the return circuit. The spill-back nozzle is feeded at constant pressure, while the return line pressure is adjusted by means of the pressure governor controlled by an actuator coupled to an adjusting cam.
Page 29: Limitations Of Use
PART II: OPERATION PART II: OPERATION LIMITATIONS OF USE THE BURNER IS AN APPLIANCE DESIGNED AND CONSTRUCTED TO OPERATE ONLY AFTER BEING CORRECTLY CONNEC- TED TO A HEAT GENERATOR (E.G. BOILER, HOT AIR GENERATOR, FURNACE, ETC.), ANY OTHER USE IS TO BE CONSIDE- RED IMPROPER AND THEREFORE DANGEROUS.
Page 30: Control Panel
PART II: OPERATION Control panel RN510 High flame lamp Low flame lamp Ignition transformer operation CMF Manual operation switch 0= Off 1= High flame 2= Low flame 3= Automatic Fan motor thermal cutout intervention Burner lockout Burner in stand-by IRA Auxiliary resistors wsitch...
Page 31: Routine Maintenance
PART III: MAINTENANCE PART III: MAINTENANCE At least once a year carry out the maintenance operations listed below. In the case of seasonal servicing, it is recommended to carry out the maintenance at the end of each heating season; in the case of continuous operation the maintenance is carried out every 6 months.
Page 32: Self-Cleaning Filter
PART III: MAINTENANCE Self-cleaning filter Fitted only on high viscosity oil burners. Periodically turn the knob to clean the filter. Removing the combustion head  Remove the cover H.  Slide the photoresistor out of its housing.  Unscrew the oil connections E (Fig. 26) connecting the flexible pipes to the gun L and remove the whole assembly as shown in Fig. ...
Page 33 PART III: MAINTENANCE Removing the oil gun, replacing the nozzle and the electrodes ATTENTION: avoid the electrodes to get in touch with metallic parts (blast tube, head, etc.), otherwise the boiler operation would be compromised. Check the electrodes position after any intervention on the combustion head. To remove the oil gun, proceed as follows: remove the combustion head as described on the prevoius paragraph;...
Page 34: Seasonal Stop
PART III: MAINTENANCE Checking the detection current To check the flame itensity signal, follow the diagram shown on the next picture. If the measured value is lower than the suggested one, check the photoresistor position, the electrical contacts. Replace the photoresistor if necessary. 34 35 Siemens LAL2..
Page 35: Troubleshooting
PART III: MAINTENANCE TROUBLESHOOTING Heavy oil operation  MAIN SWITCH OPEN  LINE FUSE INTERVENTION   MAX. PRESSURE SWITCH FAULT  FAN THERMAL CUTOUT INTERVENTION  AUXILIARY RELAIS FUSES INTERVENTION      CONTROL BOX FAULT  SERVOCONTROL FAULT ...
Page 36 APPENDIX t3’ Long preignition time: «Z» connected to terminal 15. Postignition time: SIEMENS LAL.. CONTROL BOX - «Z» must be connected to terminal 15 - With short preignition, «Z» remains on until «TSA» has elapsed connec- Control and supervision of oil atomization burners tion to terminal 16.
Page 37 4 A max., 20 A peak Internal fuse T6,3H250V according to IEC 127 During burner off times, the flame supervision circuit is live. External fuse max. 10 A Weight Device 1000 g Lockout indication Plug-in base 165 g Q R C 1 ... Startup sequence b r1 b-b’...
Page 38 Postpurge time (with «M2») Interval between start command and voltage at terminal 7 (start delay time for «M2») Duration of startup sequence (excluding «t11» and «t12») Interval from startup to the beginning of the air pressure check Air damper running time to the OPEN position Air damper running time to the low-fire position (MIN) Permissible afterburn time Interval to the OPEN command for the air damper...
Page 40 C.I.B. UNIGAS S.p.A. Via L.Galvani, 9 - 35011 Campodarsego (PD) - ITALY Tel. +39 049 9200944 - Fax +39 049 9200945/9201269 web site: www.cibunigas.it - e-mail: cibunigas@cibunigas.it Note: specifications and data subject to change. Errors and omissions excepted.
Page 41 CIB UNIGAS 600V CONTROLLER USER’S MANUAL COD. M12925CA Rel 1.2 08/2014 SOFTWARE VERSION 1.0x code 80379 / Edition 01 - 06/2012 1 • INSTALLATION 2 • TECHNICAL SPECIFICATIONS Display 2x4 digit green, high display 10 and 7mm Keys 4 of mechanical type (Man/Aut, INC, DEC, F) •...
Page 42 3 • DESCRIPTION OF FACEPLATE Function indicators Indication of output states Indicates modes of operation OUT 1 (AL1); OUT 2 (OPEN); OUT 3 (CLOSED) MAN/AUTO = OFF (automatic control) ON (manual control) PV Display: Indication of process variable Error Indication: LO, HI, Sbr, Err PRE-HEATING = ON (running) LO= the value of process variable is <...
Page 43: Programming And Configuration
5 • “EASY” PROGRAMMING and CONFIGURATION S4 Jumper THE EASY CONFIGURATION (Pro=0...12) IS SUITABLE FOR (CPU) VERSIONS WITH AL1/OPEN/CLOSED LEVEL 1 MENU P.V. / S.V. Process variable P.V. / S.V. (PV display) Work Setpoint (SV display) or control output value with controller in manual Password Local Setpoint...
Page 44 • InFo Display Information display Software version 0 No Error Self diagnostic 1 Lo error code 2 Hi 3 ERR 4 SBR OUTPUT 2 OUTPUT 3 SERIAL COMMUNICATION 0 = None 0 = None 0 = None +8 error OUT2 card recognition 1 = Relay 1 = Relay +16 error OUT3 card recognition...
Page 45 • InP Input settings S, R range 0...1750°C; error < 0.2% f.s. (t > 300°C) / for other sp. r 0 default (remote setpoint present) Def. remote setpoint range; error < 0.5% f.s. error < 0.2% f.s. (t > -150°C) range 44...1800°C;...
Page 46 • Out Output settings Select a1. r reference signal for alarm1 AL.1.r AL.x.r Variable to be compared PV (process variable) AL.1.t AL.x.t Direct (high limit) Absolute or Normal 2/3 for a1. t Inverse (low limit) relative to Symmetrical alarm 1 active setpoint (window) direct...
Page 47 • Prot Protection code Prot Display Modification SP, Hy.P, Hy.n, AL.2, AL.3, PoS, OuP, INF SP, Hy.P , Hy.n, AL.2, AL.3, PoS SP, Hy.P, Hy.n, AL.2, AL.3, PoS, OuP, INF SP, OuP, INF + 4 to disable InP, Out + 8 to disable CFG + 16 to disable SW “power-up - power down”...
Page 48 ld. 1 Function of LEDs Val. Function none MAN/AUTO controller ld. 2 HOLD Selftuning enabled Autotuning enabled ld. 3 Error present Softstart running Set point gradient running Pre-heating running + 16 LED flashes if active • Lin Custom linearization for main input Step 0 beginning Display limits s.
Page 49 7 • CONSENT FOR BURNER AL1 Obtain burner consent by configuring alarm 1 as inverse deviation with positive hysteresis Hy.P and negative hysteresis Hy.n 8 • PRE-HEATING FUNCTION Enable the pre-heating function by setting parameters GS.0, Ht.0, GS.1 other than zero. It consists of three phases that are activated sequentially at firing: - Ramp 0 phase Enabled by setting GS.0 >...
Page 50 9 • ADJUSTMENT WITH MOTORIZED VALVE In an adjustment process the adjustment valve has the function of varying fuel delivery (frequently corresponding to the thermal energy introduced into the process) in relation to the signal coming from the controller. For this purpose it is provided with an actuator able to modify its opening value, overcoming the resistances produced by the fluid passing inside it.
Page 51: Control Actions
Valve control modes With the controller in manual, the setting of parameter At.y ≥ 8 allows direct control of the valve open and close commands through the keyboard Increments and Decrements on the front seats. V0 - for floating valve without potentiometer Model V0 have similar behaviour: every manoeuvre request greater than the minimum impulse t.Lo is sent to the actuator by means of the OPEN/CLOSE relays;...
Page 52: Manual Tuning
11 • MANUAL TUNING A) Enter the setpoint at its working value. B) Set the proportional band at 0.1% (with on-off type setting). C) Switch to automatic and observe the behavior of the variable. It will be similar to that in the figure: Process D) The PID parameters are calculated s follows: Proportional band Variable...
Page 53 15 • ACCESSORIES • Interface for instrument configuration Kit for PC via the USB port (Windows environment) for GEFRAN instruments configuration: KIT PC USB / RS485 o TTL Lets you read or write all of the parameters • A single software for all models •...
Page 55 21/06/2012 rev. 0 Set-up for 600V RRR0-1-T73 regulator Set up for temperature probe Pt100 (ex Siemens QAE2120 130°C max.) The regulator comes out of the factory preset with the corresponding values of the Siemens RWF40.000 and RWF50.2x Verify wiring of the sensor Regulation of the set-point = 80 It can be modified by using arrows "up"...
Page 56: Manual Operation
A1.r … A1.t 3 (operating mode AL1 =inverse-relative-normal) … rL.1 2 (AL1) rL.2 18 (open) rL.3 19 (close) A.ty 9 (type of servocontrol command) Ac.t 12 (servocontrol running time: SQN72.4…/STA12..=12; SQM40.265=30) t_Lo t_Hi t.on t.oF dE.b 0,1 (dead zone in % of end scale) 99 then push and keep pushed F until visualization of Hrd …...
Page 57 Set up for temperature probe Pt100 for high temperature (350°C max.) Verify wiring of the sensor Regulation of the set-point = 80 It can be modified by using arrows "up" and "down". By pushing F you go to parameters: Hy.P 10 (hysteresis positive for output 1 terminals 21-22 (ex Q13-Q14) Hy.n -5 (hysteresis negative for output 1 terminals 21-22 (ex Q13-Q14)
Page 58 A1.r … A1.t 3 (mode AL1 =inverse-relative-normal) … rL.1 2 (AL1) rL.2 18 (open) rL.3 19 (close) A.ty 9 (type of servocontrol command) Ac.t 12 (servocontrol running time: SQN72.4…/STA12..=12; SQM40.265=30) t_Lo t_Hi t.on t.oF dE.b 0,1 (dead zone in % of end scale) 99 then push and keep pushed F until visualization of Hrd …...
Page 59 Set up for pressure transmitter 2 wires signal 4÷20mA With pressure transmitters first we need to enable their power supply: remove the part as shown below, then, on the CPU unit, move the bridge from Pt100 to +Vt IN/OUT cards Signal selection on terminal 3 Verify wiring of the sensor...
Page 60 …. 44 (4÷20mA) … dP_S 2 (decimals num.) Transmitter 1,6bar 3bar 10bar 16bar 25bar 40bar Lo.S 0,00 0,00 0,00 0,00 0,00 0,00 min. sensor scale Hi.S 1,60 3,00 10,00 16,00 25,00 40,00 max sensor scale offset of input correction Lo.L 0,00 0,00 0,00...
Page 61 Set -up for thermocouples type Verify wiring of the sensor Regulation of the set-point = 80 It can be modified by using arrows "up" and "down". By pushing F you go to parameters: Hy.P 10 (hysteresis positive for output 1 terminals 21-22 (ex Q13-Q14) Hy.n -5 (hysteresis negative for output 1 terminals 21-22 (ex Q13-Q14) Keep pushing F until you see PASS, release F and through the arrows set 99, push F and visualize Pro...
Page 62 A1.r … A1.t 3 (mode AL1 =inverse-relative-normal) … rL.1 2 (AL1) rL.2 18 (open) rL.3 19 (close) A.ty 9 (type of servocontrol command) Ac.t 12 (servocontrol running time: SQN72.4…/STA12..=12; SQM40.265=30) t_Lo t_Hi t.on t.oF dE.b 0,1 (dead zone in % of end scale) 99 then push and keep pushed F until visualization of Hrd …...
Page 65 RWF50.2x & RWF50.3x User manual M12922CB Rel.1.0 07/2012...
Page 66: Device Installation
DEVICE INSTALLATION Install the device using the relevant tools as shown in the figure. To wire the device and sensors, follow the instructions on the burner wiring diagram.
Page 67: Front Panel
FRONT PANEL NAVIGATION MENU Parameter level Basic display User Level - Opr SP1 or SP2 (editable) dSP readable and editable through bin1 = 2 InP1 or y (only display) Parameter Level - PArA HYS1 , HYS2 , HYS3 Pb1, dt, rt, db, tt Next parameter Main navigation...
Page 68 RWF5 is preset good for 90% of applications. However, you can set or edit parameters as follow: Set-point: set or modification: When the burner is in stand-by, (safety loop open, that is terminals 3-4/T1-T2 on the 7 pole plug open) push the Enter button: on the lower display (green) Opr appears;...
Page 69 Setting the kind of sensor to be connected to the device:  push the Enter button: on the lower display (green) Opr appears. Using the up and down arrows find ConF. Push Enter to confirm.  Now on the green display the group InP appears. Push Enter and InP1 is displaied. Enter to confirm. ...
Page 70 ConF > Cntr Parameter Value Description CtYP 1 = 3-position controller (open-stop-close only RWF50.2) controller type 2 = continuative action controller (only RWF50.3) CACt 1 = heating controller control action 0 = cooling controller least value of the set-point limitation prevents entry of values outside the defined set-point range -1999..0..+9999 range...
Page 71 ConF > OutP (parameter under group only for RWF50.3) Parameter Value Description FnCt 1 = analog input 1 doubling with possibility to convert tipo di controllo (depending on par SiGn) 4 = modulation controller SiGn physical output signal (terminals A+, A-) type of output signal 0 = 0÷20mA 1 = 4÷20mA...
Page 72 Manual control :  in order to manual change the burner load, while firing keep pushing the ESC button for more than 5 s; on the lower green display Hand appears.  using the UP and DOWN arrows, the load varies. ...
Page 73 Electric connection : With 7 pins connector version With terminals version Matches terminals between RWF50.2 and RWF40.0x0...
Page 74 Parameters summarising for RWF50.2x: Conf Conf Navigation menù Inp1 Cntr diSP PArA Types of probe SEn1 OFF1 SCL1 SCH1 Unit dECP Pb. 1 dt HYS1 (*) HYS3 (*) SP1 (*) Siemens QAE2120… needless needless 80 350 (#) 80 °C Siemens QAM2120.. needless needless 80 350 (#)
Page 75 APPENDIX: PROBES CONNECTION To assure the utmost comfort, the control system needs reliable information, which can be obtained provided the sensors have been installed correctly. Sensors measure and transmit all variations encountered at their location. Measurement is taken based on design features (time constant) and according to specific operating conditions.With wiring run in raceways, the sheath (or pipe) containing the wires must be plugged at the sensor's terminal board so that currents of air cannot affect the sensor's measurements.
Page 76 Duct or pipe sensors Installing pressure sensors A - installation on ducts carrying fluids at max. temperature 80°C Installing temperature sensors For measuring outlet air: B - installation on ducts at temperature over 80°C and for refrigerants  after delivery fan or C - installation on ducts at high temperatures: ...
Page 77 Immersion or strap-on sensors Immersion probes installation Sensors must be installed on the stretch of pipe in which fluid circulates all the time. The rigid stem (sensing element doing the measuring) must be inserted by at least 75mm and must face the direction of flow. Recommended locations: on a bend or on a straight stretch of pipe but tilted by 45°...
Page 78 Duct pressure switches and sensors Installing differential pressure probes for air Basic principles Measuring static pressure(i.e. pressure exerted by air on pipe walls) A - Control a filter (clogging) Measuring dinamic pressure B - Control a fan (upstream/downstream) Kg/m , specific weight of air m/s, air speed 9.81 m/s gravity acceleration...
Page 79 Spare parts Description Code Modulator RWF50.2 (uscita a 3 punti - apri, fermo, chiudi) 2570148 2570149 Modulator RWF50.3 (uscita continua 0÷20mA, 4÷20mA, 0÷10V) Temperature probe Siemens QAE2120.010A (30÷130°C) 2560101 2560135 Temperature probe Siemens QAM2120.040 (-15÷+50°C) 2560188 Thermoresistor Pt1000 ø6mm L100mm (30÷130°C) Thermoresistor Pt1000 ø10mm L200mm (0÷350°C) 2560103 2560145...
Page 80 Note: Specifications and data subject to change. Errors and omissions excepted.
Page 81 KM3 Modulator USER MANUAL M12927CA Rel.1.0 10/2020...
Page 82 M12927CA MOUNTING...
Page 83: Outp Ut Leds
M12927CA DISPLAY Y AND KEY onsent to the burner is rned off OUTP UT LEDs ON (o out1) - Consen nt to the burne ▲ - (o out2) Output i ncrease ▼ - (o out3) Output d decrease ● - (ou ut4) Modulato r is powered o perator Mode...
Page 84: Probe Connection
M12927CA CONNECTIONS DIAGRAM Probe connection: • PT1000/NTC/PTC: between terminal 3 and 2 • PT 100: between terminal 3 and 2 with terminal 1 • Passive pressure probe 0/4-20 mA: between terminal 4 ( + ) e 1 ( - ) Note: out4 must be activated ( IO4F must be setted to ON ) •...
Page 85: Operation Example
M12927CA SETPOINT AND HYSTERESIS CONFIGURATION (SP, AL1, HAL1 parameters) Push the button to enter into the setpoint configuration: SP setpoint value change: increase decrease 2480 Confirm / Next AL1 parameter value change: increase decrease Confirm / Next HAL1 HAL1 parameter value change: increase decrease Confirm / Next Back to the first parameter To return to normal mode, press the key for 3 seconds or wait the 10s timeout...
Page 86 M12927CA LIMITED ACCESS LEVEL Proceed as follows to change some parameters that are not visible in standard user mode: Press the key for Password = 20 3 seconds Access to parameter: Increase the displayed value Decrease the displayed value Confirm and go to next parameter Param Description...
Page 87 M12927CA...
Page 88: Configuration Parameters
M12927CA CONFIGURATION How to access configuration level The configuration parameters are collected in various groups. Every group defines all parameters related with a specific function (e.g.: control, alarms, output functions). Push the button for more than 5 seconds. The upper display will show PASS while the lower display will show 0.
Page 89 M12927CA Safety output value -100... 100 io4.F I/O4 function selection on = Out4 will be ever ON (used as a transmitter power supply) ,out4 = Uscita 4 (Used as digital output 4), dG2c = Digital input 2 for contact closure, dG2U = Digital input 2 driven by 12... 24 diF1 Digital input 1 function oFF = Not used,...
Page 90 M12927CA windows SE.br = Sensor Break LodE = Deviation low alarm (relative) HidE = Deviation high alarm (relative) LHdo = Relative band alarm in alarm out of the band LHdi = Relative band alarm in alarm inside the band Alarm 1 function 0...
Page 91 M12927CA AL3 Group - alarm 3 parameters Param Description Values Liv N° Default AL3t Alarm 3 type nonE = Alarm not used nonE LoAb = Absolute low alarm HiAb = Absolute high alarm LHAo = Windows alarm in alarm outside the windows LHAI = Windows alarm in alarm inside the windows...
Page 92 M12927CA SELF Self tuning enabling no = The instrument does not perform the self- tuning YES = The instrument is performing the self- tuning Proportional band 1... 9999 (E.U.) page 7 Integral time 0 (oFF) ... 9999 (s) page 7 Derivative time 0 (oFF) ...
Page 93 M12927CA AAc = Alarm reset ASi = Alarm acknowledge chSP = Sequential set point selection St.by = Stand by mode. The first press puts the instrument in stand by mode while a second one puts the instrument in Auto mode. Str.t = Timer run/hold/reset P.run = Program run P.rES = Program reset...
Page 94 M12927CA con Group - Consumption parameters Param Description Values N° Default Co.tY Count type oFF = Not used 1 = Instantaneous power (kW) 2 = Power consumption (kW/h) 3 = Energy used during program execution. This measure starts from zero when a program runs end stops at the end of the program.
Page 95: Automatic Mode
M12927CA OPERATIVE MODES When the instrument is powered, it starts immediately to work according to the parameters values loaded in its memory. The instrument behaviour and its performance are governed by the value of the stored parameters. At power ON the instrument can start in one of the following mode depending on its configuration: Automatic Mode In Automatic mode the instrument drives automatically the control output according to the parameter value set and the set point/measured value.
Page 96: Manual Mode
M12927CA Direct set point modification This function allows to modify rapidly the set point value selected by [83] A.SP (selection of the active Set point) or to the set point of the segment group (of the programmer) currently in progress. Push button.
Page 97: List Of Possible Errors
M12927CA ERROR MESSAGES The upper display shows the OVER-RANGE and UNDERRANGE conditions with the following indications: Over-range: Under-range The sensor break will be signalled as an out of range: Note: When an over-range or an under-range is detected, the alarms operate as in presence of the maximum or the minimum measurable value respectively.
Page 98 RWF55.5X & RWF55.6X User manual M12926CA Rel.0.1 10/2015...
Page 99 DEVICE INSTALLATION Fixing system Drilling dimensions:...
Page 100 FRONT PANEL Burner release Controlling element CLOSED/stage 1 Controlling element OPEN/stage 2 Operating mode 2-stage Actual value display (red) and parameter value USB led Comunication via interface Operating mode 2-stage Thermal shock protection Alarm function Decrease value Increase value ESC button Enter button...
Page 101 NAVIGATION MENU User Level - Opr Parameter level SP1 or SP2 (editable) dSP readable and editable through bin1 = 2 InP1 or y (only display) Basic display Parameter level - PArA Pb1, dt, rt, db, tt Heating controllerHYS1 , HYS2 , HYS3 Cooling controller HYS4 , HYS5 , HYS6...
Page 102 PID parameters set and modifications (PArA): Push Enter button, on the green display Opr appears; using the down arrow, scroll until group PArA is reached and push Enter. On the green display Pb1 e appears and on the red one the set parameter. Push is sequence the down or up arrow the menu is scrolled. Push Enter to select and the arrows to choose the desired value.
Page 103 Setting the kind of sensor to be connected to the device: Push the Enter button: on the lower display (green) Opr appears. Using the up and down arrows find ConF. Push Enter to confirm. Now on the green display the group InP appears. Push Enter and InP1 is displaied. Enter to confirm.You are inside InP1; the green display shows Sen1 (sensor type), while the red display shows the chosen sensor code Push Enter to enter the Sen1 parameter, then choose the desired sensor using the arrows.
Page 104 ConF > InP >InP2 Input 2 : this input can be used to specify an external setpoint or carry out setpoint shifting Parameter Value Description no function FnC2 external setpoint (display SPE) setpoint shifting (display dSP) angular positioning feedback SEn2 0 ÷...
Page 105 ConF > Cntr Here, the type of controller, operating action, setpoint limits and presettings for self-optimization are selected Parameter Value Description CtYP 3-position controller (open-stop-close) ontroller type continuative action controller (0 ÷10V 4 ÷ 20mA) heating controller CACt control action cooling controller minimum set-point scale -1999..0..+9999...
Page 106 Alarm functionAF The alarm function can be used to monitor the analog inputs. If the limit value is exceeded, multifunctional relay K6 (terminals 6N and 6P) is activated (depending on the switching characteristic) The alarm function can have different switching functions (lk1 to lk8) and can be set to a deviation from the active setpoint or to a fixed limit value Limit value AL relative to setpoint (x) Fixed limit value AL...
Page 107 ConF > AF Parameter Value Description FnCt Without function type of control monitored input Ik1 = InP1 monitored input Ik2 = InP1 monitored input Ik3 = InP1 monitored input Ik4 = InP1 monitored input Ik5 = InP1 monitored input Ik6 = InP1 monitored input Ik7 =...
Page 108 ConF > binF This setting decides on the use of the binary inputsD1, D2, DG Parameter Value Description without function bin1 binary imput terminals set-point changeover (SP1 / SP2) – D1) set-point shift (Opr > dSP parameter = value of set-point modify) 2 = l input alarm changeover of operating mode...
Page 109 ConF > IntF The controller can be integrated into a data network using an optional RS-485 (terminals R+ and R-) interface or an optional Profibus DP interface(only modelRWF55.6x terminalsC1-C2-C3-C4) Parameter Value Description bdrt 0 = 4800 baud baudrate 1 = 9600 baud 2 = 19200 baud 3 = 38400 baud Address in the data network...
Page 110 Display of software version : The software version is shown by pushing Enter + UP arrow on the upper display Weather-compensated setpoint shifting(climatic regulation): The RWF55 can be configured so that weather-compensated setpoint shifting is activated when an LG-Ni1000 outside sensor or a Pt1000 is connected (see parameter InP3).
Page 111 Modbus interface The tables that follow in this chapter specify the addresses of the readable and writable words that the customer is able to access. The customer may read and/or write the values using SCADA programs, PLCs, or similar. The entries under Access have the following meanings: R/O Read Only, value can only be read R/W Read/Write, value can be read and written The number of characters specified under Data type in the case of character strings includes the final \0.
Page 112 Configuration level Address Access Data type Signal reference Parameter 0x3426 Float SCL1 Start of display input 1 0x3428 Float SCH1 End of display input 1 0x3432 Float SCL2 Start value input 2 0x3434 Float SCH2 End value input 2 0x3486 Float Start of setpoint limitation 0x3488...
Page 113 Dati dell’apparecchio Address Access Data type Signal reference Parameter 0x8000 Char12 Software version 0x8006 Char14 VdN number Stato dell’apparecchio Address Access Data type Signal reference Parameter 0x0200 Word Outputs and states Bit 0 Output 1 Bit 1 Output 3 Bit 2 Output 2 Bit 3 Output 4...
Page 114 Electric connections : With 7 pins connector version With terminals version Corrispondences bornes entre RWF55.5x y RWF40.0x0Matches terminals betweenRWF55.5x and RWF40.0x0...
Page 115 Parameters summarising for RWF55.xx : ConF ConF Navigation menù Inp1 Cntr diSP PArA Types of probe SEn1 OFF1 Unit dECP Pb. 1 HYS1 (*) HYS3 (*) SP1 (*) ...
Page 116 APPENDIX: PROBES CONNECTION To assure the utmost comfort, the control system needs reliable information, which can be obtained provided the sensors have been installed correctly. Sensors measure and transmit all variations encountered at their location. Measurement is taken based on design features (time constant) and according to specific operating conditions.With wiring run in raceways, the sheath (or pipe) containing the wires must be plugged at the sensor's terminal board so that currents of air cannot affect the sensor's measurements.
Page 117 Duct or pipe sensors Installing pressure sensors Installing temperature sensors A - installation on ducts carrying fluids at max. temperature 80°C For measuring outlet air: B - installation on ducts at temperature over 80°C and for refrigerants "after delivery fan or C - installation on ducts at high temperatures : "after coil to be controlled, at a distance of at least 0,5 m ·"increase length of siphon...
Page 118 Immersion or strap-on sensors Immersion probes installation Sensors must be installed on the stretch of pipe in which fluid circula- tes all the time. The rigid stem (sensing element doing the measuring) must be inser- ted by at least 75mm and must face the direction of flow. Recommended locations: on a bend or on a straight stretch of pipe but tilted by 45°...
Page 119 Duct pressure switches and sensors Installing differential pressure probes for air Basic principles Measuring static pressure(i.e. pressure exerted by air on pipe walls) A - Control a filter (clogging) Measuring dinamic pressure B - Control a fan (upstream/downstream) Legend Kg/m3, specific weight of air m/s, air speed 9.81 m/s2 gravity acceleration mm C.A., dynamic pressure...
Page 121 Note: Specifications and data subject to change. Errors and omissions excepted.
Page 122 MANUALE USER SUPPORT MULTI-THERMOSTAT MCX06C MCX06C is a multi-thermostat with four 100k NTC inputs. It can control up to 4 temperatures showing them (not more than 2 at the same time) on a couple of displays. It is used to check and adjust oil heater temperatures. it works as follows: as soon as the burner control gives the GO to the digital 1 input (terminals DI1-COM), the adjustment program runs (the relevant LED is ON).
Page 123 Connections from terminal side : 24V AC Probe connection: input AI1 = probe Pb1 = set-point “tr” = oil heater temperature probe; input AI2 = probe Pb2 = set-point “tCI” = plant consent temperature probe (when installed); input AI3 = probe Pb3 = set-point “OIL” = oil heater output temperature probe (PID regulation); input AI4 = probe Pb4 = set-point “tcn”...
Page 124 (tCI - Pb2 probe only for mechanical atomizing burners) Menu : To enter the menu below, keep pushing ENTER for more than 3 s. Menu code Sub-menu code Function Notes Probes values You can see in sequence the 4 probe values (UP and DOWN keys): the probe code is on display A (Pb1,..., Pb4) and the probe value is on display B (not fitted or out...
Page 125 submenu CnF - configuration parameters group : Visibility Password Modbus Menu Parameter Description Additional description Default U.M. condition level index CONFIGURATION Analog Input 1 This parameter enables or disables the Probe 1 Presence probe Calibration Probe 1 Don't modify it -20,0 20,0 °C...
Page 126 Visibility Modbus Menu Parameter Description Additional description Default U.M. condition Level index Autotuning Output temperature hysteresis Don't modify it 50,0 °C Startup number Don't modify it Measurement cycles number Don't modify it Max. differential command Don't modify it exit 0,01 10,00 10,00 Differential reduction exit...
Page 127 Submenu REG – regulation parameters group : Visibility Modbus Menu Parameter Description Additional description Default U.M. condition Level index REGULATION Probe 1 Set-point Probe 1 Don't modify it (Tank resistor) -50,0 200,0 °C Probe 1 - Low Temperature Alarm Don't modify it Threshold -50,0 200,0...
Page 128 Visibility Modbus Menu Parameter Description Additional description Default U.M. condition Level index Overshooting for Integral action Don't modify it (Oil tank exit) 1000 Derivative action enabling Don't modify it (Oil tank exit) Filtering factor for derivative action Don't modify it (Oil tank exit) Duty cicle PWM for output DO3 Don't modify it...
Page 129 Alarms & Warning: When the red triangle on the top left lights, one or more alarms are activated. When the red key on the left lights, the output N05-C5 is active and the relay KTRS switches the resistors OFF. Check the reason, correct the failure and, as soon as the temperature is lower than trS, reset it through ALA/rES . In order to show active alarms and warnings, select the relevant menu through ALA/Act.and, using the UP and DOWN buttons, scroll the lines.

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