FCLI CASSETTE-TYPE FAN COIL WITH INVERTER. FCLI 82 (840x840) FCLI 122 (840x840) FCLI 124 (840x840)

TECHNICAL MANUAL CASSETTE-TYPE FAN COIL WITH INVERTER FCLI FCLI 2 (600x600) FCLI 4 (600x600) FCLI 42 (600x600) FCLI 44 (600x600) FCLI 62 (600x600) FCLI 64 (600x600) FCLI 82 (840x840) FCLI 122 (840x840) FCLI 124 (840x840) IFCLITY1106-010_01 Replace 010_00 / 1006

AERMEC is involved in the Eurovent programme: FCU Products covered by the programme can be found on the site www.eurovent-certification. com

The Aermec FCLI fan coil is made with materials of superior quality in strict compliance with safety regulations. FCLI fan coil is easy to use and will have a long life. Thanks to Aermec's FCLI range of inverter fan coils, brushless technology can now make inroads in the field of chilled water air conditioning, bringing notable energy savings along with the precise control of both air temperature and humidity in the air-conditioned rooms. TABLE OF CONTENTS DECLARATION OF CONFORMITY 4 Transport Safety symbols Important information Maintenance 6 Description of the unit Main components Description of components 8 System examples 9 How to choose 10 Operating limits 10 Technical data (2-pipe versions) 11 Technical data (4-pipe versions) 12 Cooling capacity 1 Heating capacity 29 Coil pressure drops 1 Correction factors when operating using glycol water Sound power level Sound pressure level 4 Accessories Installation information 4 Installing the "Module 600" unit 44 Installing the "Module 840" unit 46 Hydraulic conections 48 Condensate discharge connections 48 Conections for the suction of fresh external air 48 Conections for the delivery of treated air to an adjacent room 48 Electrical wirings 49 Electrical connections with GLLI accessories 0 Electrical connections with GLLI_N accessories 0 Installing and disassembling the filter for replacement or maintenance 1 Dimensions 2 Wiring diagrams 4 Alarm codes REMARKS Keep the manuals in a dry place - to maintain their good condition - for at least 10 years, for any future reference needs. Carefully and thoroughly read all the information referred to in this manual. Pay particular attention to the instructions for use accompanied by the words DANGER or WARNING because, if they are not complied with, the machine/property can damaged and/or people can be injured. For any irregularities not foreseen by this manual, promptly contact your local After Sales Service. The device must be installed in such a way that maintenance and/or repair operations are possible. The device warranty does not in any case cover costs resulting from the use of automatic ladders, scaffolding or any other lifting system necessary for carrying out repairs under warranty. AERMEC S.p.A. declines all liability for any damage due to improper use of the machine, or the partial or superficial reading of the information contained in this manual. This manual contains the following number of pages: 60.

FCLI AERMEC S.p.A. I-040 Bevilacqua (VR) Italia Via Roma, 996 Tel. (+9) 0442 6111 Telefax (+9) 0442 90 (+9) 0442 966 www.aermec. com - info @aermec. com DICHIARAZIONE DI CONFORMITÀ Noi, firmatari della presente, dichiariamo sotto la nostra esclusiva responsabilità, che il prodotto: VENTILCONVETTORE serie FCLI al quale questa dichiarazione si riferisce è conforme alle seguenti norme armonizzate: - CEI EN 60-2-40 - CEI EN 014-1 - CEI EN 014-2 - CEI EN 61000-6-1 - CEI EN 61000-6-2 - CEI EN 61000-6- - CEI EN 61000-6-4 soddisfando così i requisiti essenziali delle seguenti direttive: - Direttiva LVD 2006/9/CE - Direttiva compatibilità elettromagnetica 2004/108/CE FCLI CON ACCESSORI E fatto divieto di mettere in servizio il prodotto dotato di accessori non di fornitura Aermec. CERTIFICAT DE CONFORMITÉ Nous soussignés déclarons sous notre exclusive responsabilité que le produit: VENTILO-CONVECTEURS série FCLI auquel cette déclaration fait référence, est conforme aux normes harmonisées suivantes: - EN 60-2-40 - EN 014-1 - EN 014-2 - CEI EN 61000-6-1 - CEI EN 61000-6-2 - CEI EN 61000-6- - CEI EN 61000-6-4 satisfaisant ainsi aux conditions essentielles des directives suivantes: - Directive LVD 2006/9/CE - Directive compatibilité électromagnétique 2004/108/CE FCLI PLUS ACCESSOIRES Il est interdit de faire fonctionner l'appareil avec des accessoires qui ne sont pas fournis de Aermec. DECLARACIÓN DE CONFORMIDAD Los que suscriben la presente declaran bajo la propia y exclusiva responsabilidad que el conjunto en objeto, definido como sigue: FAN COIL serie FCLI al que esta declaración se refiere, está en conformidad a las siguientes normas armonizadas: - EN 60-2-40 - EN 014-1 - EN 014-2 - CEI EN 61000-6-1 - CEI EN 61000-6-2 - CEI EN 61000-6- - CEI EN 61000-6-4 - EN 61000-6- al que esta declaración se refiere, está en conformidad a las siguientes normas armonizadas: - Directiva LVD 2006/9/CE - Directiva compatibilidad electromagnétic 2004/108/CE FCLI CON ACCESORIOS Está prohibido poner en marcha el producto con accesorios no suministrados por Aermec. CONFORMITY DECLARATION We the undersigned declare, under our own exclusive responsibility, that the product: FAN COIL FCLI series to which this declaration refers, complies with the following standardised regulations: - EN 60-2-40 - EN 014-1 - EN 014-2 - CEI EN 61000-6-1 - CEI EN 61000-6-2 - CEI EN 61000-6- - CEI EN 61000-6-4 thus meeting the essential requisites of the following directives: - Directive LVD 2006/9/CE - EMC Electromagnetic Compatibility Directive 2004/108/CE FCLI WITH ACCESSORIES It is not allowed to use the unit equipped with accessories not supplied by Aermec. KONFORMITÄTSERKLÄRUNG Wir, die hier Unterzeichnenden, erklären auf unsere ausschließlich Verantwortung, dass das Produkt: GEBLÄSEKONVEKTOR der Serie FCLI auf das sich diese Erklärung bezieht, den folgenden harmonisierten Normen entspricht: - EN 60-2-40 - EN 014-1 - EN 014-2 - CEI EN 61000-6-1 - CEI EN 61000-6-2 - CEI EN 61000-6- - CEI EN 61000-6-4 womit die grundlegenden Anforderungen folgender Richtlinien erfüllt werden: - Richtlinie LVD 2006/9/CE - Richtlinie zur elektromagnetischen Verträglichkeit 2004/108/CE FCLI + ZUBEHÖR Falls das Gerät mit Zubehörteilen ausgerüstet wird, die nicht von Aermec geliefert werden, ist dessen Inbetriebnahme solange untersagt. Bevilacqua, 02/0/2011 La Direzione Commerciale Sales and Marketing Director Luigi Zucchi 4 IFCLITY1106-010_01

TRASPORTO CARRIAGE TRANSPORT TRANSPORT TRANSPORTE NON bagnare. Tenere al riparo NON calpestare dalla pioggia Do NOT step Do NOT wet NE PAS marcher sur cet emballage CRAINT l humidité Nicht betreten Vor Nässe schützen NO pisar NO mojar FCLI FCLI (600x600) (840x840) Sovrapponibilità: controllare sull imballo per conoscere il numero di macchine impilabili Stacking: control the packing to know the number of machines that can be stacked Empilement: vérifier sur l emballage pour connaître le nombre d appareils pouvant être empilés Stapelung: Die Anzahl der stapelbaren Geräte, wird durch die Symbole auf den Verpackungen ermittelt Apilamiento: observe en el embalaje para saber cuántos equipos pueden apilarse NON lasciare gli imballi sciolti durante il trasporto - Non rovesciare Do NOT leave loose packages during transport ATTACHER les emballages pendant le transport Die Verpackungen nicht ungesichert transportieren NO lleve las cajas sueltas durante el transporte >2Kg NON trasportare la macchina da soli se il suo peso supera i 2 Kg DO NOT handle the machine alone if its weight is over 2 Kg NE PAS transporter tout seul l appareil si son poids dépasse 2 Kg Das Gerät NICHT alleine tragen, wenn sein Gewicht 2 Kg überschreitet NO maneje los equipos en solitario si pesan más de 2 kg Fragile, maneggiare con cura Fragile, handle with care Fragile, manipuler avec soin Zerbrechlich, mit Sorgfalt behandeln Frágil, manejar con cuidado Freccia: alto Arrow: high Flèche: haut Pfeil: hoch Flecha: alto SIMBOLI DI SICUREZZA SAFETY SYMBOL SIMBOLES DE SECURITE SICHERHEITSSYMBOLE SÍMBOLOS DE SEGURIDAD Pericolo: Pericolo: Pericolo!!! Tensione Organi in movimento Danger: Danger: Danger!!! Power supply Movings parts Danger: Danger: Danger!!! Tension Organes en mouvement Gefahr! Gefahr! Gefahr!!! Spannung Rotierende Teile Peligro: Peligro: Peligro!!! Tensión Elementos en movimiento PACKAGE The fan coils are shipped in standard package which consists of expanded polystyrene foam and cardboard shells. IFCLITY1106-010_01

IMPORTANT INFORMATION AND MAINTENANCE WARNING: electrical wirings, installation of the fan coils and relevant accessories should be performed by a technician who has the necessary technical and professional expertise to install, modify, extend and maintain systems, and who is able to check the systems for the purposes of safety and correct operation. WARNING: the fan coil is connected to the power supply and a water circuit. Operations performed by persons without the required technical skills can lead to personal injury to the operator or damage to the unit and surrounding objects. WARNING:before carrying out any work, put the proper individual protection equipment on. WARNING: the device must be installed in compliance with the national plant engineering rules. WARNING: check that the power supply is disconnected before carrying out any procedures on the unit. WARNING: Install a device, main switch, or electric plug so you can fully disconnect the device from the power supply. WARNING! DANGER! Any use of the unit not expressly indicated by Aermec is strictly prohibited. ONLY SUPPLY THE FAN COIL WITH SINGLE-PHASE 20 VOLT ELECTRICITY Any other type of power supply could permanently damage the fan coil. DO NOT USE THE FAN COIL IMPROPERLY Do not use the fan coil for animal husbandry applications (e.g. incubation). AIRING THE ROOM Periodically air the room in which the fan coil has been installed. This is particularly important if the room is occupied by many people, or if gas appliances or sources of odours are present. ADJUST TEMPERATURE ADEQUATELY The external temperature should be adjusted in order to provide maximum comfort to the people in the room, especially if they are elderly, children or sick people; avoid differences over C between the outdoor temperature and the temperature inside the room in summer. In summer, a temperature that is too low causes higher electrical consumption. CORRECTLY ADJUST THE AIR JET Air coming out from the fan coil must not reach people directly; in fact, even if the air is warmer than the room temperature, it could cause a cold sensation and result in discomfort. DO NOT USE EXCESSIVELY HOT WATER Clean the fan coil with a soft cloth or sponge soaked in water not over 40 C. Do not use chemical products or solvents to clean any part of the fan coil. Do not spray water on the outer or inner surfaces of the fan coil (this might cause short circuits). CLEAN THE FILTER PERIODICALLY Cleaning the filter frequently guarantees enhanced operating efficiency. Check whether the filter is very dirty: in this case, clean it more often. Clean frequently; remove the accumulated dust with a vacuum cleaner. Once the filter is clean, refit it on the fan coil following the removal instructions but in reverse order. SUPPLEMENTARY CLEANING The fact that the blades of examinable shrouds can be removed (operation done only by adequately skilled technicians) ensures a thorough cleaning of the internal components, which is particularly important when installing the unit in crowded areas or venues requiring high hygiene standards. DURING OPERATION Always leave the filter fitted on the fan coil during operation (otherwise dust in the air could soil the coil surface area). WHAT IS NORMAL In cooling mode, water vapour may be present in the air delivery of the fan coil. In the heating operation, a slight hiss might be heard close to the fan coil. Sometimes the fan coil might give off unpleasant smells due to the accumulation of substances present in the air of the room (clean the filter more often, especially if the room is not ventilated regularly). While the unit is functioning, there could be noises and creaks inside the device due to the various thermal expansions of the elements (plastic and metal), but this does not indicate any malfunction and does not damage the unit unless the maximum input water temperature is exceeded. MALFUNCTIONING In the case of malfunctioning remove the power to the unit then re-power it and start the apparatus up again. WARNING! Do not attempt to repair the unit alone, this is extremely dangerous! If the problem occurs again, call the local Aftersales Service immediately. DO NOT TUG THE ELECTRICAL CABLE It is very dangerous to pull, tread on or crush the electric power cable, or fix it with nails or drawing pins. A damaged power cable can cause short circuits and injure people. DO NOT OBSTRUCT THE AIR OUTLETS BY PLACING OBJECTS INTO THEM Do not put anything in the air outlet slots. This could injure people and damage the fan. WARNING Avoid any use of the device by children or incompetent persons without appropriate supervision; also note that the unit should not be used by children as a toy. WARNING: reserved for the After Sales service only. There are 2 LEDs on the Inverter card (Alarm / Power) that indicate the unit's operating status. The table for the decoding of messages is found in Chapter Installation. 6 IFCLITY1106-010_01

DESCRIPTION OF THE UNIT PURPOSE OF THE FCLI CASSETTE-TYPE MODULATING FAN COIL The fan coil is a room air treatment terminal unit for both winter and summer operation. The FCLI cassette-type modulating fan coil range with brushless inverter motor are different from traditional fan coils because they offer better climatic and noise comfort, and energy savings. FCLI CASSETTE-TYPE FAN COILS Cassette-type fan coil with Inverter for installation in suspended ceilings; greater sizes can be integrated in standard 600x600 and 840x840 panelling. The FCLI cassette-type fan coil is a room air treating unit. The FCLI concentrates high technological and functional characteristics that make it the ideal climate control unit for all types of room. The supply of climate-controlled air is distributed throughout the room thanks to the delivery fins which face four directions.the FCLI generates heat if included in a heating system with boiler or heat pump, but may also be used in the summer as an air conditioner if the heating system has a water chiller. The fan coils are designed for 2- and 4-pipe systems. The unit is installed in a suspended ceiling with the possibility to send conditioned air to adjacent rooms and introduce external air regardless of unit ventilation. ADVANTAGES - The temperature is maintained with the utmost precision, the continuous modulation fan speed prevents surges due to changes in speed or the succession of on-off cycles. - The noise comfort is significant, since there are no abrupt changes between the different speeds, the noise changes from one speed to another or the change between off and on cannot be heard. The type of motor and control system used also allows a minimum rotation speed much less than that of traditional models (even less than half) and therefore, not only is the noise well below average, but above all so is the sensation of effective sound (e.g. if in a bedroom the traditional fan coil alternates minimum speed cycles and fan off cycles, we don't perceive the average noise, but the noise when running at minimum speed remains imprinted). - Energy savings through the use of the brushless motor that allows for greater efficiency, even under normal conditions. For comparison we have made an exhibitor that we will use during fairs and events where we have installed two of our fan coils of the same size, one with a brushless motor and the other with a traditional motor. With both motors at the same speed (and thus equal airflow) the reduction in power consumption by the fan coil with brushless motor exceeds 0%. The inverter is a system that automatically reduces the rotational speed and power consumption allowing the fan coil to work reduced, with considerable savings on annual operating costs. The more efficient distribution system helps to improve the energy class of the building. The electronic speed control ensures and controls the starting phase, avoiding the absorption peaks typical of this phase that occur with asynchronous motors. Obviously, these benefits assume increasing advantages in the installation as the number of FCLI fan coils increases. AVAILABLE SIZES The cassette-type fan coils of the FCLI range are available in two versions: for 2-pipe systems FCLI 2 (600x600) FCLI 42 (600x600) FCLI 62 (600x600) FCLI 82 (840x840) FCLI 122 (840x840) For 4-pipe systems FCLI 4 (600x600) FCLI 44 (600x600) FCLI 64 (600x600) FCLI 124 (840x840) MANDATORY ACCESSORY GLLI 10 (600x600) GLLI 20 (840x600) Grille unit with intake and delivery filter, with manually adjustable fins, colour RAL 9010. The accessory also includes the electric box for the unit. CONTROL PANEL The FCLI unit requires an external control panel with thermostat and ventilation speed control with 0-10V output. See the accessories list for selection. VERSIONS The cassette fan coils are available in three versions, to satisfy all system requirements. The sizes, performance levels and outer dimensions are the same as those for the standard FCL version. In this manual, versions FCLI_VL and FCLI_V2 will only be referred to when there are differences compared with the standard FCLI version; otherwise they will simply be called FCLI. Versions FCLI_VL and FCLI_V2 are available upon request. Standard FCLI version, with standard internal -way valve fitted with fast connection actuator and visual position signalling. FCLI_V2 version, with standard internal 2-way valve fitted with fast connection actuator and visual position signalling, suitable for systems with a variable water flow rate. FCLI_VL version, without an internal valve. IFCLITY1106-010_01

MAIN COMPONENTS 1 Grille with air filter (GLLI) 2 Air delivery deflector (GLLI) Grille frame (GLLI) 4 Tray Inverter device 6 Base unit Fastening brackets 8 Electrical box 9 Water connections (only for 4 pipes) 10 Water connections (2 pipes) 11 Air drain valve 12 Push-out, coupling for air delivery in an adjacent room 1 Condensate drain FCLI (module 600) GLLI 10 12 11 10 9 8 1 6 4 1 2 FCLI (Module 840) GLLI 20 12 10 11 9 8 1 6 4 2 1 DESCRIPTION OF COMPONENTS BASE The unit is characterised by a reinforced, integral metal structure with insulation in expanded polystyrene obtained from injection moulding for purposes of noise reduction and air routing. The load-bearing base is in galvanised sheet steel and is varnished with polyester powders. The following are fixed to the base: fixing brackets, coils, motor and fan, condensate discharge pump, attachment plate, control board unit and condensate drip tray. By means of the flanges, it allows the channels (for renewing environmental air and/ or delivery to an adjacent room) to be joined to the sides. FASTENING BRACKETS Galvanised steel brackets for attaching the unit to the ceiling. TRAY Tray closing off the unit. Made of injection co-moulded polystyrene to avoid thermal dispersion and the formation of condensate, it conveys conditioned air towards the fins and from the condensate drip tray. The air suction conveyor is equipped with a protective grille that impedes access to the moving fan. THERMAL EXCHANGE COIL The coils used have copper pipes and corrugated or turbulent aluminium fins. They are designed to offer the maximum heat exchange surface. All batteries are provided with air bleed pipes and water drain valves, located respectively on the highest and lowest point of the battery circulation. INTERNAL THREE-WAY VALVE Standard on standard versions. Internal all-or-nothing type -way valve, with fast connection actuator and visual signalling of the position, assembled as standard on the heating/cooling coil. Powered with a voltage of 20V ~ 0Hz. FAN UNIT The fan unit, with the latest axialcentrifugal fan designed to obtain lowsound emissions, is dynamically and statically balanced. The fan unit can be easily accessed for cleaning and maintenance. BRUSHLESS ELECTRIC MOTOR WITH INVERTER CONTROL The "brushless electric motor with Hall sensors" and the control system used in the AERMEC FCXI fan coils 8 IFCLITY1106-010_01

is a combination of sophisticated technologies in the field of mechanics and electronics entirely developed within the industrial group. This is a permanent magnet motor with low starting current and easy speed adjustment. Not affected by electromagnetic interference. The fact that it is brushless allows lower friction and less wear. With the special inverter device, it is possible to control the speed and torque of the rotor continuously, just by means of the stator currents. The electric motor is cushioned with elastic supports and the steel shaft is mounted on bushings and resistance to salt fog is tested in accordance with ASTM B11/64. The "brushless electric motor with Hall sensors" used in AERMEC FCXI modulating fan coils has huge advantages over conventional AC motors and hybrid inverter motors (without Hall sensor) normally used on other modulating fan coils: - reduced wear and tear - The possibility to regulate the rotation speed in a precise, continuous manner (0-100%) - higher energy yields - Longer life and greater reliability - Low magnetic noise - Continuous monitoring of the rotor position implies greater efficiency, and guaranteed and controlled starting - Guaranteed minimum speed 90 rpm (for thermodynamic reasons, this limit was raised to 200 rpm). CONDENSATE DISCHARGE DEVICE The condensate discharge device disposes of the condensate that is produced by the unit and deposited in the polystyrene basin. This unit is composed of a control board, a non return valve, a three level float and a pump with 800 mm. max. head. The unit can easily be connected to the condensate discharge system by means of a plastic coupling (ext. Ø 16mm). ALARM: when the level of condensate in the tray reaches the prefixed limit, the alarm will stop the flow of water to the battery, allowing only the fan to function. HYDRAULIC CONNECTIONS The attachment plate groups together the water connections and the vent of the coil's primary circuit for 2-pipe and 4-pipe systems. The plates contain raised symbols that identify the input (IN) and output (OUT) water connections for the water. GLLI10 - GLLI20 (Obligatory accessory) Intake and delivery grille unit with electric box The form and opening of the suction louvres were developed in order to have the best possible distribution of the air, both when functioning in winter as well as in summer. Suction occurs through the central grille, and delivery through the manually adjustable, perimetric slots. The plastic, colour RAL 9010, grille contains the air filter that can be easily removed for cleaning. Incorporated electric box with control board for electrical connections. The GLLI needs to be interfaced with an external control panel (not included) with thermostat and ventilation speed control, with a 0-10V output. GLLI10N - GLLI20N (VMF System obligatory accessory) Intake and delivery grille unit with incorporated VMF System-type thermostat. To be combined with the VMF-E4 control panel. The GLLI_N grille has the same characteristics as GLLI range grilles. Incorporated electric box with thermostat board and connectors for electrical connections. For characteristics, see the section on accessories. FILTERING SECTION Mechanical air filter with ABS frame, colour RAL9010. Filter in filtering class G1, selfextinguishing class V0 (UL94). Easily removable and made from regenerable materials. May be cleaned by washing. SYSTEM EXAMPLE Key: SA Ambient probe SW Water probe VHL -way valve (Hot/Cold) FCLI (Standard) 2-pipe system 4-pipe system SA SA SA V2 VHL1 VHL2 2-pipe system 2-way valve (Hot/Cold) hot -way valve hot 2-way valve FCLI (V2) 4-pipe system SA VHL SW VHL1 VHL V2 SW VHL2 V2 FCLI (VL) without valves 2-pipe system 4-pipe system SA SA SW SW IFCLITY1106-010_01 9

HOW TO CHOOSE The main technical data of the FCLI range are summarised in the tables and diagrams. The sensible and total cooling capacities at maximum speed depending on the incoming water temperature, thermal head and the dry bulb and wet bulb temperature of the air respectively for sensible and total yield are shown in the table. The performances at the average and minimum speed are obtained by multiplying the table values by the corrective factors indicated. The water side pressure drops are shown in the diagrams. The correction factors when the unit operates with glycol water for cooling and heating function modes are shown in the graphs in percentages of glycol of 10%, 20% and %. The heating capacity based on the water flow rate and temperature difference between the inlet water and inlet air is shown in a graphical form and refers to the maximum speed; the performances at average and minimum speeds are obtained by multiplying the values obtained from the chart at maximum speed by the corrective factors indicated. The pressure level and sound power of the fan coils at different speeds is shown in the tables. A wide range of accessories is available for the FCLI fan coils, but in certain cases some of them cannot be used simultaneously. Check the accessories are compatible with the fan coil chosen. The manual contains a description of each accessory, plus a drawing and its compatibility. The installation information is included in the manuals supplied together with each fan coil or its accessory. This manual is limited to provide general information in order to obtain a correct installation; it also contains drawings with fan coil dimensions and the wiring diagrams with the connections to control panels. OPERATING LIMITS FCLI 2 4 42 44 62 64 82 122 124 Maximum water inlet temperature C 80 Maximum recommended water inlet temperature C 6 Maximum operating pressure bar 8 Minimum water flow rate (heating) l/h 100 0 100 0 10 0 20 20 20 Maximum water flow rate (heating) l/h 0 400 0 400 100 400 10 240 400 Minimum water flow rate (cooling) l/h 100 100 100 100 10 10 20 0 20 Maximum water flow rate (cooling) l/h 0 0 0 0 100 100 10 240 10 External temperature limits (Ta) C 0 < Ta < 40 Relative humidity limits in the room (R.H.) R.H. < 8% Power supply 20V ( ±10% ) ~ 0 Hz Maximum input current A 0.22 0.22 0. 0. 0. 0. 0. 0. 0. Performance values refer to the following conditions: - at the maximum motor speed; - the total input power is determined by adding the input power for the unit and the input power for the accessories connected and declared in the corresponding manuals. Water temperature In order to prevent air stratification in the room, and therefore to achieve improved mixing, it is advisable not to supply the fan coil with water at a temperature over 6 C. The use of water at high temperatures could cause squeaking due to the different thermal expansions of the elements (plastic and metal). This does not however cause damage to the unit if the maximum water inlet temperature is not exceeded (see table). Minimum average water temperature If the fan coil is working in continuous cooling mode in an environment where the relative humidity is high, condensate might form on the air delivery and on the outside of the device. This condensate might be deposited on any objects underneath and on the floor. To avoid condensate on the external structure of the device while the fan is functioning, the average temperature of the water must not be lower than the limits shown in the table below, that depend on the thermo-hygrometric conditions of the external air. These limits refer to unit operating with fan at minimum speed. MINIMUM AVERAGE WATER TEMPERATURE Ambient air temperature with dry bulb 21 2 2 2 29 1 1 1 Ambient air temperature with wet bulb 19 21 6 4 2-8 6 10 IFCLITY1106-010_01

TECHNICAL DATA FCLI 2-pipe versions FCLI 2 42 62 82 122 Heating Speed 4 W - 490 620 100 1000 Heating output 0 C Speed W 280 940 480 00 1000 Speed 2 W 160 00 80 480 8800 Speed 1 W 10 220 00 00 600 Speed 4 kpa - 2 2 2 4 Pressure drop (VL) Speed kpa 9 16 21 1 24 Speed 2 kpa 6 10 1 11 1 Speed 1 kpa 4 6 10 6 9 Cooling Speed 4 W - 90 4980 6000 11000 Cooling capacity Speed W 1900 20 940 490 890 Speed 2 W 140 240 210 400 00 Speed 1 W 1160 1960 2660 2800 60 Speed 4 W - 160 810 4200 840 Sensible cooling capacity Speed W 120 260 2810 00 680 Speed 2 W 120 1820 220 20 0 Speed 1 W 990 180 1860 1900 4040 Speed 4 l/h - 69 8 102 1892 Water flow rate Speed l/h 2 9 68 824 19 Speed 2 l/h 2 4 2 69 1290 Speed 1 l/h 200 48 482 922 Speed 4 kpa - 2 6 2 8 Pressure drop (VL) Speed kpa 10 18 24 1 26 Speed 2 kpa 11 16 12 19 Speed 1 kpa 4 12 6 10 Common data Fans no. 1 1 1 1 1 Speed 4 m/h - 00 880 1100 10 Air flow rate Speed m/h 600 0 660 80 10 Speed 2 m/h 410 60 00 680 1100 Speed 1 m/h 00 260 80 460 0 Speed 4 db(a) - 61 0 60 Sound power Speed db(a) 46 46 4 4 4 Speed 2 db(a) 8 8 4 4 0 Speed 1 db(a) 41 9 44 Speed 4 db(a - 44 2 41 1 Sound pressure Speed db(a 4 6 4 Speed 2 db(a 29 29 8 4 41 Speed 1 db(a) 26 26 2 0 Speed 4 W - 8 10 1 Input power Speed W 4 4 10 12 Speed 2 W 1 2 80 10 Speed 1 W 21 22 26 4 Input current (max speed) A 0.22 0. 0. 0,0 0. Starting current A 0.66 0.99 1.11 2.10 2.2 Power supply V / Hz 20V~0Hz Maximum protection level IP 20 20 20 20 20 Heat exchanger water content L 1.2 1. 2.1 4. Water connections Ø gas /4 /4 /4 /4 /4 Kvs (-way valve, standard version) 2. 2. 2. 4 4 Kvs (2-way valve, V2 version) 2. 2. 2. 2. 2. = Performance certified EUROVENT 6/ - Sound tests certified EUROVENT 8/2 (ISO 41/2001) Performance values refer to the following conditions: Level of sound pressure (A-weighted) measured in the room with volume V = 100 m, reverberation time t = 0. s; direction factor Q = 2; distance r = 2.m Cooling: External air temperature 2 C D.B. ; 19 C W.B. Water inlet temperature C ; t water K The leakage current to earth of several devices placed under the same circuit breaker is summed, so attention should be paid to the calibration of the circuit breaker and possibly consider the division of the installation into several circuits each of which protected by its own circuit breaker. Heating 0 C: External air temperature 20 C Water inlet temperature: 0 C; t water 10 K Heating 0 C: External air temperature 20 C Water inlet temperature: 0 C; t water 10 K IFCLITY1106-010_01 11

TECHNICAL DATA FCLI 4-pipe versions FCLI 4 44 64 124 Heating Speed 4 W - 00 800 1200 Heating output 0 C Speed W 2600 20 80 10400 Speed 2 W 2190 2290 2990 900 Speed 1 W 190 1960 2640 00 Speed 4 l/h - 264 2 10 Water flow rate Speed l/h 224 2 291 894 Speed 2 l/h 188 19 2 800 Speed 1 l/h 168 169 22 606 Speed 4 kpa - 14 21 29 Pressure drop (VL) Speed kpa 11 12 1 21 Speed 2 kpa 8 8 14 1 Speed 1 kpa 6 6 11 10 Cooling Speed 4 W - 60 4610 8800 Cooling capacity Speed W 1900 000 640 20 Speed 2 W 140 240 290 6220 Speed 1 W 1160 1810 2460 40 Speed 4 W - 2920 0 60 Sensible cooling capacity Speed W 120 2180 2600 20 Speed 2 W 120 1680 2100 460 Speed 1 W 990 120 120 0 Speed 4 l/h - 628 9 114 Water flow rate Speed l/h 2 16 626 120 Speed 2 l/h 2 402 11 100 Speed 1 l/h 200 11 42 86 Speed 4 kpa - 22 1 8 Pressure drop (VL) Speed kpa 10 1 21 2 Speed 2 kpa 10 14 20 Speed 1 kpa 4 6 10 12 Common data Fans no. 1 1 1 1 Speed 4 cu.m/h - 00 880 10 Air flow rate Speed cu.m/h 600 0 660 10 Speed 2 cu.m/h 410 60 00 1100 Speed 1 cu.m/h 00 260 80 0 Speed 4 db(a) - 61 60 Sound power Speed db(a) 46 46 4 4 Speed 2 db(a) 8 8 4 0 Speed 1 db(a) 41 44 Speed 4 db(a) - 44 2 1 Sound pressure Speed db(a) 4 4 Speed 2 db(a) 29 29 8 41 Speed 1 db(a) 26 26 2 Speed 4 W - 8 1 Input power Speed W 4 4 12 Speed 2 W 1 2 10 Speed 1 W 21 22 26 Input current (max speed) A 0.22 0. 0. 0. Starting current A 0.66 0.99 1.11 2.2 Power supply V / Hz 20 ~ 0Hz Maximum protection level IP 20 20 20 20 Heat exchanger water content L 1.2 1. 2.1 4. Water connections (cold circuit) Ø gas /4 /4 /4 /4 Water connections (hot circuit) Ø gas 1/2 1/2 1/2 1/2 Kvs (-way valve, standard version) 2. 2. 2. 4 Kvs (2-way valve, V2 version) 2. 2. 2. 2. Performance values refer to the following conditions: Level of sound pressure (A-weighted) measured in the room with volume V = 100 m, reverberation time t = 0. s; direction factor Q = 2; distance r = 2.m Cooling: External air temperature 2 C D.B. ; 19 C W.B. Water inlet temperature C ; t water K The leakage current to earth of several devices placed under the same circuit breaker is summed, so attention should be paid to the calibration of the circuit breaker 12 = Performance certified EUROVENT 6/ - Sound tests certified EUROVENT 8/2 (ISO 41/2001) IFCLITY1106-010_01 and possibly consider the division of the installation into several circuits each of which protected by its own circuit breaker. Heating 0 C: External air temperature 20 C Water inlet temperature: 0 C; t water 10 K Heating 0 C: External air temperature 20 C Water inlet temperature: 0 C; t water 10 K

COOLING CAPACITY - FCLI 2 / FCLI4 Tw 9 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 126 1281 119 14 126 126 14 14 122 122 19 19 1 1969 124 196 144 1961 161 19 1808 191 191 19 19 19 2448 1264 2442 1444 246 162 240 1800 2424 19 2420 2062 21 29 140 294 1609 299 186 291 196 2929 202 2 49 191 49 1 481 1948 4 20 1 11 1164 14 14 1404 1404 102 102 16 16 128 128 1 18 114 181 1 1 10 18 111 180 180 182 182 19 220 1169 2266 149 2262 128 228 10 224 1882 2246 1968 21 284 140 2 119 2 1698 26 18 26 196 2 106 2 1684 19 1862 1 191 1 106 1014 114 114 1261 1261 140 140 164 164 164 164 1 118 10 11 121 140 1400 189 189 164 164 1698 1698 19 206 109 202 129 2048 141 2040 192 2044 11 2048 1861 21 28 129 29 141 2 19 21 1 26 1860 2 14 1410 141 190 1 16 129 18 1 118 109 1201 1201 1266 1266 141 141 16 16 1641 1641 1 161 109 162 121 1621 1448 1620 1620 1649 1649 160 160 19 2108 108 2104 126 2100 1444 2092 1618 2090 194 2084 1880 21 2614 124 2606 142 2092 1618 29 18 29 18 2 16 141 1 19 14 14 141 1862 1 98 94 1064 1064 1188 1188 144 144 1498 1498 1 1 1 141 984 1412 1161 141 14 142 142 14 14 186 186 19 1912 98 1908 1166 1906 14 1900 120 1898 1696 1902 18 21 2428 1161 2424 141 2420 118 2412 169 2411 181 2 298 129 294 108 296 168 296 1 1 62 62 91 91 108 108 124 124 140 140 148 148 1 1069 812 112 1014 121 121 10 10 141 141 1488 1488 19 164 8 164 10 168 121 164 19 1692 18 114 1682 21 220 10 2199 121 219 1408 2191 184 2191 162 2 269 1229 26 1408 2 18 2 16 1 862 862 96 96 1109 1109 1261 1261 1411 1411 148 148 1 1268 910 1262 108 12 1266 114 114 141 141 1488 1488 19 148 90 144 1086 140 126 14 14 10 1612 1 101 21 222 10 2246 124 2242 141 228 1608 224 169 2 296 124 290 1421 284 19 281 168 1 09 09 86 86 102 102 1186 1186 141 141 141 141 1 996 8 109 90 1110 1110 120 120 144 144 1420 1420 19 121 800 118 98 11 11 124 1 1 119 1 1 21 2044 980 2040 11 20 1 20 109 201 19 2 298 111 29 129 28 104 28 19 1 6 6 9 9 91 91 1086 1086 1249 1249 128 128 1 64 99 800 800 944 944 1088 1088 121 121 10 10 19 119 6 116 81 121 1010 1284 1211 168 168 141 141 21 1 89 11 10 11 1212 1 190 18 1482 2 261 104 2 1222 2 198 249 148 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 2 / FCLI4 Qv [m /h] k (Pc) k (Ps) Speed V 600 1 1 Speed V2 410 0. 0.82 Speed V1 00 0.61 0.6 IFCLITY1106-010_01 1

COOLING CAPACITY - FCLI 2 / FCLI4 Tw 11 1 1 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 640 640 99 99 94 94 110 110 126 126 10 10 1 8 19 90 90 9 9 110 110 128 128 1 1 19 18 26 1 902 12 10 1 12 182 182 198 198 21 1866 899 1862 106 188 121 184 1426 18 112 2 2411 1068 240 1244 2401 1420 29 106 1 22 22 00 00 866 866 102 102 118 118 1261 1261 1 601 80 29 29 868 868 1028 1028 1186 1186 1264 1264 19 102 99 10 6 110 96 1168 118 1249 1249 1294 1294 21 162 94 1624 90 1624 1146 1624 122 162 141 2 218 90 218 1148 219 122 219 1410 1 06 06 0 0 4 4 921 921 1088 1088 110 110 1 06 06 2 2 4 4 924 924 1091 1091 111 111 19 06 699 60 84 82 99 99 1111 1111 119 119 21 126 642 1268 819 106 100 166 120 1401 101 2 1910 84 1908 100 1906 120 1902 1291 1 46 46 69 69 96 96 949 949 1100 1100 11 11 1 14 14 641 641 98 98 91 91 110 110 118 118 19 96 40 9 14 96 896 1012 1012 1106 1106 1181 1181 21 14 20 140 896 144 1069 144 1242 141 12 2 199 891 199 106 1989 1240 198 12 1 24 24 28 28 02 02 866 866 1026 1026 110 110 1 2 2 28 28 0 0 868 868 1028 1028 110 110 19 09 9 68 62 62 886 886 100 100 1109 1109 21 119 99 119 4 118 96 12 114 126 1242 2 144 8 140 961 16 114 16 1222 1 14 14 08 08 62 62 1 1 92 92 1008 1008 1 14 14 08 08 62 62 4 4 926 926 1009 1009 19 19 19 10 10 69 69 928 928 1012 1012 21 88 4 4 60 892 821 1020 1020 1080 1080 2 1 644 1 818 1404 1002 1426 1096 1 04 04 4 4 68 68 94 94 94 94 1022 1022 1 0 0 4 4 69 69 96 96 948 948 102 102 19 44 4 8 60 60 9 9 949 949 1026 1026 21 1001 6 998 08 101 88 1060 1060 1091 1091 2 1 1 1 88 148 108 14 1144 1 124 124 1 1 0 0 866 866 94 94 1 124 124 2 2 0 0 868 868 948 948 19 12 12 06 06 81 81 949 949 21 8 6 6 4 94 81 911 911 91 91 2 1246 9 1246 68 1261 946 1280 109 1 2 2 14 14 21 21 0 0 6 6 84 84 1 2 2 14 14 21 21 1 1 8 8 84 84 19 2 2 14 14 22 22 9 9 846 846 21 160 160 2 2 89 89 66 66 849 849 2 661 8 81 60 944 81 100 920 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 2 / FCLI4 Qv [m /h] k (Pc) k (Ps) Speed V 600 1 1 Speed V2 410 0. 0.82 Speed V1 00 0.61 0.6 14 IFCLITY1106-010_01

COOLING CAPACITY - FCLI 42 Tw 9 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 1 2662 19 029 1 1 22 22 80 80 6 6 1 4094 2648 4086 022 408 91 4069 8 40 40 4061 4061 19 089 262 0 002 06 02 42 040 410 02 428 21 614 29 6126 46 6110 14 609 4082 6089 426 2 20 08 262 68 2 401 229 42 1 2 2420 2800 2800 2918 2918 122 122 46 46 92 92 1 11 2441 0 281 691 180 0 6 48 48 90 90 19 419 240 411 280 40 1 469 48 4686 91 460 4091 21 89 286 2 18 64 0 2 898 48 4082 2 692 11 6916 02 6900 81 6891 40 1 2194 2108 298 298 2622 2622 2924 2924 22 22 416 416 1 16 212 10 22 201 2911 0 0 49 49 29 29 19 42 2201 426 2 429 2946 4242 10 420 681 429 80 21 26 61 2946 16 4 686 6 866 2 68 291 629 0 61 64 60 8 1 246 22 249 249 26 26 294 294 28 28 411 411 1 91 22 82 264 1 010 68 68 428 428 4 4 19 482 226 44 261 46 002 449 6 44 1 4 908 21 4 260 419 29 449 6 94 12 90 89 2 662 2946 64 20 68 688 629 81 1 20 202 2211 2211 2469 2469 294 294 114 114 269 269 1 294 2046 29 241 29 29 060 060 190 190 29 29 19 9 202 966 242 962 296 90 160 946 26 94 14 21 048 2414 040 28 02 16 01 20 011 02 2 6192 26 6184 1 616 0 619 68 1 184 184 1906 1906 221 221 29 29 2924 2924 088 088 1 222 1689 2 2109 22 22 218 218 294 294 094 094 19 416 182 416 21 40 221 49 290 18 299 6 49 21 49 2189 41 260 46 292 4 29 4 4 2 6 26 48 292 1 292 1 48 1 19 19 1988 1988 206 206 2622 2622 29 29 088 088 1 266 1891 2624 226 260 261 22 22 2941 2941 094 094 19 6 1886 62 228 61 262 606 2988 9 1 60 21 4682 229 460 2608 4662 29 46 42 464 20 2 81 28 801 294 89 21 81 0 1 14 14 199 199 21 21 2466 2466 288 288 294 294 1 200 161 2161 2016 208 208 208 208 294 294 292 292 19 162 1664 16 20 10 2401 16 2 20 19 2 2 21 420 20 4242 2406 424 22 4226 1 4222 1 2 402 294 94 26 12 1 1 1114 1114 16 16 1906 1906 22 22 296 296 260 260 1 140 1244 166 166 196 196 2262 2262 2602 2602 266 266 19 2409 12 2426 1699 22 2101 260 219 284 284 2941 2941 21 691 18 68 212 68 219 691 2889 16 082 2 4908 21 4900 241 4892 290 4884 08 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 42 Qv [m /h] k (Pc) k (Ps) Speed V4 00 1 1 Speed V 0 0.82 0. Speed V2 60 0.64 0.8 Speed V1 260 0.0 0.44 IFCLITY1106-010_01 1

COOLING CAPACITY - FCLI 42 Tw 11 1 1 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 10 10 1661 1661 1982 1982 2296 2296 2610 2610 266 266 1 181 149 1881 1881 2022 2022 202 202 2616 2616 21 21 19 2822 108 281 186 2811 2240 2814 2608 28 28 290 290 21 880 180 82 22 864 2601 8 2964 81 14 2 011 2219 4999 28 4991 292 498 12 1 1086 1086 14 14 1801 1801 21 21 2460 2460 2622 2622 1 120 120 116 116 1804 1804 218 218 2466 2466 262 262 19 2228 124 224 1614 202 2002 2429 240 296 296 2689 2689 21 82 161 201 28 248 94 29 2 446 201 446 28 40 24 40 291 1 66 66 1142 1142 10 10 191 191 2262 2262 242 242 1 6 6 1148 1148 12 12 1920 1920 2268 2268 24 24 19 102 4 144 12 16 120 206 206 210 210 242 242 21 260 1 266 10 21 2094 289 201 291 204 2 91 16 966 2142 962 206 94 2684 1 990 990 129 129 166 166 194 194 2288 2288 244 244 1 1069 1069 12 12 1660 1660 19 19 229 229 2449 2449 19 1946 112 1940 148 1988 1864 2104 2104 2299 2299 24 24 21 020 149 01 1862 009 2222 00 282 01 268 2 412 182 414 2218 41 28 411 28 1 6 6 109 109 149 149 1801 1801 212 212 2296 2296 1 66 66 1099 1099 1462 1462 1804 1804 218 218 202 202 19 108 4 126 1200 184 184 1841 1841 2141 2141 20 20 21 2409 124 2409 1610 2460 198 268 284 260 282 2 62 16 61 1999 609 28 609 240 1 21 21 641 641 1168 1168 161 161 192 192 2096 2096 1 21 21 641 641 1168 1168 16 16 1926 1926 2098 2098 19 1 1 644 644 1182 1182 169 169 1929 1929 2104 2104 21 1222 16 124 18 108 2121 2121 224 224 2 2862 19 2862 101 2918 208 2964 229 1 6 6 991 991 126 126 160 160 196 196 2124 2124 1 64 64 99 99 129 129 164 164 191 191 212 212 19 92 69 1118 1109 12 12 16 16 194 194 212 212 21 2081 1114 206 141 2110 1844 220 220 2268 2268 2 22 1482 20 1844 218 2200 21 29 1 2 2 69 69 1104 1104 1462 1462 1801 1801 1968 1968 1 28 28 69 69 1106 1106 146 146 1804 1804 191 191 19 29 29 01 01 1108 1108 1468 1468 1810 1810 194 194 21 119 4 1408 119 161 1624 189 189 2019 2019 2 290 12 290 196 2622 196 2661 2160 1 1 1 21 21 66 66 118 118 12 12 1 1 1 1 1 21 21 66 66 1188 1188 1 1 16 16 19 1 1 21 21 60 60 1190 1190 18 18 19 19 21 690 690 1224 1224 192 192 16 16 2 14 9 1691 12 196 169 209 1912 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 42 Qv [m /h] k (Pc) k (Ps) Speed V4 00 1 1 Speed V 0 0.82 0. Speed V2 60 0.64 0.8 Speed V1 260 0.0 0.44 16 IFCLITY1106-010_01

COOLING CAPACITY - FCLI 44 Tw 9 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 292 2460 2919 299 292 292 024 024 08 08 42 42 1 8 244 29 68 1 60 4 49 49 19 40 242 4692 24 4680 11 4669 48 46 9 460 962 21 66 248 661 092 646 42 60 2 62 942 2 618 0 610 40 668 4 6680 91 1 20 226 28 28 269 269 288 288 1 1 19 19 1 40 226 422 2600 411 299 426 286 464 464 02 02 19 461 224 4 292 446 296 48 28 40 61 41 80 21 49 2 4 2918 26 261 1 602 11 2 2 6406 2894 691 26 6 668 4 1 2028 1948 2216 2216 2422 2422 202 202 00 00 1 1 1 2916 1989 2911 21 298 2690 02 02 18 18 261 261 19 90 204 94 280 9 222 920 09 92 402 9 6 21 4969 281 494 222 4946 064 499 406 491 2 6041 209 60 04 6018 9 6011 64 1 226 2101 20 20 24 24 22 22 010 010 12 12 1 1 2100 12 244 11 281 112 112 16 16 209 209 19 4049 208 4042 241 404 24 4019 109 401 44 4004 612 21 022 2409 00 21 4019 109 4984 40 4980 99 2 6064 22 606 068 6041 408 60 1 189 182 204 204 2281 2281 282 282 28 28 021 021 1 22 1891 21 220 249 28 2828 2828 2948 2948 04 04 19 6 1896 66 2240 661 28 60 2920 646 28 64 42 21 466 221 46 26 460 291 46 22 461 421 2 22 2 14 289 699 2 691 40 1 146 146 161 161 2080 2080 296 296 202 202 284 284 1 204 161 214 1949 21 21 211 211 22 22 289 289 19 1 164 1 199 146 20 18 2684 21 049 29 22 21 422 202 4224 266 4216 20 4209 04 4209 21 2 19 262 11 204 296 042 296 214 1 16 16 18 18 211 211 2422 2422 210 210 284 284 1 246 14 242 208 2449 241 224 224 218 218 289 289 19 14 0 2086 42 242 2 261 24 09 29 268 21 42 2069 41 2410 408 249 400 088 4292 2 2 2 288 61 229 49 069 42 2 1 161 161 1662 1662 19 19 229 229 2 2 22 22 1 191 1494 1996 186 212 212 218 218 282 282 228 228 19 2922 18 2916 189 2911 2218 292 264 2984 2919 026 026 21 92 1882 920 2224 912 261 90 2898 901 06 2 4992 2212 4984 2 4969 2890 4969 061 1 100 100 1419 1419 161 161 208 208 299 299 20 20 1 129 110 1 1 1814 1814 2091 2091 2404 2404 26 26 19 2226 1224 2242 10 21 1941 246 22 2629 2629 218 218 21 411 160 40 1988 40 228 411 260 4 2848 2 46 2008 428 248 420 2686 41 282 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 44 Qv [m /h] k (Pc) k (Ps) Speed V4 00 1 1 Speed V 0 0.82 0. Speed V2 60 0.64 0.8 Speed V1 260 0.0 0.4 IFCLITY1106-010_01 1

COOLING CAPACITY - FCLI 44 Tw 11 1 1 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 1229 1229 1 1 182 182 2122 2122 2412 2412 26 26 1 16 182 18 18 1868 1868 212 212 241 241 261 261 19 2608 194 260 14 298 200 2600 2410 26 26 2686 2686 21 8 128 8 206 0 240 6 28 9 2904 2 461 201 4619 289 4612 228 4604 2894 1 100 100 144 144 166 166 19 19 22 22 2422 2422 1 11 111 1401 1401 166 166 196 196 229 229 2428 2428 19 209 111 2064 1492 212 180 224 2224 299 299 248 248 21 12 12 120 1864 120 2202 120 29 16 214 2 4201 1864 4201 2206 4186 29 4186 208 1 8 8 106 106 142 142 169 169 2091 2091 224 224 1 89 89 1061 1061 14 14 14 14 2096 2096 220 220 19 92 68 14 118 162 189 1881 1881 21 21 2266 2266 21 240 12 246 1 209 19 2624 211 2692 2499 2 669 1641 66 199 661 216 64 2480 1 91 91 1228 1228 10 10 1824 1824 2114 2114 228 228 1 988 988 121 121 14 14 182 182 2119 2119 226 226 19 198 108 19 12 18 122 1944 1944 212 212 2268 2268 21 291 18 286 120 280 20 2 286 288 28 2 86 111 82 2049 821 282 81 249 1 622 622 1014 1014 148 148 166 166 190 190 2122 2122 1 624 624 101 101 11 11 166 166 196 196 212 212 19 9 691 1226 1109 146 146 101 101 198 198 210 210 21 2226 111 2226 148 22 186 2 220 240 286 2 0 11 42 184 4 219 4 24 1 29 29 9 9 109 109 1442 1442 1 1 196 196 1 29 29 9 9 109 109 1448 1448 180 180 199 199 19 06 06 9 9 1092 1092 140 140 182 182 1944 1944 21 1129 18 1448 119 114 18 1960 1960 20 20 2 264 128 264 12 269 192 29 2106 1 8 8 916 916 1226 1226 12 12 1816 1816 1962 1962 1 86 86 91 91 1228 1228 129 129 1821 1821 196 196 19 84 641 10 102 1249 1249 11 11 1824 1824 190 190 21 192 1029 1918 160 1949 104 206 206 2096 2096 2 298 10 2984 104 294 20 291 2198 1 2 2 64 64 1020 1020 11 11 166 166 1819 1819 1 28 28 64 64 1022 1022 14 14 166 166 1821 1821 19 29 29 648 648 1024 1024 16 16 162 162 1824 1824 21 101 69 101 1102 126 101 11 11 1866 1866 2 294 114 294 14 2422 181 249 1996 1 4 4 29 29 616 616 109 109 14 14 1620 1620 1 4 4 29 29 616 616 109 109 14 14 162 162 19 4 4 29 29 619 619 1100 1100 148 148 162 162 21 08 08 6 6 111 111 141 141 161 161 2 120 16 118 1814 166 194 16 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 44 Qv [m /h] k (Pc) k (Ps) Speed V4 00 1 1 Speed V 0 0.82 0. Speed V2 60 0.64 0.8 Speed V1 260 0.0 0.4 18 IFCLITY1106-010_01

COOLING CAPACITY - FCLI 62 Tw 9 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 4000 210 98 62 4000 4000 412 412 414 414 410 410 1 162 19 11 644 141 4089 10 41 11 490 120 120 19 641 16 6401 619 686 406 60 412 64 490 644 169 21 44 8 24 404 0 448 682 4921 6 14 2 916 989 91 444 9124 4884 9114 106 1 41 291 0 92 680 680 96 96 42 42 428 428 1 469 294 4669 92 46 84 464 4288 426 426 48 48 19 90 2929 99 82 929 81 919 428 908 41 888 492 21 298 9 28 80 26 426 22 400 246 4921 2 840 819 4222 8699 4668 8688 4889 1 26 241 02 02 0 0 68 68 4100 4100 40 40 1 99 29 92 042 406 10 4164 998 46 46 440 440 19 90 264 9 10 69 2 48 991 9 449 69 466 21 680 106 69 2 649 998 68 4444 628 4661 2 8242 4 822 98 8211 4429 8201 460 1 10 241 148 148 19 19 1 1 410 410 400 400 1 42 240 4264 18 420 629 4246 400 421 421 48 48 19 2 221 14 12 04 619 48 40 48 4498 462 412 21 682 14 682 89 48 40 6800 44 69 4696 2 82 2 826 400 8242 444 822 466 1 26 2442 288 288 11 11 2 2 926 926 4122 4122 1 1 246 01 2909 1 0 88 84 4022 4022 41 41 19 011 244 001 292 4996 1 4980 810 49 421 498 448 21 66 2911 64 61 644 806 62 4244 618 4464 2 80 2 96 80 422 6 444 1 199 199 240 240 288 288 269 269 68 68 89 89 1 2802 206 2966 24 180 0 426 426 1 1 901 901 19 40 2149 40 2601 429 040 46 02 44 98 4492 421 21 4 269 6 08 29 42 90 42 4192 2 2 081 246 29 226 969 226 419 1 2260 2260 206 206 2908 2908 0 0 69 69 89 89 1 2 2280 09 220 41 1 444 444 08 08 901 901 19 481 22 40 222 460 16 446 602 4 4040 442 4264 21 90 2699 888 144 8 8 86 400 86 4244 2 29 116 14 61 298 4004 288 422 1 18 18 2268 2268 2692 2692 109 109 16 16 1 1 1 2610 1949 224 240 2909 2909 16 16 2 2 22 22 19 986 2006 99 242 92 2894 99 4 402 808 4129 4044 21 9 246 48 2901 8 42 2 82 22 999 2 6811 2886 6800 1 680 0 680 994 1 140 140 196 196 240 240 284 284 2 2 480 480 1 1690 100 2096 2080 244 244 282 282 280 280 48 48 19 08 19 09 2049 180 2 66 0 8 40 08 08 21 46 212 464 294 464 0 46 484 4684 16 2 6188 2620 618 06 6168 0 61 22 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 62 Qv [m /h] k (Pc) k (Ps) Speed V4 880 1 1 Speed V 660 0.9 0.4 Speed V2 00 0.64 0.60 Speed V1 80 0. 0.49 IFCLITY1106-010_01 19

COOLING CAPACITY - FCLI 62 Tw 11 1 1 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 16 16 209 209 2499 2499 289 289 291 291 48 48 1 2288 180 21 220 249 249 2902 2902 298 298 494 494 19 8 1819 1 2262 44 200 48 14 622 601 66 66 21 4892 224 4881 269 481 16 4861 486 89 2 618 266 60 11 6292 9 6282 6 1 169 169 184 184 221 221 2692 2692 102 102 0 0 1 16 14 1911 1911 22 22 269 269 109 109 12 12 19 2810 102 281 1946 2902 2414 06 2902 2 2 91 91 21 4264 1990 42 242 42 28 42 1 429 41 2 2 242 2 288 11 1 11 4 1 801 801 1440 1440 194 194 2414 2414 282 282 066 066 1 80 80 144 144 19 19 2421 2421 289 289 00 00 19 126 896 18 111 2214 20 26 26 291 291 091 091 21 16 1609 2 20 42 22 80 016 62 261 2 006 2142 001 282 4996 021 498 26 1 1248 1248 166 166 208 208 2489 2489 2884 2884 080 080 1 148 148 169 169 209 209 2492 2492 2892 2892 088 088 19 24 1 2446 190 206 224 26 26 2899 2899 09 09 21 808 180 801 224 94 269 86 11 804 8 2 24 222 229 264 21 109 208 2 1 848 848 18 18 1840 1840 221 221 2688 2688 289 289 1 82 82 18 18 184 184 22 22 269 269 2902 2902 19 1 901 162 144 199 199 221 221 2699 2699 2906 2906 21 08 101 08 1941 102 296 2 28 16 11 2 40 194 460 2410 40 2844 40 062 1 40 40 809 809 142 142 1968 1968 2424 2424 2642 2642 1 40 40 809 809 142 142 19 19 2428 2428 264 264 19 41 41 812 812 1490 1490 199 199 242 242 26 26 21 140 9 19 112 29 209 264 29 281 281 2 608 161 608 201 680 212 248 1 98 98 120 120 162 162 2080 2080 248 248 268 268 1 800 800 121 121 166 166 2086 2086 248 248 2681 2681 19 1166 86 1410 1 104 104 2089 2089 2489 2489 2688 2688 21 2624 14 261 14 2660 222 2 2688 289 289 2 40 18 402 222 40 26 404 2869 1 24 24 8 8 192 192 184 184 221 221 2481 2481 1 2 2 8 8 194 194 184 184 22 22 248 248 19 26 26 884 884 198 198 180 180 2282 2282 2489 2489 21 1462 910 1 148 2082 199 289 289 246 246 2 266 1492 266 1924 0 21 2604 1 64 64 40 40 841 841 1494 1494 1982 1982 2210 2210 1 64 64 40 40 841 841 149 149 1986 1986 2214 2214 19 64 64 40 40 844 844 101 101 1989 1989 2218 2218 21 420 414 80 80 144 144 200 200 222 222 2 1 99 212 111 244 204 268 20 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 62 Qv [m /h] k (Pc) k (Ps) Speed V4 880 1 1 Speed V 660 0.9 0.4 Speed V2 00 0.64 0.60 Speed V1 80 0. 0.49 20 IFCLITY1106-010_01

COOLING CAPACITY - FCLI 64 Tw 9 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 0 294 68 8 0 0 819 819 419 419 460 460 1 48 298 468 6 49 88 449 4198 4 460 440 440 19 940 29 92 911 68 89 4180 882 486 8 489 21 169 22 10 8 11 4149 111 49 10 46 2 8484 696 84 4116 8446 42 846 41 1 19 20 268 142 406 406 644 644 4010 4010 4192 4192 1 42 22 422 14 408 42 9 4 4 442 442 19 08 214 498 14 489 49 49 96 469 41 40 40 21 66 112 6 2 62 94 61 4 608 460 2 8091 498 802 912 802 42 804 40 1 261 24 299 299 060 060 41 41 96 96 98 98 1 68 2404 6 2818 6 22 8 04 401 401 4119 4119 19 4989 249 4980 28 490 291 491 698 4960 411 490 42 21 626 288 62 291 624 0 628 4118 6228 419 2 60 24 620 692 601 4104 91 408 1 28 29 2914 2914 0 0 49 49 802 802 980 980 1 9 29 94 29 94 62 91 1 4000 4000 40 40 19 114 221 10 299 09 06 8 01 416 06 466 21 64 2912 624 2 06 8 629 4146 6290 41 2 69 291 649 09 60 4120 620 424 1 2 2262 281 281 2881 2881 261 261 64 64 81 81 1 49 228 426 269 42 12 1 62 2 2 848 848 19 469 2292 4629 209 4624 12 4610 0 460 98 461 4149 21 892 269 882 114 8 26 8 92 849 41 2 22 08 21 0 198 91 188 411 1 1848 1848 2224 2224 262 262 02 02 41 41 604 604 1 294 188 246 26 2944 282 12 12 49 49 611 611 19 98 1991 98 2409 94 281 401 24 4106 686 419 90 21 4 244 2860 2 20 16 69 16 884 2 618 28 608 269 6689 6 6689 88 1 2092 2092 220 220 2692 2692 060 060 42 42 604 604 1 06 2112 06 220 09 299 188 188 4 4 611 611 19 4240 210 421 222 4221 292 4208 8 4198 4 420 91 21 46 201 40 291 441 24 41 4 421 92 2 68 288 60 299 66 10 646 91 1 119 119 2099 2099 2492 2492 288 288 24 24 49 49 1 2416 1806 222 222 269 269 2928 2928 261 261 446 446 19 690 189 68 222 6 2682 69 100 69 28 822 4 21 4960 22 491 2688 4941 096 492 04 492 0 2 60 264 629 086 626 49 626 01 1 100 100 192 192 2224 2224 264 264 00 00 221 221 1 164 190 1941 192 2291 2291 2640 2640 06 06 228 228 19 2812 1480 282 1898 2944 24 116 2814 20 280 4 4 21 408 1994 4298 2404 4298 2814 408 228 46 44 2 29 2428 19 288 09 248 00 448 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 64 Qv [m /h] k (Pc) k (Ps) Speed V4 880 1 1 Speed V 660 0.9 0.4 Speed V2 00 0.64 0.9 Speed V1 80 0. 0.49 IFCLITY1106-010_01 21

COOLING CAPACITY - FCLI 64 Tw 11 1 1 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 1 1 199 199 214 214 2680 2680 046 046 228 228 1 2118 161 219 210 260 260 268 268 0 0 2 2 19 294 168 28 2096 281 202 284 2914 6 9 9 21 428 2088 419 2499 409 290 400 11 449 11 2 849 249 84 2888 82 29 81 499 1 126 126 1698 1698 2102 2102 2492 2492 281 281 060 060 1 149 146 169 169 2106 2106 249 249 288 288 066 066 19 2601 191 260 180 268 22 28 2689 00 00 19 19 21 94 1844 941 224 941 2662 941 00 961 281 2 06 22 06 2666 28 069 28 24 1 42 42 1 1 1809 1809 224 224 2640 2640 288 288 1 44 44 140 140 1812 1812 2241 2241 264 264 2842 2842 19 1228 80 1696 1400 200 1921 26 26 2696 2696 2862 2862 21 069 1491 06 1902 168 240 14 294 400 021 2 464 1984 4629 292 4624 299 461 2998 1 11 11 11 11 192 192 204 204 260 260 282 282 1 124 124 14 14 19 19 20 20 26 26 288 288 19 221 12 2264 169 220 2082 246 246 268 268 286 286 21 2 162 18 2080 12 2482 0 2884 22 09 2 484 2068 4840 248 4826 2880 4821 081 1 8 8 1280 1280 10 10 2102 2102 2489 2489 2680 2680 1 88 88 1282 1282 106 106 2106 2106 249 249 268 268 19 124 8 148 141 1848 18 2149 2149 2498 2498 2690 2690 21 2812 191 2812 198 281 2220 299 266 069 2884 2 421 1829 4221 22 4212 26 4212 28 1 49 49 16 16 1822 1822 2244 2244 2446 2446 1 49 49 16 16 1828 1828 2248 2248 2449 2449 19 86 86 2 2 180 180 182 182 221 221 246 246 21 1426 868 1828 1401 216 190 24 2402 2621 2621 2 40 1496 40 1900 406 22 49 246 1 9 9 11 11 148 148 1926 1926 2294 2294 249 249 1 40 40 118 118 11 11 191 191 200 200 2482 2482 19 109 10 129 18 18 194 194 204 204 2489 2489 21 2429 1244 242 1644 2462 2060 21 2490 264 264 2 166 69 2060 6 248 268 1 00 00 812 812 1289 1289 106 106 2102 2102 229 229 1 01 01 812 812 1290 1290 110 110 2106 2106 200 200 19 02 02 818 818 1294 1294 11 11 2112 2112 204 204 21 1 84 1644 12 192 181 2211 2211 2 2 2 02 182 02 18 060 219 106 241 1 9 9 8 8 18 18 18 18 2046 2046 1 9 9 8 8 186 186 188 188 200 200 19 9 9 82 82 189 189 1842 1842 20 20 21 88 8 80 80 1429 1429 188 188 209 209 2 1604 888 194 1400 2291 189 2442 216 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 64 Qv [m /h] k (Pc) k (Ps) Speed V4 880 1 1 Speed V 660 0.9 0.4 Speed V2 00 0.64 0.9 Speed V1 80 0. 0.49 22 IFCLITY1106-010_01

COOLING CAPACITY - FCLI 82 Tw 9 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 4820 8 498 4026 4820 416 490 490 48 48 6 6 1 6219 20 6206 401 6194 40 6181 499 6162 49 6169 22 19 1 492 12 990 69 448 6 494 66 46 64 699 21 91 92 906 444 9281 496 926 42 9249 669 2 1104 49 1100 4898 1099 84 10980 629 1 418 216 42 9 44 426 442 442 219 219 46 46 1 68 24 62 9 606 422 61 42 694 22 6 49 19 168 229 16 29 14 422 11 416 119 200 094 4 21 89 0 868 419 86 4691 8 181 81 42 2 100 4162 100 46 10480 146 10468 90 1 2801 64 89 982 946 4442 4442 4940 4940 189 189 1 494 2860 48 486 869 01 440 224 494 61 21 19 6494 2926 6481 42 6469 91 6444 4400 646 489 6469 14 21 8168 424 814 916 811 4408 8118 4899 8106 19 2 990 896 9918 49 989 488 9880 126 1 42 021 9 20 999 999 446 446 4949 4949 181 181 1 11 021 18 1 121 4000 116 448 206 4991 2 229 19 666 2999 6644 496 661 990 6606 442 6600 498 681 19 21 826 46 821 96 6606 442 819 49 818 1 2 9968 916 99 441 990 4902 9918 14 1 089 2692 9 248 0 0 4244 4244 40 40 4966 4966 1 446 219 449 20 419 1 4648 428 4846 46 009 009 19 60 22 602 22 6019 16 6000 4200 994 4686 6006 496 21 668 209 66 0 64 419 618 468 612 4920 2 940 6 99 416 968 46 96 4898 1 240 2291 289 289 419 419 99 99 4442 4442 4691 4691 1 6 224 4 280 82 0 4128 92 446 442 400 400 19 189 269 189 286 12 1 224 861 44 48 41 4648 21 696 2910 6944 402 691 890 6919 4 6919 4621 2 84 9 81 890 806 4 806 462 1 22 22 020 020 0 0 982 982 44 44 4691 4691 1 4004 21 986 2999 402 49 410 400 4468 4468 400 400 19 19 20 06 001 494 489 4 91 464 444 4 401 21 112 296 094 466 081 9 069 4442 06 469 2 881 4 8812 926 89 4414 881 46 1 228 2206 22 22 24 24 46 46 426 426 446 446 1 144 2149 282 269 0 22 810 6 4244 4244 448 448 19 480 2211 494 20 48 191 4811 688 4906 4198 494 448 21 646 20 6444 198 641 684 6419 4169 6412 4408 2 8206 181 819 62 8168 416 8168 440 1 1692 1692 22 22 289 289 428 428 94 94 419 419 1 206 164 226 2292 2981 2896 4 4 92 92 4201 4201 19 660 161 686 228 82 292 40 48 421 902 4468 418 21 606 2 94 2860 94 48 606 840 644 4096 2 46 2889 44 41 864 418 410 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 82 Qv [m /h] k (Pc) k (Ps) Speed V4 1100 1 1 Speed V 80 0.80 0.9 Speed V2 680 0.68 0.66 Speed V1 460 0.4 0.4 IFCLITY1106-010_01 2

COOLING CAPACITY - FCLI 82 Tw 11 1 1 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 2021 2021 224 224 011 011 488 488 96 96 4201 4201 1 2 1988 28 202 01 02 49 49 9 9 4210 4210 19 428 200 429 2494 420 29 424 46 464 969 4416 4219 21 894 248 881 29 869 4 86 99 80 41 2 612 290 9 46 81 92 68 416 1 1649 1649 2210 2210 26 26 24 24 982 982 1 1899 1601 202 2194 241 241 24 24 46 46 991 991 19 8 16 94 214 49 2661 690 199 94 40 408 400 21 18 2194 129 2681 129 16 129 62 1 90 2 6906 2681 6906 12 6881 62 6881 89 1 966 966 1 1 24 24 2908 2908 4 4 694 694 1 968 968 144 144 28 28 291 291 44 44 699 699 19 198 988 2208 166 2668 2286 09 288 10 42 24 24 21 99 14 4004 226 4124 284 41 24 442 94 2 601 261 602 2846 6019 1 6006 6 1 10 10 2019 2019 21 21 2998 2998 4 4 11 11 1 1624 148 202 202 221 221 00 00 484 484 20 20 19 29 149 294 19 020 24 196 299 492 492 29 29 21 488 1990 49 244 41 29 462 42 484 680 2 606 2461 600 2948 6281 42 62 666 1 1022 1022 166 166 2216 2216 26 26 29 29 488 488 1 1026 1026 1669 1669 2221 2221 241 241 24 24 49 49 19 1606 99 201 19 240 2181 296 24 22 22 01 01 21 660 16 660 219 2641 900 169 99 42 2 06 216 494 26 481 1 481 6 1 488 488 94 94 14 14 21 21 2921 2921 18 18 1 488 488 94 94 14 14 280 280 292 292 18 18 19 0 464 99 99 19 182 284 284 290 290 196 196 21 186 10 280 166 2818 220 222 288 411 14 2 44 180 44 2261 44 269 402 029 1 961 961 10 10 201 201 206 206 298 298 226 226 1 96 96 108 108 2019 2019 21 21 2994 2994 20 20 19 140 922 1699 144 20 202 21 21 2998 2998 29 29 21 162 1481 1 19 20 241 46 296 44 219 2 4910 190 4906 241 4889 292 4884 162 1 90 90 106 106 16 16 2221 2221 26 26 2990 2990 1 91 91 106 106 169 169 222 222 241 241 2994 2994 19 9 91 106 106 1684 1684 2229 2229 249 249 2998 2998 21 161 100 219 18 209 219 288 221 06 299 2 9 1644 9 2121 982 2614 4042 281 1 488 488 101 101 1800 1800 288 288 266 266 1 488 488 101 101 1804 1804 29 29 2668 2668 19 488 488 101 101 1808 1808 29 29 262 262 21 0 46 1048 1029 1860 194 2418 240 2680 2680 2 2088 10 269 1666 2981 22 19 241 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): FCLI 82 Qv [m /h] k (Pc) k (Ps) Speed V4 1100 1 1 Speed V 80 0.80 0.9 Speed V2 680 0.68 0.66 Speed V1 460 0.4 0.4 24 IFCLITY1106-010_01

COOLING CAPACITY - FCLI 122 Tw 9 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 886 1 89 8118 886 886 9112 9112 990 990 10404 10404 1 11401 099 118 8101 11 9089 112 100 11298 11049 1109 1109 19 141 041 1419 8046 1410 9041 1400 1000 1406 11004 1401 11492 21 1106 90 1060 8968 1014 99 16968 10940 169 114 2 2024 886 20222 98 201 108 2010 111 1 62 648 9 40 812 812 869 869 969 969 10002 10002 1 106 64 101 41 1028 824 1024 92 1049 1049 10 10 19 1142 612 1119 19 1096 816 10 910 101 1048 100 1096 21 16121 468 160 8464 1602 9460 16018 10449 16006 10941 2 190 89 19260 98 19214 10 19191 10869 1 6111 649 668 668 00 00 814 814 90 90 914 914 1 889 68 8 662 891 802 9199 8888 9 9 9829 9829 19 1190 901 11882 690 1189 89 1181 88 1186 9868 1189 102 21 149 690 14929 896 14906 8889 14884 9880 14861 106 2 18206 8 1818 889 181 984 18114 10 1 689 609 694 694 2 2 8206 8206 90 90 9498 9498 1 944 6092 9419 08 988 806 980 9049 94 94 961 961 19 1220 6048 12180 01 121 8046 12111 9018 12100 9999 1206 1046 21 116 698 1090 99 12111 9018 1021 9949 1010 10440 2 1824 89 1822 8899 18206 9886 1818 106 1 662 429 618 618 68 68 81 81 861 861 9104 9104 1 8206 484 81 646 828 492 821 821 8884 8884 918 918 19 11069 00 11046 6499 1104 49 11000 840 10989 940 11011 99 21 1409 641 1406 41 1401 8460 196 944 196 992 2 124 406 1221 8404 11 988 112 98 1 4410 4410 08 08 6269 6269 222 222 814 814 8600 8600 1 6190 42 62 6 02 696 68 68 8206 8206 8616 8616 19 914 4 914 81 9482 68 9 86 99 884 992 94 21 12 868 120 6862 120 84 12684 882 12684 920 2 16029 680 16006 84 1960 8824 1960 922 1 499 499 6 6 6422 6422 00 00 816 816 8600 8600 1 40 069 08 6048 9 0 608 608 8190 8190 8616 8616 19 10118 06 1009 601 1002 0 10041 8008 10018 8982 100 9480 21 109 6001 100 6990 12982 9 1299 898 1296 946 2 16189 6928 161 91 16121 8902 16098 988 1 410 410 009 009 946 946 686 686 6 6 8206 8206 1 6 4 601 40 6426 6426 698 698 81 81 8222 8222 19 880 4460 889 40 8 64 8821 4 8994 8466 9120 8990 21 1186 49 1181 640 1190 40 1168 840 116 8890 2 1044 6416 1021 40 149 882 149 889 1 10 10 426 426 08 08 628 628 20 20 686 686 1 6 461 462 46 46 600 600 24 24 02 02 19 610 0 6 44 02 60 44 61 92 869 8190 8190 21 1028 48 102 6 102 62 1028 4 104 8261 2 1669 82 1646 6810 162 92 1600 824 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. FCLI 122 Qv [m /h] k (Pc) k (Ps) Speed V4 10 1 1 Speed V 10 0.81 0.81 Speed V2 1100 0.68 0.68 Speed V1 0 0.49 0.48 IFCLITY1106-010_01 2

COOLING CAPACITY - FCLI 122 Tw 11 1 1 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 0 0 462 462 21 21 69 69 269 269 02 02 1 0 4008 2 04 61 61 6411 6411 28 28 18 18 19 860 404 844 029 828 600 86 6991 8001 8001 8096 8096 21 1080 011 1082 996 109 691 10 94 102 842 2 196 949 1921 690 1898 912 18 89 1 024 024 402 402 016 016 946 946 682 682 00 00 1 481 20 4221 4221 024 024 94 94 686 686 16 16 19 6206 8 6221 426 6411 6 66 642 20 20 490 490 21 9419 442 940 40 940 68 940 6 941 82 2 12661 406 12661 698 1261 64 1261 86 1 10 10 181 181 416 416 2 2 600 600 6 6 1 14 14 19 19 42 42 4 4 616 616 681 681 19 2929 1992 4048 9 4890 4609 60 60 644 644 6828 6828 21 24 8 40 464 60 614 90 604 8112 248 2 110 461 11046 40 1104 61 11011 19 1 26 26 01 01 4611 4611 49 49 61 61 6804 6804 1 29 29 09 09 462 462 0 0 68 68 6820 6820 19 418 011 402 980 6 499 89 89 640 640 686 686 21 8411 401 89 4990 89 9 864 6921 840 421 2 1161 496 110 94 1116 6911 1104 9 1 18 18 0 0 4064 4064 016 016 98 98 69 69 1 1881 1881 09 09 401 401 024 024 94 94 6411 6411 19 294 200 69 218 4410 498 12 12 962 962 6418 6418 21 610 610 414 682 26 11 690 24 6921 2 1009 488 1002 8 10049 621 10049 680 1 894 894 186 186 22 22 44 44 86 86 1 894 894 186 186 22 22 46 46 6 6 84 84 19 922 922 194 194 292 292 41 41 1 1 89 89 21 402 208 46 62 166 4 906 64 62 62 2 90 90 90 49 812 8 82 6108 1 162 162 260 260 69 69 49 49 4 4 914 914 1 166 166 264 264 01 01 460 460 489 489 922 922 19 2 188 114 29 64 64 461 461 49 49 98 98 21 96 2986 80 944 8 4942 61 9 616 616 2 9002 9 8994 4942 8962 898 894 6 1 16 16 19 19 0 0 401 401 016 016 481 481 1 1 1 19 19 09 09 409 409 024 024 489 489 19 21 21 19 19 08 08 408 408 040 040 49 49 21 229 2022 922 196 499 44 26 26 62 62 2 214 16 214 428 00 22 411 89 1 142 142 894 894 18 18 00 00 49 49 488 488 1 142 142 894 894 18 18 0 0 486 486 4890 4890 19 142 142 894 894 186 186 1 1 494 494 4898 4898 21 92 920 1921 1921 410 410 444 444 4914 4914 2 82 211 409 9 46 44 828 12 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. FCLI 122 Qv [m /h] k (Pc) k (Ps) Speed V4 10 1 1 Speed V 10 0.81 0.81 Speed V2 1100 0.68 0.68 Speed V1 0 0.49 0.48 26 IFCLITY1106-010_01

COOLING CAPACITY - FCLI 124 Tw 9 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 069 0 08 6489 069 069 290 290 96 96 82 82 1 9121 64 9102 64 9084 26 9066 801 908 881 904 904 19 119 628 1111 641 11284 22 1126 801 11229 89 11210 918 21 168 60 1648 168 1611 9 1 844 166 918 2 16196 088 1618 89 1612 868 16104 90 1 6099 184 62 602 602 602 696 696 6 6 8002 8002 1 8268 20 820 602 822 6814 829 619 81 81 844 844 19 1014 20 1049 6010 104 680 1049 601 10440 882 10404 864 21 1289 969 12860 66 12842 62 12814 81 1280 84 2 1444 609 1408 0 11 8294 1 868 1 4889 41 4 4 840 840 61 61 24 24 611 611 1 01 4610 019 40 12 626 9 104 661 661 86 86 19 924 416 906 1 948 611 941 092 9469 88 948 8290 21 11980 19 1194 611 1192 10 1190 89 11888 828 2 146 6280 1446 081 1410 80 14491 8262 1 488 480 6 6 866 866 66 66 28 28 98 98 1 4 4869 66 10 6448 04 2 66 66 19 962 484 944 66 926 641 9689 208 9680 992 962 8 21 12108 8 1202 6 9689 208 1201 92 12008 844 2 14620 612 14601 11 146 902 1446 8294 1 40 49 492 492 00 00 622 622 69 69 28 28 1 66 48 640 169 6628 989 681 681 10 10 46 46 19 88 496 88 19 882 989 8800 60 891 8809 9 21 1124 12 11229 92 11210 662 1114 41 11164 91 2 19 920 16 61 140 04 121 89 1 28 28 4246 4246 01 01 61 61 6880 6880 1 492 618 242 418 620 42 60 60 66 66 689 689 19 611 819 611 4621 86 402 661 622 88 068 99 49 21 10202 4690 10184 484 10166 621 1014 0 1014 449 2 1282 46 1280 620 1268 0 1268 41 1 994 994 4429 4429 18 18 840 840 6 6 6880 6880 1 82 401 84 484 90 6 6086 6086 62 62 689 689 19 8094 4042 806 48 808 62 80 6401 8014 19 802 8 21 1041 49 10404 8 108 6 106 160 1049 42 2 1292 12924 628 1289 11 1288 04 1 282 282 400 400 4 4 494 494 6212 6212 66 66 1 4612 46 481 419 141 141 88 88 622 622 68 68 19 044 6 01 46 019 14 06 94 19 66 296 186 21 9469 464 941 1 942 98 9414 620 940 106 2 120 128 1201 919 11980 600 11980 09 1 2482 2482 421 421 4246 4246 028 028 84 84 6149 6149 1 2986 2666 04 69 42 42 040 040 96 96 6162 6162 19 68 288 406 640 620 400 948 96 68 6290 62 62 21 822 82 8204 4610 8204 9 822 6190 828 660 2 109 466 1091 44 10899 6228 10880 661 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. FCLI 124 Qv [m /h] k (Pc) k (Ps) Speed V4 10 1 1 Speed V 10 0.8 0.82 Speed V2 1100 0.1 0.69 Speed V1 0 0.2 0.0 IFCLITY1106-010_01 2

COOLING CAPACITY - FCLI 124 Tw 11 1 1 T Ta W.B. Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] Pc [W] Ps [W] 21 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 2 C Ta D.B. 29 C Ta D.B. 0 C Ta D.B. 1 2964 2964 01 01 4416 4416 116 116 81 81 6162 6162 1 4044 204 4190 40 40 40 128 128 828 828 614 614 19 6288 21 62 4020 626 498 6269 88 6401 698 64 64 21 8644 400 8626 49 8608 2 889 649 880 6 2 11164 4 111 9 11119 624 11100 610 1 2419 2419 241 241 401 401 4 4 481 481 840 840 1 28 281 4019 4019 46 46 494 494 8 8 19 496 2668 49 48 128 4290 412 1 84 84 992 992 21 2 422 2 10 2 88 60 6292 2 10129 421 10129 114 10092 886 10092 629 1 1416 1416 24 24 42 42 426 426 040 040 418 418 1 1419 1419 28 28 49 49 428 428 0 0 42 42 19 244 192 28 268 912 684 46 46 14 14 462 462 21 89 2860 82 648 6048 448 626 8 6489 94 2 8846 806 88 488 882 69 8809 49 1 220 220 2961 2961 689 689 498 498 09 09 44 44 1 281 281 296 296 698 698 4404 4404 110 110 46 46 19 4 240 422 181 4429 992 468 468 122 122 469 469 21 629 20 616 989 604 460 6691 2 622 91 2 9249 96 9240 42 9212 24 920 909 1 1499 1499 2444 2444 21 21 401 401 40 40 116 116 1 10 10 244 244 2 2 4019 4019 46 46 128 128 19 26 1601 29 22 28 16 4101 4101 469 469 1 1 21 68 2668 68 448 481 42 21 108 89 2 2 806 0 808 4282 809 0 809 441 1 1 1 1429 1429 2602 2602 48 48 4284 4284 4668 4668 1 1 1 1429 1429 2602 2602 490 490 4290 4290 46 46 19 8 8 14 14 26 26 49 49 429 429 468 468 21 222 166 490 268 41 68 42 460 002 002 2 66 2869 66 644 602 446 660 4882 1 1410 1410 2208 2208 29 29 66 66 49 49 41 41 1 141 141 2211 2211 2961 2961 686 686 491 491 48 48 19 2060 148 2492 26 011 011 692 692 498 498 40 40 21 46 28 4624 12 400 90 4908 4 0 0 2 201 16 19 90 10 414 164 09 1 2 2 149 149 2460 2460 2 2 401 401 48 48 1 4 4 149 149 246 246 26 26 4019 4019 491 491 19 162 162 240 240 20 20 402 402 498 498 21 28 1616 1 2 69 480 4221 4221 4498 4498 2 1 261 1 420 840 4214 929 462 1 11 11 1 1 1486 1486 2640 2640 0 0 906 906 1 11 11 1 1 1486 1486 2646 2646 09 09 912 912 19 11 11 1 1 1492 1492 262 262 1 1 919 919 21 41 1 1 228 228 4 4 91 91 2 062 104 6 268 42 61 4662 4096 Tw = Inlet water temperature Ta W.B. = Inlet air temperature with wet bulb Ta D.B. = Inlet air temperature with dry bulb Pc [W] = Total cooling capacity Ps [w] = Sensible cooling capacity COOLING CAPACITY CORRECTION FACTORS The cooling outputs of the table are at maximum speed (maximum air flow). To determine the cooling capacity based on the speed (air flow), the values shown in the table must be multiplied by the following factors (k): NB: The values in bold type indicate the nominal value. If sensible power values are above the total cooling capacity, this means that cooling is carried out without dehumidification. In this case, only sensible power values are considered. FCLI 124 Qv [m /h] k (Pc) k (Ps) Speed V4 10 1 1 Speed V 10 0.8 0.82 Speed V2 1100 0.1 0.69 Speed V1 0 0.2 0.0 28 IFCLITY1106-010_01

HEATING CAPACITY "Module 600" FCLI 2 t C (water inlet temperature- air inlet temperature) FCLI 4 t C (water inlet temperature- air inlet temperature) Water flow rate [l/h] 0, 1 1, 2 2, Ph - Heating capacity [kw] FCLI 42 t C (water inlet temperature- air inlet temperature) FCLI 44 t C (water inlet temperature- air inlet temperature) Water flow rate [l/h] Water flow rate [l/h) Water flow rate [l/h] Ph - Heating capacity [kw] Ph - Heating capacity [kw] 0, 1 1, 2 2,, Ph - Heating capacity [kw] FCLI 62 t C (water inlet temperature- air inlet temperature) FCLI 64 t C (water inlet temperature- air inlet temperature) Water flow rate(l/h) Water flow rate(l/h) Ph - Heating capacity [W] 0 0, 1 1, 2 2,, 4 4, Ph - Heating capacity [W] HEATING CAPACITY CORRECTION FACTORS The heat yields refer to the maximum speed. For the rest of the speeds the values must be multiplied by the following factors: FCLI 2 4 42 44 62 64 Speed 4 (Maximum) - - 1 1 1 1 Speed 1 1 0.81 0.89 0.80 0.89 Speed 2 0.82 0.84 0.61 0.8 0.66 0.81 Speed 1 (Minimum) 0.1 0. 0.0 0.2 0. 0. IFCLITY1106-010_01 29

HEATING OUTPUT "Modulo 840" FCLI 82 Water flow rate [l/h] t C (water inlet temperature- air inlet temperature) 1200 20 C 0 C 40 C 0 C 60 C 0 C 1100 1000 900 800 00 600 00 400 00 2 4 6 8 10 12 14 16 18 Heating capacity [kw] FCLI 122 Water flow rate [l/h] t C (water inlet temperature- air inlet temperature) 2000 20 C 0 C 40 C 0 C 60 C 0 C 1800 1600 1400 1200 1000 800 600 400 4 6 8 10 12 14 16 18 20 22 24 26 28 0 2 Heating capacity [kw] FCLI 124 Water flow rate [l/h) t C (water inlet temperature- air inlet temperature) 2000 20 C 0 C 40 C 0 C 60 C 0 C 1800 1600 1400 1200 1000 800 600 400 4 6 8 10 12 14 16 18 20 Heating capacity [kw] HEATING CAPACITY CORRECTION FACTORS The heat yields refer to the maximum speed. For the rest of the speeds the values must be multiplied by the following factors: FCLI 82 122 124 Speed 4 (Maximum) 1 1 1 Speed 0.91 0.81 0.8 Speed 2 0.61 0.68 0.4 Speed 1 (Minimum) 0.49 0.49 0.6 0 IFCLITY1106-010_01

COIL PRESSURE DROPS (VL version without valve) Pressure drops [kpa] - Heating with 0 C water Water flow rate [l/h] FCLI2 FCLI42 FCLI62 FCLI82 FCLI122 100 1.0 0. 0.6 0.4 0.1 200.1 2. 2. 1.20 0.60 00.1.29 4.84 2.49 1.24 400 12.9 8.8 8.12 4.18 2.0 00 19. 1.26 12.1 6.24.10 600 26.84 18.41 16.84 8.6 4.0 00.42 24.0 22.2 11.44.68 800 4.04 0.90 28.2 14.4.22 900.68 8.19 4.9 1.98 8.9 1000 6.1 46.1 42.2 21. 10.9 1100 9.90 4.81 0.1 2.80 12.81 1200 9.4 64.10 8.66 0.1 14.98 100 10.9 4.04 6. 4.8 1.0 1400 12.4 84.60.41 9.82 19. 100 19.64 9.9 8.6 4.09 22.9 1600 16.8 10.9 98.4 0.64 2.14 100 14.9 120.00 109.80 6.48 28.04 1800 19.89 1.00 121.0 62.60 1.08 1900 21.0 146.9 14.1 69.00 4.26 2000 24. 160. 14.11.68. 2100 2.89 1. 160.61 82.62 41.02 2200 28.24 190.86 14.64 89.84 44.60 200 01.42 206.6 189.19 9.2 48.2 2400 2.41 22.22 204.2 10.0 2.1 200 0.2 240.24 219.82 11.08 6.1 Pressure drops [kpa] - Heating with 0 C water Water flow rate [l/h] FCLI4 FCLI44 FCLI64 FCLI124 0 0.4 0.0 0.1 0.12 100 2.8 2.44 2.49 0.40 10.4.06.16 0.84 200 8.9 8.49 8.6 1.41 20 1.40 12.69 12.9 2.10 00 18.61 1.62 1.98 2.92 0 24.6 2.26 2..8 400 1.24 29.8 0.18 4.89 00 46.68 44.20 4.10.1 600 64.81 61.6 62.62 10.1 00 8. 80.99 82.64 1.40 800 108. 102.99 10.10 1.04 900 14.46 12.1 129.92 21.06 1000 162. 1.90 1.0 2.46 1100 192.9 182.0 186.44 0.2 1200 22.6 21.68 218.0. 100 260.64 246.80 21.84 40.8 1400 29.84 282.01 28.8 46.6 100.22 19.0 2.8 2.82 1600 8.6 8.64 6.9 9. 100 422.4 99.99 408.1 66.1 1800 468.21 44. 42.40.4 1900 16.06 488.6 498.64 80.84 2000 6.98.91 46.8 88.66 IFCLITY1106-010_01 1

COIL PRESSURE DROPS (VL version without valve) Pressure drops [kpa] - Cooling with C water Water flow rate [l/h] FCLI2 FCLI42 FCLI62 FCLI82 FCLI122 FCLI4 FCLI44 FCLI64 FCLI124 100 1.19 0.80 0. 0. 0.19 1.19 0.81 0. 0.29 200 4.1 2. 2.62 1.0 0.6 4.1 2.81 1.0 0.99 00 8.6..44 2.0 1.8 8.6.82 2.0 2.06 400 14. 9.64 9.1 4.4 2.2 14. 9. 4.4.46 00 21.48 14.41 1.6 6.8.46 21.48 14.60 6.8.1 600 29.82 20.01 18.9 9.42 4.81 29.82 20.2 9.42.18 00 9. 26.41 2.01 12.4 6. 9. 26. 12.4 9.48 800 0.0.8 1.81 1.81 8.0 0.0 4.01 1.81 12.0 900 61.8 41.2 9.2 19.4 9.98 61.8 42.0 19.4 14.90 1000 4.8 0.19 4. 2.62 12.06 4.8 0.8 2.62 18.01 1100 88.8 9.8 6.42 28.04 14.2 88.8 60.4 28.04 21.8 1200 10.8 69.68 6.99 2.80 16.4 10.8 0. 2.80 2.01 100 119.9 80.48 6.21.88 19.4 119.9 81.1.88 28.88 1400 1.04 91.96 8.09 4.29 22.10 1.04 9.14 4.29.01 100 1.16 104.12 98.61 49.01 2.02 1.16 10.4 49.01. 1600 14.2 116.9 110..0 28.10 14.2 118.44.0 41.9 100 194. 10.4 12.2 61.9 1.4 194. 12.10 61.9 46.81 1800 21.4 144. 16.91 68.0 4.4 21.4 146.42 68.0 1.89 1900 2.4 19.4 10.90.00 8.29 2.4 161.8.00.19 2000 260.42 14. 16.0 82.26 41.99 260.42 16.99 82.26 62.2 2100 284.2 190.80 180.69 89.81 4.8 284.2 19.24 89.81 68.48 2200 09.1 20.46 196.4 9.6 49.8 09.1 210.11 9.6 4.46 200 4.91 224.4 212.84 10.9 4.01 4.91 22.62 10.9 80.66 2400 61. 242.64 229.8 114.21 8.0 61. 24.4 114.21 8.08 200 89.14 261.14 24.0 122.92 62. 89.14 264.48 122.92 9.2 2 IFCLITY1106-010_01

CORRECTION FACTORS WHEN OPERATING USING GLYCOL WATER Key: Pressure drops Air flow rate Capacity COOLING FUNCTION MODE HEATING FUNCTION MODE GLYCOL WATER AT 10% 1,2 1,4 Correction factor 1,1 1,0 0,9 Correction factor 1, 1,2 1,1 1,0 0,9 0,8 6 8 9 10 11 12 1 14 1 16 1 C Medium glycol water temperature 0,8 0 40 0 60 0 80 90 C Medium glycol water temperature GLYCOL WATER AT 20% 1,2 1,4 1,1 1, Correction factor 1,0 0,9 0,8 0, Correction factor 1,2 1,1 1,0 0,9 0,6 6 8 9 10 11 12 1 14 1 16 1 C Medium glycol water temperature 0,8 0 40 0 60 0 80 90 C Medium glycol water temperature GLYCOL WATER AT % Correction factor 1,6 1, 1,4 1, 1,2 1,1 1,0 0,9 0,8 0, 0,6 0, 6 8 9 10 11 12 1 14 1 16 1 18 C Medium glycol water temperature Correction factor 1,4 1, 1,2 1,1 1,0 0,9 0,8 0 40 0 60 0 80 90 C Medium glycol water temperature IFCLITY1106-010_01

SOUND POWER LEVEL IN db (A) Mod. Speed Central frequency band [Hz] Over-all 12 20 00 1000 2000 4000 8000 db db(a) FCLI2 FCLI4 Speed (Maximum) 49.6 48. 4. 9.1 6.2 20. 14.0 46 Speed 2 8.2 40.2 8. 1.0 2.9 22.4 18.9 44 8 Speed 1 (Minimum).2.2. 28.0 20.9 19.4 1.9 41 FCLI42 FCLI44 Speed 4 (Super Maximum) 4.1 4.2 1. 46.8 44.0 1.2 16.6 9 Speed 49.6 48. 4. 9.1 6.2 20. 14.0 46 Speed 2 8.2 40.2 8. 1.0 2.9 22.4 18.9 44 8 Speed 1 (Minimum).2.2. 28.0 20.9 19.4 1.9 41 FCLI62 FCLI64 Speed 4 (Super Maximum) 60. 6. 8.. 2. 4.2 1.8 6 61 Speed.1.2 2. 4.8 4.0 2.2 1. 60 4 Speed 2 48.9 48.9 46.0 9. 6.0 19.4 10.6 4 Speed 1 (Minimum) 42.6 4. 41.4 2.0 2. 9.1 9.4 48 41 FCLI82 Speed 4 (Super Maximum). 49. 46.2 46. 9.0 28. 18.1 9 0 Speed 6.4 42.6 42.1 40.1 2.2. 12.9 4 Speed 2. 41.2 41.0.0 2.8 9.9 12. 6 4 Speed 1 (Minimum) 1.. 6.6 2.9 0.4 11.0 12.2 2 9 FCLI122 FCLI124 Speed 4 (Super Maximum) 6.1 60.1 6..1 2. 46. 6.6 66 60 Speed 8.8. 49.8 0.1 4.9.0 2. 61 4 Speed 2 9.6 48. 46.6 46.2 4.6 21.8 18.1 60 0 Speed 1 (Minimum).4 41.6 41.1 9.1 24.2 10.1 1. 6 44 = EUROVENT 8/2 (ISO 41/2001) certified acoustic tests SOUND PRESSURE LEVEL expressed in db (A) Speed FCLI 2 4 42 44 62 64 82 122 124 Speed 4 (Super Maximum) db(a) - - 44 44 2 2 41 1 1 Speed db(a) 4 4 6 4 4 Speed 2 db(a) 29 29 29 29 8 8 4 41 41 Speed 1 (Minimum) db(a) 26 26 26 26 2 2 0 Level of sound pressure (A-weighted) measured in the room with volume V = 100 m ; reverberation time t = 0. s; direction factor Q = 2; distance r = 2.m; 4 IFCLITY1106-010_01

ACCESSORIES Consult the compatibility table to choose accessories. FCLI 2 4 42 44 62 64 82 122 124 Obligatory accessories GLLI10 GLLI20 WMT20* Obligatory accessories for the VMF System GLLI10N GLLI20N VMF-E4** Accessory for installation FCLM10 Accessory for air purification FEL10 Accessories for air delivery in an adjacent room and for connection to a fresh air intake KFL KFL20 KFLD* KFLD20 Accessories valves VHL1 VHL20 VHL2 VHL22 Accessory probe for WMT20 SWI FCLI / VMF System Accessories to combine with the GLLI10N and GLLI20N grilles with VMF-E4 control panels FCLI 2 4 42 44 62 64 82 122 124 Accessory main interface panel for plant management VMF-EB VMF-EN Accessory water temperature probe for a 2-pipe system SW4 Accessories water temperature probes for a 4-pipe system VMF-SW1 *** SW4*** Obligatory accessories:essential for unit operation. GLLI and GLLI_N range intake and delivery grille units with electric box are obligatory accessories as the FCLI units are dispatched without these components. The GLLI and GLLI_N range accessories consist of a grille with central suction and lateral air delivery fins, all within a frame, and include an electric box for FCLI versions. NB> * The GLLI10 and GLLI20 grille units have to be combined with a 0-10V output control panel to control ventilation speed (see WMT20). ** The GLLI10N and GLLI20N grille units have to be combined with a VMF range control panel (see VMF-E4). *** Cold water circuit **** Hot water circuit Some accessories may not be applied at the same time on the same fan coil, while others need to be used with other accessories and/or with a particular fan coil configuration. Before placing an order, see documentation relating to all accessories and the fan coil. IFCLITY1106-010_01

ACCESSORIES GLLI10N - GLLI20N INTAKE AND DELIVERY GRILLE UNIT WITH "VMF System" THERMOSTAT GLLI 10 N GLLI 20 N GLLI10N 600x600 GLLI10N 840x600 Intake and delivery grille unit with "VMF System" advanced electronic thermostat. The grille is part of the GLLI-N range grille unit (obligatory accessory). The form and opening of the suction louvres were developed in order to have the best possible distribution of the air, both when functioning in winter as well as in summer. Suction occurs through the central grille, and delivery through the manually adjustable, perimetric slots. In plastic, colour RAL 9010, it contains the air filter that can be easily removed for cleaning. The GLLI_N includes the electric box with incorporated VMF System thermostat board, with bayonet coupling to the connector bound to the unit's load-bearing structure. The GLLI_N needs to be interfaced with a VMF-E4 external control panel if installed on a single FCLI unit, or with a "Master" function in a network with up to other "Slave" fan coils supplied with "VMF System" thermostat only (GLLI-N and/or GLL-N and/or VMF-E18 and/or VMF-E1 and/or VMF-E0). If the GLLI_N is combined with a VMF-E4 control panel ("Master" configuration), the fan coil can be connected to a VMF-E central supervisor system. The GLLI_N accessory consists of : Intake and delivery grille unit "VMF System" advanced electronic thermostat board, installed in the electric box, easily applicable to the fan coil. System with connection cables to the Inverter Command Module. The cables are wired with connectors for quick connection. The thermostat board has a protective fuse, a dip-switch for configuration, and connectors for connection with: - the power supply, - the earthing, - the valve control, - the Inverter command module power supply, - the ambient air temperature probe, - the water temperature probe, - the auxiliary water temperature probe, - the control panel (user interface), - the presence sensor, - the external contact, - the microswitch contact - the VMF-E central supervisor system serial, - the fan coil network serial (TTL). The thermostat is used to control: Three fan coil speeds in manual mode. Continuous ventilation and thermostat control, by controlling the valves Automatic fan mode with BRUSHLESS motor depending on the load Season visualisation Visualisation of alarms and ventilation request Up to two ON/OFF 2- or -way valves The switch-on of an electric heater An air temperature probe A water temperature probe, with minimum and maximum temperature and changeover functions An additional water probe for controlling the second coil (4-pipe systems) Season change according to the water or air temperature (4-pipe systems) Input for external contact. This is a digital input with the following logic: - When open, the thermostat works normally; - When closed, the fan coil is switched off. Anti-freeze function Presence sensor to enable the SLEEP function from an external contact (reduction of ambient set-point by 2 or degrees, depending on the settings, if a room is unoccupied) Input for local serial. The thermostat is designed to communicate with GLLI-N and/or GLL-N and/or VMF-E18 and/or VMF-E1 and/or VMF-E0 type thermostats via a dedicated serial based on the TTL logic standards. This serial communication is essential for the exchange of information within small fan coil networks (up to 6 thermostats with a maximum length of 0 metres). It was designed, in fact, for small areas where the fan coils (more than one) need to be controlled from a single control point. More specifically, this network always contains a Master (to which a user interface VMF-E2, VMF- E4 is connected) which controls the operation of the Slaves connected to it, according to the settings made on its user interface. Input for supervision serial. In networks made up of several fan coils subdivided into independent temperature areas, the GLLI-N area thermostat allows communication with a central system supervisor (VMF-E). 6 IFCLITY1106-010_01

ACCESSORIES GLLI10 - GLLI20 INTAKE AND DELIVERY GRILLE UNIT GLLI 10 GLLI 20 The GLLI includes the electric box, with bayonet coupling to the connector bound to the unit's load-bearing structure. The GLLI needs to be interfaced with an external control panel (not included) ) with thermostat and ventilation speed control, with a 0-10V output. GLLI10 (600x600) GLLI20 (840x840) Suction and delivery grille unit The grille is part of the GLLI range grille unit (obligatory accessory). The form and opening of the suction louvres were developed in order to have the best possible distribution of the air, both when functioning in winter as well as in summer. Suction occurs through the central grille, and delivery through the manually adjustable, perimetric slots. In plastic, colour RAL 9010, it contains the air filter that can be easily removed for cleaning. FEL10 ELECTROSTATICALLY PRE-CHARGED AIR FILTER FEL10 For GLLI10 and GLLI10N grille units. Electrostatically pre-charged air filter, regenerated with class-2 fire resistance (UL 900). Supplied in a sealed package which should only be opened at the time of use. The electrostatically pre-charged filter combines the normal mechanical filtering of the air that passes through the filter, with an electrostatic attraction of powder that increases its filtering considerably. The electrostatic filter charge runs down two years after the opening of the box; after this period it behaves like a normal filter. Frequent cleaning, removal (with a vacuum) of the dust that has built up, and the use of water and detergents considerably speeds up the deterioration of the electrostatic charge. IFCLITY1106-010_01

ACCESSORIES KFL DELIVERY FLANGE KFL10 KFL20 KFL10 Delivery flange for directing air to an adjacent room. KFL20 (***) Delivery flange for directing air to an adjacent room. Up to three KFL20 can be assembled on a single unit. Ø 10 KFLD SUCTION FLANGE KFLD10 KFLD Suction flange for connection to a duct, to introduce fresh air into the room via an external fan. The fresh air is directly introduced from the fin corresponding to the flange position. The air is not extracted by the fan, so is not mixed inside the unit with air that has already been treated. KFLD20 KFLD20 (***) Suction flange for connection to a duct, to introduce fresh air into the room via an external fan. The fresh air is directly introduced from the fin corresponding to the flange position. The air is not extracted by the fan, so is not mixed inside the unit with air that has already been treated. Up to two KFL20D devices can be assembled on a single unit. Ø 10 8 IFCLITY1106-010_01

ACCESSORIES VHL1 - VHL20 -WAY VALVES KIT VHL1 - VHL20 Motor-driven three-way valve for the heating battery in 4-pipe systems. Obligatory accessory for 4-pipe systems. VHL2 - VHL22 2-WAY VALVES KIT VHL2 - VHL22 motor-driven two-way valve for the heating battery in 4-pipe systems. Obligatory accessory in 4-pipe systems with variable flow rates. IFCLITY1106-010_01 9

ACCESSORIES CONTROL PANEL WITH THERMOSTAT CONTROL PANELS *: These accessories can only be used with the FCLI models fitted with GLLI range grilles. WMT20 Wired control panel with thermostat and digital display, ventilation speed control with 0-10V output; wall mounting. Reconfigurable to meet the needs of different types of system P or P+I adjustment of the fan with 0..10V proportional output Adjustment with ON-OFF actuators control Range of setpoint knob different for heating and cooling Special functions, economy, dirty filter warning, window contact Input for centralised* summer/winter selection Selectable power supply 20V~ or 24V~ SWI WATER TEMPERATURE PROBE 2000mm SWI Water temperature probe for WMT20 control panels. Cable length L = 2m. ACCESSORIES WATER TEMPERATURE PROBES FOR VMF SYSTEM SW4 WATER TEMPERATURE PROBE FOR: - 2-PIPE SYSTEMS - HOT WATER CIRCUIT IN 4-PIPE SYSTEMS SW4 Water temperature probe for VMF System thermostats to be used in: - 2-pipe systems - the hot water circuit in 4-pipe systems VMF-SW1 WATER TEMPERATURE PROBE FOR: - COLD WATER CIRCUIT IN 4-PIPE SYSTEMS VMF-SW1 VMF-SW1: Water temperature probe for VMF System thermostats to be used in: - the cold water circuit in 4-pipe systems 40 IFCLITY1106-010_01