Post on 22-Sep-2020
• 1.- About fans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . pag. 3General conceptsMotor positions and arrangements
• 2.- Construction features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . pag. 9Classification of axial fans
Axial fans overviewEF tubular fansES bell shaped fansEB high temperature fans
ImpellersBlade pitchMotors
3.- Codification and guide to curves . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . pag. 19
4.- Engineering data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . pag. 27Direct driven axial fan
ES and EF available sizes Aluminium impeller
ES suitable motorsEF suitable motorsES-EF curves
Steel hub impellerES suitable motorsEF suitable motorsES-EF curves
Belt driven axial fanEF and EB available sizes Aluminium impeller
EF suitable motorsEF curvesEB suitable motorsEB curves
Steel hub impellerEF suitable motors
Arrangement 9Arrangement 12
EF curvesEB suitable motorsEB curves
GENERAL INDEX
2
GENERAL INDEX
• 5.- Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . pag. 147Counter flangeInlet discharge governorAir reducing flapDamperThrottle valveFlexible connectionFilter inlet sideVibration dampersProtection net “RC”Protection net “RG”Inlet nozzleSquare basesSupports PD (for EF)Supports PD/S (for ES)Supports PD/V (for vertical assembly)
• 6.- About Ferrari. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . pag. 165General information Definitions and categoriesConstruction characteristicsSafetyPerformance, noise emissions and vibrationsDocumentation
AXIAL FANS
ABOUT FANS
ABOUT FANS1. - General concepts ........................................................................................................pag. 5
2. - Motor positions and arrangements ........................................................................pag. 7
5
About fans
General concepts
About fans
6
7
About fans
Motor positions and arrangements
About fans
8
ARRANGEMENT 1
ARRANGEMENT 4
ARRANGEMENT 9
ARRANGEMENT 12
For belt drive - wheel keyed overhung.Working temperature:• min. - 20°C• max + 60°C.For higher temperatures see fanseries EB.
For direct drive - wheel keyed overhung.Working temperature:• min. - 20°C• max + 40°C.
- Up to motors with whed-base 250 mm for fanswith impeller with cap in steel.- Up to motors with whed-base 200 mm for fanswith impeller with cap in aluminium.For belt drive - same as 1 with motor supportedby the casing.Working temperature:• min. - 20°C• max + 60°C.For higher temperatures see fan series EB.
For belt drive - both fan and motor supported bythe foundation frame.Working temperature:• min. - 20°C• max + 60°C.For higher temperatures see fan series EB.
AXIAL FANS
CONSTRUCTION FEATURES
CONSTRUCTION FEATURES1. - Classification of axial fans .........................................................................................pag. 11
1.1. - Axial fans overview ........................................................................................pag. 11
1.2. - EF Tubular fan .................................................................................................pag. 12
1.3. - ES bell shaped fan ..........................................................................................pag. 14
1.4. - EB high temperature fan ..............................................................................pag. 15
2. - Impellers.......................................................................................................................pag. 16
3. - Blade pitch ...................................................................................................................pag. 17
4. - Motors ..........................................................................................................................pag. 17
11
Construction features
1.- Classification of axial fans1.1.- Axial fans overview
AXIAL FANS
ES DIRECT
ALUMINIUM HUB
ARRANGEMENT 9
ARRANGEMENT 9
ARRANGEMENT 12
ARRANGEMENT 9
STEEL HUB
ALUMINIUM HUB
STEEL HUB
ALUMINIUM HUB
STEEL HUB
DIRECT
BELT DRIVEN
BELT DRIVEN
EF
EB
ALUMINIUM HUB
STEEL HUB
ARRANGEMENT 9
Construction features
12
1.2.- EF Tubular fan
Main feature of EF fans is its tubular design with inlet and outlet flangedcasing. This simple circular design, allows these fans to be easily in-stalled in ductwork.
They are a powerful tool in the hands of ventilation systems designers,as they can cover a wide range of pressure and capacity and at thesame time they can keep space requirements small due to the wide va-riety of suitable options.
Casing
The casing is built in strong welded sheet. For fans with impeller inaluminium up to size 1000 mm, the standard coating is done by ca-thode epoxy paint RAL 7045 and cataphoretic cycle and subsequentbaking at 170°C. For sizes over this diameter the casing is hot dip gal-vanized. Fans with impeller with steel hub are hot dip galvanized forany size.
Impeller
EF tubular axial fans, can either be found with full aluminium impeller or with steel hub impeller completed with aluminium blades.More information about the main differences and advantages of those two kinds of impellers can be found in paragraph 3.2. When design conditions allow that, full aluminium impellers become an optimal cost save solution. Both direct and belt driven EFaxial fans, can be selected with aluminium impellers for diameter up in 310 mm to 1400 mm. When installation requirements go over aluminium engineering limits, steel hub impeller with aluminium blades need to be used.This type of impeller represents a perfect solution for high performance applications. Available steel hub impellers for EF fans coverthe range between 900 mm and 1800 mm diameter impeller for direct driven fans and between 900 mm and 2000 mm diameterimpeller for belt driven fans.
Arrangements
The EF axial tubular fans are the only one kind of fans available either in belt or direct drive mode.
Direct driven
In this kind of construction the motor is supported by a base tightly anchored to the fan casing. Air can flow from motor to impeller(standard solution) or from impeller to motor, but anyhow the motor is involved by fluid stream. This fact state the temperature rangeof the air flow to the limits recommended by motor manufacturer, normally between -20°C to 40°C. Direct driven fans are able to match working conditions through the regulation of pitch angle (see section 3 in page 17).
13
Construction features
Belt driven
In this arrangement the motor is set it out of the air flow stream. Torque and rotational motion is transferred from motor to impellerthrough a belt and pulleys transmission. In this situation pulleys are not completely isolated from motor flow, so that states the ma-ximum temperature of the flow running through the fan to 60°C.
EF fans with aluminium impellers shall be supplied in arrangement 9,with motor supported by fan casing. Support feet can be supply on de-mand when the fan is requested to stand itself.
EF fans with impeller with steel hub and aluminium blades, normallyneed higher motors sizes to support performance demanded. As notall the motor sizes can be sustained by fan casing, some of these fansshall be provided with base frame to sustain heaviest motors. Informa-tion about maximum motor size suitable for any arrangement and forany fan can be found in the engineering data section of the catalogue.Support feet can be supply on demand when the fan is requested tostand itself, keeping the arrangement 9.
Construction features
14
1.3.-ES bell shaped fan
Its special bell shaped casing converts this axial fan in the perfect solution for allnon ducted inlets systems. It increases efficiency and reduce noise emissionsby minimizing fan entry losses.
The adjustable pitch angle and the wide range of appropriate motors let designengineers to find a suitable model for any requested performance.
Casing
The casing is built in strong welded sheet. For fans with impeller in aluminium upto size 1000 mm, the standard coating is done by cathode epoxy paint RAL 7045and cataphoretic cycle and subsequent baking at 170°C. For sizes over this dia-meter the casing is hot dip galvanized. Fans with impeller with steel hub are hotdip galvanized for any size.
Impeller
ES bell shaped axial fans, can either be found with full aluminium impeller or withsteel hub impeller completed with aluminium blades. More information about the main differences and advantages of those two kindsof impellers can be found in paragraph 3.2.
When design conditions allow that, full aluminium impellers become an optimal cost save solution. ES can be selected with alu-minium impellers for diameter up in 310 mm to 1400 mm. When installation requirements go over aluminium engineering limits, steel hub impeller with aluminium blades need to be used.This type of impeller represents a perfect solution for high performance applications. Available steel hub impellers for ES fans coverthe range between 900 mm and 1800 mm diameter impeller.
Arrangements
Direct driven
In this kind of construction the motor is supported by a base tightly anchored to the fan casing. Air can flow from motor to impel-ler (standard solution) or from impeller to motor, but anyhow the motor is involved by fluid stream. This fact state the temperature
range of the air flow to the limits recommended by motor manufacturer, nor-mally between -20°C to 40°C.
Direct driven fans are able to match working conditions through the regula-tion of pitch angle (see section in page …).Support feed shall be supplied on demand when fan is requested need tostand itself. Safety protection net in the fan inlet is recommended to prevent any kind ofinjures. For more information about options and accessories see section 6,accessories.
15
Construction features
1.4.- EB high temperature fan
This fan represents the solution for applications where air temperature go over 60°C. The motor and the transmission completelyisolated from air stream, let it deliver air at temperatures up to 180°C.
Casing
The casing is built in strong welded sheet. For fans with impeller in aluminium upto size 900 mm, the standard coating is made by cathode epoxy paint RAL 7045and cataphoretic cycle and subsequent baking at 170°C. For sizes over this dia-meter the casing is hot dip galvanized. Fans with impeller with steel hub are hotdip galvanized for any size.
Impeller
EB high temperature axial fans, can either be found with full aluminium impelleror with steel hub impeller completed with aluminium blades. More informationabout the main differences and advantages of those two kinds of impellers canbe found in paragraph 3.2.
When design conditions allow that, full aluminium impellers become an optimalcost save solution. EB can be selected with aluminium impellers for diameter upin 350 mm to 1400 mm. When installation requirements go over aluminium engineering limits, steel hubimpeller with aluminium blades need to be used. This type of impeller representsa perfect solution for high performance applications. Available steel hub impellersfor EB fans cover the range between 900 mm and 1800 mm diameter impeller.
Arrangements
Belt driven
In this arrangement the motor is set it out of the air flow stream. Torqueand rotational motion is transferred from motor to impeller through a beltand pulleys transmission. In this situation the transmission is completelyisolated from motor flow, so the maximum temperature the fan could reachis 180°C. These fans are normally supplied in arrangement 9 with motor supportedby fan casing. However, sometimes for the biggest sizes arrangement 12with baseframe could be possible. Information about maximum motor sizesuitable for any arrangement and for any fan can be found in the engi-neering data section of the catalogue.Support feet can be supply on demand when the fan is requested to standitself, keeping the arrangement 9.
Construction features
16
2.- Impellers
Adjustable pitch
Aluminium hubDie cast aluminium hub machined to fix
adjustable blades
Extraction GrooveFor easy removal of impeller from motor
Aluminium bladesDie cast aluminium blades
Fixing boltthreaded holes
Aluminium impeller
Steel Hub impeller
Blade positionindexIndication of current and next available blade pitch
Extraction holesFour threaded holes permit the easy dismantling of impeller from motor
Hub - Single piece steel pressed hub machined to fixadjustable blades
BushFor motor-impeller attachment
Aluminium bladesDie cast aluminium blades
Rotationsense printIndication of the right rotation way for the impeller
Motor fixing boltTo fix impeller to motor shaft
Cover discfixing bolts
Adjustable pitch
17
Construction features
3.- Blade pitch
Direct driven axial fans are supplied with fixed, set in plant, blade pitch. However, to cover expansion or reduction in air needs, bladepitch (blade pitch for steel hub impeller is shown in figure) for direct driven axial fan may be changed. In fact, performance curvemoves up or down in the charts when blade pitch changes. As this increment in the pitch would increase the absorbed power offan too, before changing it, it’s very important to verify that power of installed motor can cover new power absorption.Precise information about the procedure for blade pitch adjustment can be found in the manual “Warning and instructions for use”supplied with fans.
4.- Motors
Next table shows main features for motors provided with Ferrari fans:
Feature Standard furnishing Special furnishing
Type TEFC squirrel cage induction -----------
Sizes According to EN 50347 Possible on demand
Efficiency EFF 2 EFF 1
Degree of protection IP 55 Possible on demand
Insulation Class F Class H
Phases 3 1
Mounting arrangement B3 Possible on demand
Frequency drives availability Up to size 250 Over size 250
Furnishing Supplied by Ferrari w/o or free issue motor
Winding 50 Hz Special winding 60 Hz
Voltage 230 VΔ / 400V Y for sizes <132 Possible on demand
400V Δ / 690V Y for sizes ≥132 Possible on demand
TypeTEFC totally enclosed fan cooled
EfficiencyMotors normally supplied are EFF 2 according to the European classes stated by CEMEP (European Committee of Manufacturers ofElectrical Machines and Power electronics). On demand, EFF 1 motors can be supplied. This efficiency levels are applicable for 2 and4 poles motors 3ph.
Degree of protectionIP 55 Motors protected against dust and against water jets.
InsulationFerrari use class F insulation systems that cover most common requirement among the industry today.
Construction features
18
Frequency drivesStandard motors up to size normally 250 can be driven by frequency converter without any modification, but duty cycle need to bechecked. Motors over size 250 driven by frequency converter need to be reinforced.
FurnishingFans are normally supplied with motor. On demand is possible provide fans without motor or even assembly motors sent by customersin our plants.
WindingNormally wound for 50 Hz (suitable to be fed at 60 Hz with the right voltage), on demand special winding for 60 Hz. See next paragraph.
VoltageMotors supplied with Ferrari fans are wound for a rated supply of 50 Hz and for two different voltages according to the Star or Delta win-ding connection. For motors size <132 the standard voltage is 230 VΔ / 400V Y. That means that the fan can be used at voltage 230 V set-ting connection or at voltage 400 V using Y connection. For motors size ≥ 132 the standard voltage is 400VΔ /690V Y. That means thatthe fan can be used at voltage 400 V setting Δ connection, or at voltage 400 V using Y connection. Permitted tolerance for voltage is ±5%. When those motors, wound for 50 Hz, are connected to 60 Hz supply, speed will increase by 20% with reference to speed at 50 Hz. Newperformance values will change according to voltage supplied at 60 Hz using the multipliers shown in the following table (indicative data):
For any other supplied voltage, next formulas can be used:
V50 = Rated voltage at 50 Hz V60 = Rated voltage at 60 Hz N50 = Speed at 50 Hz N60 = Speed at 60 Hz P50 = Power at 50 Hz P60 = Power at 60 Hz I50 = Current at 50 Hz I60 = Current at 60 Hz M50 = Torque at 50 Hz M60 = Torque at 60 Hz
P60 = P50 • V60
V50
P60 = P50 • = 22 • = 25.3 KwV60
V50
460400
144 •
1.2 460 = 138 Nm400
M60 = M50 •
V60
1.2 V50
M60 = = M50 •
V60
1.2 V50
N60 = 1.2 • N50
N60 = 1.2 • N50 = 1.2 • 1459 = 1751 r.p.m.
I60 = I50
I60 = I50 = 41.5 A
Example: Using the multipliers:
Feature Data at 50 Hz Multiplier Data at 60 Hz
Voltage (V) 400 --------- 460
Power (Kw) 22 1.15 25.3
Speed (r.p.m) 1459 1.2 1751
Current (A) 41.5 1 41.5
Torque (Nm) 144 0.96 138
Using the formulas:
50 Hz 60 Hz
Rated voltage V Supply voltage V New performance data at full load
Power Speed IN MN
230 230 1 1.2 1 0.83
265 1.15 1.2 1 0.96
275 1.2 1.2 1 1
400 400 1 1.2 1 0.83
460 1.15 1.2 1 0.96
480 1.2 1.2 1 1
AXIAL FANS
CODIFICATION AND GUIDE TO CURVES
CODIFICATION AND GUIDE TO CURVES
21
Codification and guide to curves
Codification and guide to curves
Fan diameter
31 310 mm
35 350 mm
40 400 mm
45 450 mm
50 500 mm
56 560 mm
63 630 mm
71 710 mm
80 800 mm
90 900 mm
100 1000 mm
112 1120 mm
125 1250 mm
140 1400 mm
160 1600 mm
180 1800 mmImpeller / Hub ratio
Speciality
A Without cooling disc
B With cooling disc
Type of fan
EF Tubular fan
ES Fan with iniet
nozzle
Pitch angle code
0 Over 40°
1 From 37° to 40°
2 From 33° to 46°
3 From 29° to 32°
4 From 25° to 28°
5 From 21° to 24°
6 From 17° to 20°
7 From 13° to 16°
8 From 9° to 12°
9 Up to 8°
Power transmission
4 Direct driven
9 Belt driven
arrangement 9
12 Belt driven
arrangement 12
Flow
A From motor to impeller
B From impeller to motor
EF 112 6 /H 4 A /A
Codification and guide to curves
22
80
78
77
Shaft powercurves
Efficiencycurves
Performancecurves
Capacity
Dinamicpressure line
Sound pressure
level
Pitch angleand code
ELVE EF 408-406-405 4A/AInstalled power 0,75 - 1,1 - 1,5 kW
ELVE ES 408-406-405 4A/AInstalled power 0,75 - 1,1 - 1,5 kW
Impeller diameter 400 mm Suitablemotors
η % EFFICIENCY OPERATING SPEED
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
23
Codification and guide to curves
Performance curves for direct driven axial fans working at 60 Hz haven’t been obtained by direct testing but choosing the suitable bladepitch angle in order to replicate performance of fans working at 50 Hz.
Impeller diameter. Fan size is constant for every curve. Fan size is defined by impeller diameter.
Pitch angle and suitable motorFor direct driven fan is not possible to choose the speed of the impeller as it have to follow the synchronism speed of motor. This speedis about 3600 r.p.m for 2 poles motor, 1800 r.p.m for 4 poles, 1200 r.p.m for 6 poles motors and 900 r.p.m for 8 poles motors. This fact couldmake difficult sometime to find a fan suitable to match the operation point. To solve this problem, performance curve of a fan can be mo-dified by changing the pitch angle of its blades. Increments of pitch angle will move the performance curve up in the chart and pressureand capacity will increase and so the absorbed power of the fan. Fan diameter and speed are constant for every chart and three curves (three for performance, three for efficiency and three for absorbedpower) with three different pitch angle matching the right motor have been plotted.
Shaft power curvesThis curves shown the absorbed power of the fan. These curves follow the formula:Those curves locate in the charts standardized motors power data. To know the absorbed power of a fan working point placed betweentwo curves, interpolation may be done. For a more precise value, the next formula can be use:
W= Absorbed power in Kw V= Air delivered in m3/s, shown in the capacity axis Pt= total pressure in Pa, shown in the pressure axis ηt= Efficiency of the fan as read in the chart in %There are three different curves corresponding to three different pitch angles.
Sound pressure levelIt indicates the sound pressure at 1,5 m distance from the fan with free inlet and outlet ducted, weighted considering scale A. This scaleconsiders the perception of sound by human ear. The units for sound pressure level are dBA.
Efficiency curveThis curve represents the total efficiency of the fan. That means the rate between the final energy received by the air and the energy sup-plied to the shaft of the fan. This efficiency reflects the losses into the fan but not the losses in drive.
Fan speedIt indicates the rotational speed of the impeller. This speed is constant for any chart.
Performance curveThis is the most representative curve of the fan. It shows the total pressure provided by the fan for a range of capacities. The point of in-tersection of the system curve and the performance curve determines the operating point of the fan. The curve doesn’t cover the entirerange from free delivery (no obstruction to flow) to no delivery, but only the useful zone of the curve where the efficiency is higher. The se-lection of the fan shall assure that the operating point of the fan lies in the useful zone. A fan working out of this zone could create insta-bility or overheating of the motor drive. There are three different performance curves corresponding to three different pitch angles.
Dynamic pressure lineThis line represents the dynamic pressure of the fan. For a given capacity this pressure doesn’t change and is readable in the pressureaxis. This dynamic pressure can be calculated using the formula Pd= ρ v2/2, where ρ is the density (1,226 Kg/m3) and v the velocity ofthe fluid.
Pressure AxisThe ordinate axis shows the pressure of the fan in kgf/m2 units.
Capacity Axis The abscissa axis shows the pressure of the fan in m3/s units. Example: the figures shows a fan diameter 400 mm working with a 2 poles motor (3600 r.p.m) . The selected operating point will have the next characteristics:- Capacity: 1,95 m3/s, as shown in abscissa axis- Dynamic pressure: 16.5 kgf/m2 This value is shown by the projection in the ordinate axis of the intersection between the line corre-
sponding to capacity and the dynamic pressure line. - The total pressure is 37 kgf/m2 as seen in pressure axis, by the projection in the ordinate axis of the intersection between the line cor-
responding to capacity and the performance curve. It’s possible now to read the pitch angle, at the bottom of the performance curve. Inthis case the angle is 18°.
- The efficiency is visible in the second chart and is 70%, considering the efficiency curve for 18°. - Is possible to read the absorbed power in the top chart, using always the curve corresponding to 18°. The absorbed power is 1,05 Kw.
At the bottom of the curve is possible now to read the code corresponding to the angle, that is 6 in this case for angle 18°. The complete code of the fan will be then EF 406/G and the installed motor 1,1 Kw.
W = V x Pt
10 x ηt
Codification and guide to curves
24
VENT EB 904/H 9B/BPitch angle 28°
Impeller diameter 900 mm
Impellerdiameter
Performancecurves
Efficiency
Velocity
Rotationalspeed
Soundpressure
level
Capacity
Powercurves
Pressureaxis
Dinamicpressure
Max allowable speed
Air density 1,226 kg/m3
Maximumallowed speed
Moment of inertia of impeller
25
Codification and guide to curves
Impeller diameter. Fan size is constant for every curve. Fan size is defined by impeller diameter.
Pitch angleIt indicates the pitch angle of the blades. This angle is fix and should not be changed for belt driven fans, as the setting of the fan isdone by modifying ratio between driving and driven pulley.
Performance curveThis is the most representative curve of the fan. It shows the total pressure provided by the fan for a range of capacities. The point of in-tersection of the system curve and the performance curve determines the operating point of the fan. The curve doesn’t cover the entirerange from free delivery (no obstruction to flow) to no delivery, but only the useful zone of the curve where the efficiency is higher. Theselection of the fan shall assure that the operating point of the fan lies in the useful zone. A fan working out of this zone could create in-stability or overheating of the motor drive.
EfficiencyIt indicates the total efficiency of the fan represent the rate between the final energy received by the air and the energy supplied shaft ofthe fan. This efficiency reflects the losses into the fan but not the losses in the transmission and motor.
Power curvesThose curves locate in the charts standardized motors power data. To know the absorbed power of a fan working point placed betweentwo curves, interpolation may be done. For a more precise value, the next formula can be use:
W= Absorbed power in Kw Pt= total pressure in Pa, shown in the pressure axis
V= Air delivered in m3/s, shown in the capacity axis ηt = Efficiency of the fan as read in the chart in %Since this absorbed power doesn’t includes the transmission losses, so this power need to be increased by at least 15% before selec-ting the motor to be installed.
Example. The working point in the chart indicates a pressure of 420 Pa and a capacity of 8,75 m3/s. The efficiency shown is 71. The ab-sorbed power is then:
This absorbed power need to be increase by 15%, so the power to be considered for the selection of the motor would be:5,17x1,15=5,95 Kw. So a motor 5,5 Kw power won’t be enough and a 7,5 Kw should be used.
Rotational speedIt indicates the rotational speed of the impeller of the fan. Once the fan transmission has been set, this speed doesn’t vary.
Pressure AxisThe ordinate axis shows the total pressure provided by the fan. This pressure can be read both in Pa and kgf/m2 units.
Capacity AxisThe first two abscissa axis show the capacity supplied by fan. In the first one expressed in m3/s, while in the second one in m3/h. The third and fourth axis present the dynamic pressure supplied by the fan in Pa and in kgf/m2 This dynamic pressure can be obtainedusing the formula Pd=ρ v2/2, where ρ is the density and v the velocity of the fluid.Last axis indicates the velocity of the fluid at inlet and outlet of the fan. This velocity is obtained by dividing the air delivered by the sec-tion of the fan.
Safe speedStrength and mechanical properties of engineering material are affected by and change with temperature: when temperature increase,mechanical strength decrease. To avoid any damage, the running speed of the fan must stand under safe speed, according to the maxi-mum temperature predicted in the installation.
Sound pressure levelIt indicates the sound pressure at 1,5 m distance from the fan with both sides ducted, weighted considering scale A. This scale consi-ders the perception of sound by human ear. The units for sound pressure level are dBA.
Factor of inertiaIt indicates the moment of inertia of the impeller P D2. The correspondence with J is:
J in Kg • m2
W = V x Pt
10 x ηt
J = P • D2
4
W = V x Pt = 8,75 x 420 = 5,17 Kw100 x ηt 10 x 71
Codification and guide to curves
NOTE:
26
DIRECT DRIVEN AXIAL FANS
SERIES
ES-EF
ENGINEERING DATA1. - Direct driven axial fan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 29
1.1. - ES and EF available sizes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 29
1.2. - Aluminium impeller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 33
1.2.1. - ES suitable motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 33
1.2.2. - EF suitable motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 34
1.2.3. - EF/ES curves on discharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 35
1.3. - Steel hub impeller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 71
1.3.1. - ES suitable motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 71
1.3.2.- EF suitable motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 72
1.3.3.- EF/H - ES/H curves . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 73
2. - Belt driven axial fan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 91
2.1. - EF and EB available sizes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 93
2.2. - Alluminium impeller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 97
2.2.1. - EF suitable motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 97
2.2.2. - EF curves on discharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 98
2.2.3. - EB suitable motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 112
2.2.4. - EB curves on discharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 113
2.3. - Steel hub impeller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 129
2.3.1. - EF suitable motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 129
2.3.1.1. - Arrangement 9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 129
2.3.1.2. - Arrangement 12 . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 130
2.3.2. - EF/H curves on discharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 131
2.3.3. - EB/H suitable motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 139
2.3.4. - EB/H curves on discharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .pag. 140
29
Engineering data
1.- Direct driven axial fan1.1.- ES and EF available sizes
Direct driven fan ES/EF Steel Hub
SIZE 2p 4p 6p 8p
310
350
400
450
500
560
630
710
800
900 900/H 900/H
1000 1000/K 1000/K 1000/K
1120 1120/H 1120/H 1120/H
1250 1250/H* 1250/H 1250/H
1400 1400/H 1400/H
1600 1600/H 1600/H
1800 1800/H* 1800/H
2000 2000/H (EF)
Direct driven fan ES/EF Aluminium Hub
SIZE 2p 4p 6p 8p
EF ES EF/ES EF ES EF ES
310 310/I 310/I 310/I
350 350/H 350/H 350/H
400 400/G 400/G 400/G
450 450/H 450/H 450/H
500 500/G 500/G
560 560/H 560/H
630 630/G 630/G
710 710/H 710/H 710/H
800 800/G 800/G 800/G 800/G
900900/F 900/F 900/F 900/F
900/I 900/I 900/I
10001000/E 1000/E 1000/E
1000/H 1000/H 1000/H 1000/H 1000/H
1120 1120/G 1120/G 1120/G 1120/G
1250 1250/F 1250/F 1250/F 1250/F
1400 1400/E 1400/E
* Fans with longer delivery time.
30
IMPELLERS WITH ALUMINIUM HUB
The axial fans FERRARI are suitable for large quantities of air at low pressures and run very quiet.
Compared with centrifugal fans the axial fans have the following advantages:• they are cheaper;• the impeller, rotation “RD” if seen from opposite side of inlet, wich has adjustableblades, makes it possible to adapt the fan to the requirements of the plant;• reduced space requirements;• shorter ducts, therefore cheaper.Every impeller has been examined as to UNI 10531 / ISO 5801.All specifications listed in the tables are referred to air at a temperature of 15°C, specific gravity 1.226 Kgf/m3.Noise level values were taken at an average distance of 1,5 m from the fan, the decibels mentioned in the catalogue are referred to scale “A”. The readings took place in open country with outlet pipe connections (linear diagrams), with pipe connections at out -and inlet side (logarithmic diagrams).
WV = 0 ÷ 35 m3/s
Pt = 0 ÷ 250 Kgf/m2
Medium/Low pressures.
32
33
Engineering data
1.2.- Aluminium impeller1.2.1.- ES suitable motors
1.2.2.- EF suitable motors
Engineering data
34
35
Engineering data
3600/1
12
77
75
73
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 318-316-314/I 4A/AInstalled power 0,25 - 0,37 - 0,55 kW
ELVE ES 318-316-314/I 4A/AInstalled power 0,25 - 0,37 - 0,55 kW
Impeller diameter 315 mm
Engineering data
36
3600/1
80
78
77
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 357-355-354/H 4A/AInstalled power 0,55 - 0,75 - 1,1 kW
ELVE ES 357-355-354/H 4A/AInstalled power 0,55 - 0,75 - 1,1 kW
Impeller diameter 350 mm
37
Engineering data
3600/1
80
78
77
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 408-406-405/G 4A/AInstalled power 0,75 - 1,1 - 1,5 kW
ELVE ES 408-406-405/G 4A/AInstalled power 0,75 - 1,1 - 1,5 kW
Impeller diameter 400 mm
Engineering data
38
86
84
83
3600/1
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 458-456-455/H 4A/AInstalled power 1,5 - 2,2 - 3 kW
ELVE ES 458-456-455/H 4A/AInstalled power 1,5 - 2,2 - 3 kW
Impeller diameter 450 mm
39
Engineering data
87
86
84
3600/1
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 508-507-505/G 4A/AInstalled power 2,2 - 3 - 4 kW
Impeller diameter 500 mm
Engineering data
40
93
91
90
3600/1
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 568-567-566/H 4A/AInstalled power 4 - 5,5 - 7,5 kW
Impeller diameter 560 mm
41
Engineering data
1800/1
55
57
58
4
3
2
1
0
0.1
0.08
0.06
0.04
0.02
0
100
80
60
40
20
0
12
11
10
9
8
7
6
5
4
3
2
1
0
0.750.720.690.660.630.60.570.540.510.480.450.420.390.360.330.3
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 318-316-314/I 4A/AInstalled power 0,12 - 0,12 - 0,12 kW
ELVE ES 318-316-314/I 4A/AInstalled power 0,12 - 0,12 - 0,12 kW
Impeller diameter 315 mm
Engineering data
42
1800/1
60
58
57
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 357-355-354/H 4A/AInstalled power 0,12 - 0,12 - 0,18 kW
ELVE ES 357-355-354/H 4A/AInstalled power 0,12 - 0,12 - 0,18 kW
Impeller diameter 355 mm
43
Engineering data
1800/1
61
59
58
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 408-406-405/G 4A/AInstalled power 0,12 -0,12 -0,18 kW
ELVE ES 408-406-405/G 4A/AInstalled power 0,12 -0,12 -0,18 kW
Impeller diameter 400 mm
Engineering data
44
68
66
65
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 458-456-455/H 4A/AInstalled power 0,25 - 0,37 - 0,55 kW
ELVE ES 458-456-455/H 4A/AInstalled power 0,25 - 0,37 - 0,55 kW
Impeller diameter 450 mm
45
Engineering data
68
67
65
1800/1
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 508-507-505/G 4A/AInstalled power 0,25 - 0,37 - 0,55 kW
ELVE ES 508-507-505/G 4A/AInstalled power 0,25 - 0,37 - 0,55 kW
Impeller diameter 500 mm
46
1800/1
73
71
70
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 568-567-566/H 4A/AInstalled power 0,55 - 0,75 - 1,1 kW
ELVE ES 568-567-566/H 4A/AInstalled power 0,55 - 0,75 - 1,1 kW
Impeller diameter 560 mm
47
Engineering data
ELVE EF 638-636-635/G 4A/AInstalled power 1,1 - 1,5 - 2,2 kW
ELVE ES 638-636-635/G 4A/AInstalled power 1,1 - 1,5 - 2,2 kW
Impeller diameter 630 mm
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
Engineering data
48
82
80
79
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 718-716-715/H 4A/AInstalled power 2,2 - 3 - 4 kW
ELVE ES 718-716-715/H 4A/AInstalled power 2,2 - 3 - 4 kW
Impeller diameter 710 mm
49
Engineering data
83
81
80
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 808-806-805/G 4A/AInstalled power 3 - 4 - 5,5 kW
ELVE ES 808-806-805/G 4A/AInstalled power 3 - 4 - 5,5 kW
Impeller diameter 800 mm
Engineering data
50
90
89
88
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 908-907-906/F 4A/AInstalled power 4 - 5,5 - 7,5 kW
ELVE ES 908-907-906/F 4A/AInstalled power 4 - 5,5 - 7,5 kW
Impeller diameter 900 mm
51
Engineering data
92
90
89
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 907-906-905/I 4A/AInstalled power 7,5 - 11 - 15 kW
ELVE ES 907-906-905/I 4A/AInstalled power 7,5 - 11 - 15 kW
Impeller diameter 900 mm
Engineering data
52
95
93
92
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1008-1006-1005/H 4A/AInstalled power 11 - 15 - 18,5 kW
ELVE ES 1008-1006-1005/H 4A/AInstalled power 11 - 15 - 18,5 kW
Impeller diameter 1000 mm
53
Engineering data
65
63
62
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE ES 638-636-635/G 4A/AInstalled power 0,25 - 0,37 -0,55 kW
Impeller diameter 630 mm
Engineering data
54
71
69
68
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 718-716-715/H 4A/AInstalled power 0,75 - 1,1 - 1,5 kW
ELVE ES 718-716-715/H 4A/AInstalled power 0,75 - 1,1 - 1,5 kW
Impeller diameter 710 mm
55
Engineering data
72
70
69
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 808-806-805/G 4A/AInstalled power 1,1 - 1,5 - 2,2 kW
ELVE ES 808-806-805/G 4A/AInstalled power 1,1 - 1,5 - 2,2 kW
Impeller diameter 800 mm
Engineering data
56
79
78
77
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 908-907-906/F 4A/AInstalled power 1,1 - 1,5 - 2,2 kW
ELVE ES 908-907-906/F 4A/AInstalled power 1,1 - 1,5 - 2,2 kW
Impeller diameter 900 mm
Engineering data
81
79
78
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 907-906-905/I 4A/AInstalled power 2,2 - 3 - 4 kW
ELVE ES 907-906-905/I 4A/AInstalled power 2,2 - 3 - 4 kW
Impeller diameter 900 mm
57
Engineering data
58
80
79
78
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1009-1008-1007/E 4A/AInstalled power 1,5 - 2,2 - 3 kW
ELVE ES 1009-1008-1007/E 4A/AInstalled power 1,5 - 2,2 - 3 kW
Impeller diameter 1000 mm
59
Engineering data
83
81
80
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1008-1006-1005/H 4A/AInstalled power 3 - 4 - 5,5 kW
ELVE ES 1008-1006-1005/H 4A/AInstalled power 3 - 4 - 5,5 kW
Impeller diameter 1000 mm
Engineering data
60
84
83
82
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1128-1126-1125/G 4A/AInstalled power 5,5 - 7,5 -11 kW
ELVE ES 1128-1126-1125/G 4A/AInstalled power 5,5 - 7,5 -11 kW
Impeller diameter 1120 mm
61
Engineering data
86
85
84
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1258-1257-1256/F 4A/AInstalled power 7,5 - 11 - 15 kW
ELVE ES 1258-1257-1256/F 4A/AInstalled power 7,5 - 11 - 15 kW
Impeller diameter 1250 mm
Engineering data
62
65
63
62
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE ES 807-806-805/G 4A/AInstalled power 0,37 - 0,55 -0,75 kW
Impeller diameter 800 mm
63
Engineering data
71
70
69
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE ES 908-907-906/F 4A/AInstalled power 0,55 - 0,75 - 1,1 kW
Impeller diameter 900 mm
Engineering data
64
72
71
70
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE ES 1009-1008-1007/E 4A/AInstalled power 0,75 - 1,1 - 1,5 kW
Impeller diameter 1000 mm
65
Engineering data
76
74
73
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1008-1006-1005/H 4A/AInstalled power 2,2 -2,2 -3 kW
ELVE ES 1008-1006-1005/H 4A/AInstalled power 2,2 -2,2 -3 kW
Impeller diameter 1000 mm
Engineering data
66
76
75
74
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1128-1126-1125/G 4A/AInstalled power 2,2 -3 - 4 kW
ELVE ES 1128-1126-1125/G 4A/AInstalled power 2,2 -3 - 4 kW
Impeller diameter 1120 mm
67
Engineering data
78
77
76
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1258-1257-1256/F 4A/AInstalled power 3 - 4 - 5,5 kW
ELVE ES 1258-1257-1256/F 4A/AInstalled power 3 - 4 - 5,5 kW
Impeller diameter 1250 mm
Engineering data
68
900/1
Pv kW POTENZA ASSORBITA ASSE VENTILATORE RUMOROSITÀ Lp
dB/A
η % RENDIMENTO VELOCITÀ giri / min
Pt kgf/m2 PRESSIONE TOTALE PRESSIONE DINAMICA Pd kgf/m2
PORTATA Qm3/secARIA densità 1.226 Kg/m3
ELVE EF 1409-1408-1407/E 4A/AInstalled power 4 - 5,5 - 7,5 kW
ELVE ES 1409-1408-1407/E 4A/AInstalled power 4 - 5,5 - 7,5 kW
Impeller diameter 1400 mm
IMPELLERS WITH STEEL HUB
The axial fans FERRARI are suitable for large quantities of air at low pressures and run very quiet.
Compared with centrifugal fans the axial fans have the following advantages:• they are cheaper;• the impeller, rotation “RD” if seen from opposite side of inlet, wich has adjustableblades, makes it possible to adapt the fan to the requirements of the plant;• reduced space requirements;• shorter ducts, therefore cheaper.Every impeller has been examined as to UNI 10531 / ISO 5801.All specifications listed in the tables are referred to air at a temperature of 15°C, specific gravity 1.226 Kgf/m3.Noise level values were taken at an average distance of 1,5 m from the fan, the decibels mentioned in the catalogue are referred to scale “A”. The readings took place in open country with outlet pipe connections (linear diagrams), with pipe connections at out - and inlet side (logarithmic diagrams).
WV = 0 ÷ 112 m3/s
Pt = 0 ÷ 400 Kgf/m2
Low, middle and high pressures.
70
71
Engineering data
1.3.- Steel hub impeller1.3.1.- ES suitable motors
Weight J WeightFan Motor Fan Motor
A B C D E F G N° Ø Kg Kg·m2 Kg·m2A B C D E F G N° Ø KgES 908/H 4A 132 MA4 551 663 132 ES 1256/H 4A 180 L6 800 910 310ES 907/H 4A 132 MB4 551 663 137 ES 1255/H 4A 180 L6 800 910 310ES 906/H 4A 160 M4 656 768 195 ES 1254/H 4A 200 LR6 870 980 390ES 907/H 4A 132 SA6 551 663 106 ES 1256/H 4A 160 L8 700 810 280ES 906/H 4A 132 SA6 551 663 106 ES 1255/H 4A 160 L8 700 810 280ES 904/H 4A 132 MA6 551 663 124 ES 1254/H 4A 180 L8 800 910 320ES 1008/K 4A 160 M4 656 768 215 ES 1408/H 4A 200 LR6 890 1070 480ES 1007/K 4A 160 L4 656 768 235 ES 1407/H 4A 200 L6 890 1070 500ES 1006/K 4A 180 M4 740 852 270 ES 1406/H 4A 225 M6 820 1090 550ES 1007/K 4A 132 MA6 551 663 145 ES 1407/H 4A 180 L8 830 1010 415ES 1006/K 4A 132 MB6 551 663 155 ES 1406/H 4A 200 L8 890 1070 500ES 1004/K 4A 160 M6 656 768 295 ES 1404/H 4A 200 L8 890 1070 500ES 1007/K 4A 132 SB8 551 663 136 ES 1607/H 4A 250 M6 1000 1190 670ES 1006/K 4A 132 SB8 551 663 136 ES 1606/H 4A 280 S6 1150 1340 740ES 1004/K 4A 132 MB8 551 663 155 ES 1605/H 4A 280 M6 1150 1340 780ES 1128/H 4A 180 L4 780 910 290 ES 1606/H 4A 225 S8 940 1130 590ES 1127/H 4A 200 L4 850 980 380 ES 1605/H 4A 225 M8 940 1130 610ES 1126/H 4A 200 L4 850 980 380
ES 1257/H 4A 225 S4 890 1000 440ES 1256/H 4A 225 M4 890 1000 460ES 1255/H 4A 250 M4 950 1060 530
ES 1604/H 4A 250 M8 1000 1190 690ES 1127/H 4A 160 M6 680 810 240ES 1126/H 4A 160 L6 680 810 250ES 1124/H 4A 180 L6 780 910 280ES 1127/H 4A 132 MA8 600 730 215
ES 1808/H 4A 280 M6 1170 1370 960
ES 1126/H 4A 160 MR8 680 810 235
ES 1807/H 4A 315 S6 1180 1350 1080
ES 1124/H 4A 160 M8 680 810 240
ES 1806/H 4A 315 M6 1180 1350 1130ES 1807/H 4A 280 S8 1170 1370 960ES 1806/H 4A 280 M8 1170 1370 990ES 1804/H 4A 315 S8 1180 1350 1070
450 24 12 1,77
900 958 1005 1200 450 16 12 1,12
1000
Type
1067 1107
Type
1120 1200 1248 1490 500 24 12 2,75
1250 1337 1380 1670 560 24 12 4
J
6,25
9,75
4
19,3
1340
121540
1380 1670 560 24 12
32
1800 1856 1930 2320 750 32 14
14
1250 1337
1400 1491
32
6301870
1600 1663 20901730 670
Engineering data
72
1.3.2.- EF suitable motors
Weight JWeightFan Motor Fan Motor
A B C D E F G H N Ø Kg Kg·m2
J
Kg·m2 A B C D E F G H N Ø KgEF 908/H 4A 132MA4 152 EF 1257/H 4A 160 L6 320EF 907/H 4A 132MB4 167 EF 1256/H 4A 180 L6 350EF 906/H 4A 160M4 215 EF 1255/H 4A 180 L6 350EF 904/H 4A 160L4 710 990 235 EF 1254/H 4A 200 LR6 430EF 908/H 4A 112M6 111 EF 1257/H 4A 160 M8
1000 1355310
EF 907/H 4A 132SA6 126 EF 1256/H 4A 160 L8 320EF 906/H 4A 132SA6 126 EF 1255/H 4A 160 L8 320EF 904/H 4A 132MA6 144 EF 1254/H 4A 180 L8 360EF 1008/K 4A 160M4 245 EF 1408/H 4A 200 LR6 575EF 1007/K 4A 160L4 265 EF 1407/H 4A 200 L6 595EF 1006/K 4A 180M4 300 EF 1406/H 4A 225 M6 645EF 1004/K 4A 180L4
800 1080
320 EF 1404/H 4A 250 M6 710EF 1008/K 4A 132SA6 166 EF 1408/H 4A 160 L8
1000 1400450
EF 1007/K 4A 132MA6 175 EF 1407/H 4A 180 L8 490EF 1006/K 4A 132MB6 185 EF 1406/H 4A 200 L8 580EF 1004/K 4A 160M6 235 EF 1404/H 4A 200 L8 580EF 1008/K 4A 132SB8 161 EF 1608/H 4A 225 M6 720EF 1007/K 4A 132SB8 166 EF 1607/H 4A 250 M6 785EF 1006/K 4A 132SB8 166 EF 1606/H 4A 280 S6 860EF 1004/K 4A 132MB8 185 EF 1605/H 4A 280 M6 1250 1700 900EF 1128/H 4A 180 L4 330 EF 1607/H 4A 200 L8 650EF 1127/H 4A 200 L4 420 EF 1606/H 4A 225 S8 690EF 1126/H 4A 200 L4 420 EF 1605/H 4A 225 M8 710EF 1124/H 4A 225 S4
900 1215
460 EF 1604/H 4A 250 M8 790EF 1128/H 4A 132 MB6 245 EF 1808/H 4A 280 M6 1140EF 1127/H 4A 160 M6 270 EF 1807/H 4A 315 S6 1260EF 1126/H 4A 160 L6 285 EF 1806/H 4A 315 M6 1310EF 1124/H 4A 180 L6 310 EF 1804/H 4A 315 MA6 1400 1900 1360EF 1128/H 4A 132 SA8 235 EF 1808/H 4A 250 M8 1010EF 1127/H 4A 132 MA8 245 EF 1807/H 4A 280 S8 1100EF 1126/H 4A 160 MR8 270 EF 1806/H 4A 280 M8 1135EF 1124/H 4A 160 M8 275 EF 1804/H 4A 315 S8 1215EF 1258/H 4A 200 L4 1000 1355 460 EF 2007/H 4A 280 M8 1400 2030 1250EF 1257/H 4A 225 S4 1000 1355 500 EF 2006/H 4A 315 S8 1400 2030 1330EF 1256/H 4A 225 M4 1000 1355 520 EF 2005/H 4A 315 M8 1400 2030 1410EF 1255/H 4A 250 M4 1000 1355 590 EF 2004/H 4A 315 MG8 1400 2030 1490
27321320560 142000 2073 2130 2580
500232019301856 19,314321180
1060 32 14 9,751663 1730 2090 450
950 32 12 6,251491 1540 1870 400
850 24 12 41337 1380 1670 355
2,75
Type
1250 1337 1380 1670 355 850 24
1190
Type
900 958 1005 280 600 16 12 1,12
1000 1067 1107 1330 280 670 24 12 1,77
1120
12 4
1200 1248 1490 315 750 24 12
1250
1400
1600
1800
73
Engineering data
89
88
87
86
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 908-907-906-904/H 4A/AInstalled power 7,5 - 9 - 11 - 15 kW
ELVE ES 908-907-906/H 4A/AInstalled power 7,5 - 9 - 11 kW
Impeller diameter 900 mm
Engineering data
74
93
92
91
90
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1008-1007-1006-1004/K 4A/AInstalled power 11 - 15 - 18,5 - 22 kW
ELVE ES 1008-1007-1006/K 4A/AInstalled power 11 - 15 - 18,5 kW
Impeller diameter 1000 mm
75
Engineering data
97
96
95
94
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1128-1127-1126-1124/H 4A/AInstalled power 22 - 30 - 30 - 37 kW
ELVE ES 1128-1127-1126/H 4A/AInstalled power 22 - 30 - 30 kW
Impeller diameter 1120 mm
Engineering data
76
100
99
98
97
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1258-1257-1256-1255/H 4A/AInstalled power 30 - 37 - 45 - 55 kW
ELVE ES 1257-1256-1255/H 4A/AInstalled power 37 - 45 -55 kW
Impeller diameter 1250 mm
77
Engineering data
79
78
77
76
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 908-907-906-904/H 4A/AInstalled power 2,2 - 3 - 3 - 4 kW
ELVE ES 907-906-904/H 4A/AInstalled power 3 - 3 - 4 kW
Impeller diameter 900 mm
Engineering data
78
1200/1
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1008-1007-1006-1004/K 4A/AInstalled power 3 - 4 - 5,5 - 7,5 kW
ELVE ES 1007-1006-1004/K 4A/AInstalled power 4 - 5,5 - 7,5 kW
Impeller diameter 1000 mm
79
Engineering data
1200/1
87
86
85
84
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1128-1127-1126-1124/H 4A/AInstalled power 5,5 - 7,5 - 11 - 15 kW
ELVE ES 1127-1126-1124/H 4A/AInstalled power 7,5 - 11 - 15 kW
Impeller diameter 1120 mm
Engineering data
80
1200/1
91
90
89
88
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1257-1256-1255-1254/H 4A/AInstalled power 11 - 15 - 15 - 18,5 kW
ELVE ES 1256-1255-1254/H 4A/AInstalled power 15 - 15 - 18,5 kW
Impeller diameter 1250 mm
81
Engineering data
1200/1
95
94
93
92
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1408-1407-1406-1404/H 4A/AInstalled power 18,5 - 22 - 30 - 37 kW
ELVE ES 1408-1407-1406/H 4A/AInstalled power 18,5 - 22 - 30 kW
Impeller diameter 1400 mm
Engineering data
82
1200/1
98
97
9695
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1608-1607-1606-1605/H 4A/AInstalled power 30 - 37 - 45 -55 kW
ELVE ES 1607-1606-1605/H 4A/AInstalled power 37 - 45 -55 kW
Impeller diameter 1600 mm
83
Engineering data
1200/1
103
102
101
100
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1808-1807-1806-1804/H 4A/AInstalled power 55 - 75 - 90 - 110 kW
ELVE ES 1808-1807-1806/H 4A/AInstalled power 55 - 75 - 90 kW
Impeller diameter 1800 mm
Engineering data
84
900/1
76
75
74
73
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1008-1007-1006-1004/K 4A/AInstalled power 2,2 - 2,2 - 2,2 - 3 kW
ELVE ES 1007-1006-1004/K 4A/AInstalled power 2,2 - 2,2 - 3 kW
Impeller diameter 1000 mm
85
Engineering data
900/1
80
79
78
77
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1128-1127-1126-1124/H 4A/AInstalled power 2,2 - 3 - 4 - 5,5 kW
ELVE ES 1127-1126-1124/H 4A/AInstalled power 3 - 4 - 5,5 kW
Impeller diameter 1120 mm
Engineering data
86
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1257-1256-1255-1254/H 4A/AInstalled power 5,5 - 7,5 - 7,5 - 11 kW
ELVE ES 1256-1255-1254/H 4A/AInstalled power 7,5 - 7,5 - 11 kW
Impeller diameter 1250 mm
87
Engineering data
900/1
88
87
86
85
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1408-1407-1406-1404/H 4A/AInstalled power 7,5 - 11 - 15 - 15 kW
ELVE ES 1407-1406-1404/H 4A/AInstalled power 11 - 15 -15 kW
Impeller diameter 1400 mm
Engineering data
88
900/1
92
91
90
89
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1607-1606-1605-1604/H 4A/AInstalled power 15 - 18,5 - 22 - 30 kW
ELVE ES 1606-1605-1604/H 4A/AInstalled power 18,5 - 22 - 30 kW
Impeller diameter 1600 mm
89
Engineering data
900/1
96
95
94
93
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 1808-1807-1806-1804/H 4A/AInstalled power 30 - 37 - 45 - 55 kW
ELVE ES 1807-1806-1804/H 4A/AInstalled power 37 - 45 - 55 kW
Impeller diameter 1800 mm
Engineering data
90
900/1
100
99
98
97
Pv kW ABSORBED POWER NOISE PRESSURE LEVEL Lp
dB/A
η % EFFICIENCY OPERATING SPEED giri / min
Pt kgf/m2 TOTAL PRESSURE DYNAMIC PRESSURE Pd kgf/m2
CAPACITYm3/secAIR DENSITY 1.226 Kg/m3
ELVE EF 2007-2006-2005-2004/H 4A/AInstalled power 45 - 55 - 75 -90 kW
Impeller diameter 2000 mm
BELT DRIVEN AXIAL FANS
SERIES
EF - EB
92
93
Engineering data
2.- Belt driven axial fan2.1.- EF and EB available sizes
Belt driven fans EFSIZE Aluminium Hub310 314/I350 354/H400 404/G450 454/H500 504/G560 564/H630 634/G710 714/H800 804/G900 904/I
1000 1004/H1120 1124/G1250 1255/F1400 1406/E160018002000
Available fans with impeller completely in aluminium.
Belt driven fans EBSIZE Aluminium Hub310350 354/H400 404/G450 454/H500 504/G560 564/H630 634/G710 714/H800 804/G900 904/I
1000 1004/H1120 1124/G1250 1255/F1400 1406/E16001800
Available fans with impeller completely in aluminium.
Belt driven fans EFSIZE Steel Hub310350400450500560630710800900 904/H
1000 1004/K1120 1124/H1250 1254/H1400 1404/H1600 1604/H1800 1804/H2000 2004/H
Available fans with impeller with steel hub and aluminium blades.
Belt driven fans EBSIZE Steel Hub310350400450500560630710800900 904/H
1000 1004/K1120 1124/H1250 1254/H1400 1404/H1600 1604/H1800 1804/H
Available fans with impeller with steel hub and aluminium blades.
Engineering data
NOTE:
94
The axial fans FERRARI are suitable for large quantities of air at low pressures and run very quiet.
Compared with centrifugal fans the axial fans have the following advantages:• they are cheaper;• the impeller, rotation “RD” if seen from opposite side of inlet, wich has adjustableblades, makes it possible to adapt the fan to the requirements of the plant;• reduced space requirements;• shorter ducts, therefore cheaper.Every impeller has been examined as to UNI 10531 / ISO 5801.All specifications listed in the tables are referred to air at a temperature of 15°C, specific gravity 1.226 Kgf/m3.Noise level values were taken at an average distance of 1,5 m from the fan, the decibels mentioned in the catalogue are referred to scale “A”. The readings took place in open country with outlet pipe connections (linear diagrams), with pipe connections at out -and inlet side (logarithmic diagrams).
WV = 0 ÷ 35 m3/s
Pt = 0 ÷ 250 Kgf/m2
Medium/Low pressures.
96
Engineering data
97
2.2.- Alluminium impeller2.2.1.- EF suitable motors
98
Engineering data
VENT EF 314/I 9A/APitch angle 28°
Impeller diameter 315 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
99
VENT EF 354/H 9A/APitch angle 27°
Impeller diameter 355 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
100
Engineering data
VENT EF 404/G 9A/APitch angle 27°
Impeller diameter 400 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
101
VENT EF 454/H 9A/APitch angle 28°
Impeller diameter 450 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
102
Engineering data
VENT EF 504/G 9A/APitch angle 27°
Impeller diameter 500 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
103
VENT EF 564/H 9A/APitch angle 27°
Impeller diameter 560 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
104
Engineering data
VENT EF 634/G 9A/APitch angle 27°
Impeller diameter 630 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
105
VENT EF 714/H 9A/APitch angle 28°
Impeller diameter 710 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
106
Engineering data
VENT EF 804/G 9A/APitch angle 27°
Impeller diameter 800 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
107
VENT EF 904/I 9A/APitch angle 28°
Impeller diameter 900 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
108
Engineering data
VENT EF 1004/H 9A/APitch angle 28°
Impeller diameter 1000 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
109
VENT EF 1124/G 9A/APitch angle 27°
Impeller diameter 1120 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
110
Engineering data
VENT EF 1255/F 9A/APitch angle 22°
Impeller diameter 1250 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
111
VENT EF 1406/E 9A/APitch angle 19°
Impeller diameter 1400 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
112
Engineering data
2.2.3.- EB suitable motors
Engineering data
113
VENT EB 354/H 9B/BPitch angle 27°
Impeller diameter 355 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
114
Engineering data
VENT EB 404/G 9B/BPitch angle 27°
Impeller diameter 400 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
115
VENT EB 454/H 9B/BPitch angle 28°
Impeller diameter 450 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
116
Engineering data
VENT EB 504/G 9B/BPitch angle 27°
Impeller diameter 500 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
117
VENT EB 564/H 9B/BPitch angle 27°
Impeller diameter 560 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
118
Engineering data
VENT EB 634/G 9B/BPitch angle 27°
Impeller diameter 630 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
119
VENT EB 714/H 9B/BPitch angle 28°
Impeller diameter 710 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
120
Engineering data
VENT EB 804/G 9B/BPitch angle 27°
Impeller diameter 800 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
121
VENT EB 904/I 9B/BPitch angle 28°
Impeller diameter 900 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
122
Engineering data
VENT EB 1004/H 9B/BPitch angle 28°
Impeller diameter 1000 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
Engineering data
123
VENT EB 1124/G 9B/BPitch angle 278°
Impeller diameter 1120 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
124
Engineering data
VENT EB 1255/F 9B/BPitch angle 22°
Impeller diameter 1250 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
125
VENT EB 1406/E 9B/BPitch angle 19°
Impeller diameter 1400 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
NOTE:
126
IMPELLERS WITH STEEL HUB
The axial fans FERRARI are suitable for large quantities of air at low pressures and run very quiet.
Compared with centrifugal fans the axial fans have the following advantages:• they are cheaper;• the impeller, rotation “RD” if seen from opposite side of inlet, wich has adjustableblades, makes it possible to adapt the fan to the requirements of the plant;• reduced space requirements;• shorter ducts, therefore cheaper.Every impeller has been examined as to UNI 10531 / ISO 5801.All specifications listed in the tables are referred to air at a temperature of 15°C, specific gravity 1.226 Kgf/m3.Noise level values were taken at an average distance of 1,5 m from the fan, the decibels mentioned in the catalogue are referred to scale “A”. The readings took place in open country with outlet pipe connections (linear diagrams), with pipe connections at out - and inlet side (logarithmic diagrams).
WV = 0 ÷ 112 m3/s
Pt = 0 ÷ 400 Kgf/m2
Low, middle and high pressures.
128
Weight
Weight
Fan Motor
Fan Motor
A D F G I N° Ø Kg
A C D E F G H I N° Ø Kg
132 SA6 34
5,57,5111522
81098011201280145016101820
45,57,51115
18,5
8009001010116013001470
770 150
160 L4 1090 416
112 M4 780 160
180 L4 1140 460
132 SA4 825 170
200 L4 1180 550
132 MA4 825 180
160 M6 1180 490
160 M4 875 245
160 L6 1180 509
160 L4 875 265
180 L6 1220 530
180 L4 915 320
200 LA6 1220 525
132 MA6 840 210
200 L4 1270 600
132 SA4 885 220
160 L6 1290 626
132 MA4 885 230
180 L6 1290 668
160 M4 935 295
200 LR6 1330 740
160 L4 975 315
200 L6 1380 760
180 M4 1002 370
225 S4 1400 800
132 MB6 955 279
180 L8 1400 909
160 M6 955 293
180 L6 1440 930
160 M4 1010 320
200 LR6 1490 1020
160 L4 1010 331
225 M6 1510 1090
180 M4 1070 356
250 M6 1590 1150
200 L4 1110 460
200 L8 1550 1030
132 MB6 1040 376
225 S8 1600 1125
160 M6 1090 398
200 L6 1600 1140
160 L6 1090 418
250 M6 1700 1245
Type
HECB
B
750 24 12 3
2
1,2512
EF 1254/H 9A
EF 1404/H 9A
EF 1124/H 9A 1120 1200 1248 1490 900 315 1215
1180 670 24 121330 900 280
900
EF 1004/K 9A 1000 1067 1107
280 600
Type
16958 1005 1190 800EF 904/H 9A 1080
EF 1254/H 9A 1250
kW(1)
inst. fan
(2)
rpm
fan(2)
rpm
5,57,51115
18,5305,57,511
720800900103011801310650730810
kW(1)
inst.1522307,51115
18,5301115
18,52237
1115
18,5303715
18,52237
92010501170580650730840940490550610690790
430480540610690380430480540
1337 1380 1670 1000 355 1355 850 24 12 4,25
EF 1604/H 9A
EF 1804/H 9A
EF 2004/H 9A
1250
1800
1337 1380 1670 1000 355 1355 850 24 12
1400 1491 1540 1870 1000 400 1400 950 32 12
1432
1432
32 14
1060163045011802090173016631600
1856 1930 2320 1400
1400
500 1900 1180
1320--20732000 2130 2580
J
4,25
6,5
10,25
19,5
27,5
(1)
(2)
Kg·m2
J
Kg·m2
129
Engineering data
2.3.- Steel hub impeller2.3.1.- EF suitable motors
2.3.1.1.- Arrangement 9
Engineering data
130
2.3.1.2.- Arrangement 12
131
Engineering data
VENT EF 904/H 9-12A/APitch angle 28°
Impeller diameter 900 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
132
VENT EF 1004/K 9-12A/APitch angle 28°
Impeller diameter 1000 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
133
Engineering data
VENT EF 1124/H 9-12A/APitch angle 28°
Impeller diameter 1120 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
134
VENT EF 1254/H 9-12A/APitch angle 28°
Impeller diameter 1250 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
135
Engineering data
VENT EF 1404/H 9-12A/APitch angle 28°
Impeller diameter 1400 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
136
VENT EF 1604/H 9-12A/APitch angle 28°
Impeller diameter 1600 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
137
Engineering data
VENT EF 1804/H 9-12A/APitch angle 28°
Impeller diameter 1800 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Engineering data
138
VENT EF 2004/H 9-12A/APitch angle 28°
Impeller diameter 2000 mm
rpm
Max allowable speed
Air density 1,226 kg/m3
Type
Fan
EB 904/H 9B
EB 1004/K 9B
EB 1124/H 9B
EB 1254/H 9B
EB 1404/H 9B
EB 1604/H 9B
Motor
132 MA6132 S4132 M4160 M4160 L4
45,57,51115
9801120128014501610
132 MB6132 M4160 M4160 L4180 M4
132 MB6160 M6160 M4160 L4180 M4200 L4
132 MB6160 M6160 L6180 L4200 L4
160 M6160 L6180 L6180 M4200 L4
160 L6180 L6
200 LR6200 L6225 S4
EB 1804/H 9B
180 L8180 L6
200 LR6225 M6250 M6
900
1000
1120
1250
1400
1600
1800
720800900
103011801310
650730810
10501170
580650730840940
490550610690790
430480540610690
9001010116013001470
5,57,51115
18,5
5,57,51115
18,530
5,57,5112230
7,51115
18,530
1115
18,52237
1115
18,53037
958
1067
1200
1337
1491
1663
1856
1005
1107
1248
1380
1540
1730
1930
1190
1340
1490
1670
1870
2090
2320
630
750
750
850
850
950
1060
280
280
315
355
400
450
500
1190
1310
1380
1560
1650
1850
2060
16
24
24
24
32
32
32
12
12
12
12
12
14
14
245255270290310
305320340355430
345355420440475530
495525570585620
545575615635665
685705760785855
900925975
10301090
1,37
2
3
4,25
6,5
10,25
19,5
918957957
10151015
10251025108310831175
113011301185118512451285
12601260131013101350
13601360140014001450
14701470151015601580
15701640168017001780
Weight
kg kg•m2
J
A B C D E F G I N° ØkW
(1)
inst.fan
(2)
rpm
Weight with motor
(1) Installed motor power
(2) Recommended fan RPM.
The above data are unbinding
139
Engineering data
2.3.3.- EB/H suitable motors
Engineering data
140
VENT EB 904/H 9B/BPitch angle 28°
Impeller diameter 900 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
141
Engineering data
VENT EB 1004/K 9B/BPitch angle 28°
Impeller diameter 1000 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
Engineering data
142
VENT EB 1124/H 9B/BPitch angle 28°
Impeller diameter 1120 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
143
Engineering data
VENT EB 1254/H 9B/BPitch angle 28°
Impeller diameter 1250 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
Engineering data
144
VENT EB 1404/H 9B/BPitch angle 28°
Impeller diameter 1400 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
145
Engineering data
VENT EB 1604/H 9B/BPitch angle 28°
Impeller diameter 1600 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
VENT EB 1804/H 9B/BPitch angle 28°
Impeller diameter 1800 mm
Max allowable speed
Air density 1,226 kg/m3
rpm
Engineering data
146
AXIAL FANS
ACCESSORIES
ACCESSORIES1.- Counterflanges............................................................................................................pag. 149
2. - Inlet discharge governor..........................................................................................pag. 150
3. - Air reducing flap.........................................................................................................pag. 151
4. - Damper ........................................................................................................................pag. 152
5. - Throttle valve..............................................................................................................pag. 153
6. - Flexible connection...................................................................................................pag. 154
7. - Filter inlet side............................................................................................................pag. 155
8. - Vibration dampers .....................................................................................................pag. 156
9. - Protection net “RC” ...................................................................................................pag. 158
10. - Protection net “RG” .................................................................................................pag. 159
11. - Inlet nozzle................................................................................................................pag. 160
12. - Square bases .............................................................................................................pag. 161
13. - Supports PD (for EF) ................................................................................................pag. 162
14. - Supports PD (for ES) ................................................................................................pag. 163
15. - Supports PD/V (for vertical assembly) .................................................................pag. 164
149
Accessories
1.- Counterflanges
COUNTER-FLANGEUse: the counter-flanges can be supplied in three executions (see picture). They are welded to pipes and set against the fan flanges to facilitate installation.
CF 250 254 292 324 4 50 8 10 0,98 2,0
CF 280 285 332 365 4 50 8 10 1,26 2,2
CF 315 320 366 400 4 100 160 8 10 1,40 2,5 5
CF 355 360 405 440 4 100 160 8 10 1,56 3 6
CF 400 405 448 485 4 100 160 12 10 1,72 3,5 7
CF 450 455 497 535 5 112 160 12 10 2,40 4 8
CF 500 505 551 585 5 112 160 12 10 2,65 4,5 9
CF 560 566 629 666 5 112 160 12 10 3,76 5,5 11
CF 630 636 698 736 5 112 160 12 10 4,19 6,5 13
CF 710 716 775 816 5 125 180 16 12 4,65 8 16
CF 800 806 861 906 5 125 180 16 12 5,20 9,5 19
CF 900 906 958 1006 5 125 200 16 12 5,82 11,5 23
CF 1000 1007 1067 1107 6 125 200 24 12 7,69 13,5 27
CF 1120 1128 1200 1248 6 140 224 24 12 13,8 18 36
CF 1250 1260 1337 1380 8 140 224 24 12 19,3 22 45
CF 1400 1420 1491 1540 8 140 250 32 14 21,6 25 50
CF 1600 1610 1663 1730 10 140 250 32 14 24,3 32 63
CF 1800 1810 1856 1930 10 160 280 32 14 27,2 40 80
CF 2000 2010 2073 2130 12 160 280 32 14 30,2 50 100
a b c h¹ h² h³ N° Ø Kg¹ Kg² Kg³
TIPO
TYPE
TYP
PESO
WEIGHT
POIDS
GEWICHT
INLET DISCHARGE GOVERNOR: are used to regulate the discharges of the fan while maintaining its efficiency high.
Accessories
150
2.- Inlet discharge governor
DP 315 315 366 400 260 117 280 8 10 26
DP 355 355 405 440 280 117 280 8 10 28
DP 400 400 448 485 303 150 315 12 10 31
DP 450 450 497 535 328 150 315 12 10 34
DP 500 500 551 585 353 177 355 12 10 51
DP 560 560 629 666 383 177 355 12 10 57
DP 630 630 698 736 418 177 355 12 10 61
DP 710 710 775 816 458 167 355 16 12 71
DP 800 800 861 906 504 190 400 16 12 90
DP 900 900 958 1006 554 200 400 16 12 102
DP 1000 1000 1067 1107 604 180 400 24 12 124
DP 1120 1120 1200 1248 664 210 450 24 12 157
DP 1250 1250 1337 1380 730 210 450 24 12 177
DP 1400 1400 1491 1540 805 195 450 32 12 205
DP 1600 1600 1663 1730 905 225 500 32 14 216
DP 1800 1800 1856 1930 1005 240 500 32 14 352
DP 2000 2000 2073 2130 1105 232 500 32 14 425
a b c h¹ h² h³ N° Ø Kg¹
TIPO
TYPE
TYP
PESO
WEIGHT
POIDS
GEWICHT
AIR REDUCING FLAP: has the work of reducing the discharge according to the needs of the plant.
151
Accessories
3.- Air reducing flap
a b a¹ b¹ a² b² c h N° Ø Kg
TIPO
TYPE
TYP
PESO
WEIGHT
POIDS
GEWICHT
SAP 100X71 105 76 139 110 165 136 112 2+2 10 2,6
SAP 112X80 117 85 151 119 177 145 112 2+2 10 2,8
SAP 125X90 131 95 165 129 191 155 100 125 4+2 10 3,1
SAP 140X100 146 105 182 139 216 175 112 140 4+2 12 3,5
SAP 160X112 164 117 200 151 234 187 112 160 4+2 12 4,5
SAP 180X125 183 131 219 165 253 201 112 180 4+2 12 5,5
SAP 200X140 205 146 241 182 275 216 112 224 4+4 12 6,5
SAP 224X160 229 164 265 200 299 234 112 224 4+4 12 7,5
SAP 250X180 256 183 292 219 326 253 112 224 6+4 12 8,5
SAP 280X200 288 205 332 249 368 285 125 224 6+4 12 10
SAP 315X224 322 229 366 273 402 309 125 224 6+4 12 11
SAP 355X250 361 256 405 300 441 336 125 224 6+4 12 14
SAP 400X280 404 288 448 332 484 368 125 224 8+6 12 17
SA 450X315 453 322 497 366 533 402 125 224 8+6 12 21
SA 500X355 507 361 551 405 587 441 125 224 8+6 12 24
SA 560X400 569 404 629 464 669 504 160 224 8+6 14 28
SA 630X450 638 453 698 513 738 553 160 224 8+6 14 32
SA 710X500 715 507 775 567 815 607 160 224 10+6 14 37
SA 800X560 801 569 871 639 921 689 200 224 8+6 14 44
SA 900X630 898 638 968 708 1018 758 200 224 10+8 14 49
SA 1000X710 1007 715 1077 785 1127 835 200 280 10+8 14 60
SA 1120X800 1130 801 1210 881 1270 941 200 280 12+8 18 85
SA 1250X900 1267 898 1347 978 1407 1038 200 280 14+10 18 100
SA 1400X1000 1421 1007 1501 1087 1561 1147 200 280 14+10 18 116
SA 1600X1120 1593 1130 1683 1220 1753 1290 200 280 16+12 22 152
SA 1800X1250 1786 1267 1876 1357 1946 1427 200 315 18+14 22 189
SA 2000X1400 2003 1421 2093 1511 2163 1581 200 315 20+14 22 248
DAMPERUse: the outlet dampers are of square shape and are used against adverse weather conditions. Outlet dampers are usually installed together with propeller fans seriesES, EF and EB. The siats open automatically as the air flows from the fan and close by gravity when the air stops flowing.
Accessories
152
4.- Damper
SG 315 315 338 400 80 160 141 l0 2.6
SG 355 355 374 440 80 160 156 l0 3
SG 400 400 432 485 80 160 117 l0 3.5
SG 450 450 480 535 80 160 130 l0 4
SG 500 500 532 585 90 180 144 l0 4.3
SG 560 560 607 666 90 180 164 l0 7.5
SG 630 630 674 736 100 200 182 l0 8.6
SG 710 710 760 816 100 200 153 12 10.6
SG 800 800 844 906 112 224 170 12 19.2
SG 900 900 939 1006 125 250 188 12 21.7
SG 1000 1000 1058 1107 140 280 142 12 25.5
SG 1120 1120 1190 1246 160 315 160 12 36
SG 1250 1250 1320 1380 180 355 178 12 46
SG 1400 1400 1470 1540 200 400 149 12 56
a b c e f g Ø Kg
TIPO
TYPE
TYP
PESO
WEIGHT
POIDS
GEWICHT
THROTTLE VALVE: Its work is to partially the discarge of the fan.
153
Accessories
5.- Throttle valve
SF 180 180 219 254 16 40 95 180 8 8 6
SF 200 200 241 274 16 40 106 200 8 8 6,3
SF 224 224 265 298 16 40 118 224 8 8 6,7
SF 250 250 292 324 16 40 132 250 8 10 7
SF 280 280 332 365 16 40 148 280 8 10 10
SF 315 315 366 400 16 40 165 315 8 10 11
SF 355 355 405 440 16 40 185 355 8 10 14
SF 400 400 448 485 16 40 208 400 12 10 17
SF 450 450 497 535 20 45 234 450 12 10 21
SF 500 500 551 585 20 45 259 500 12 10 30
SF 560 560 629 666 20 45 289 560 12 10 40
SF 630 630 698 736 20 45 324 630 12 10 49
SF 710 710 775 816 20 45 364 710 16 12 59
SF 800 800 861 906 30 56 413 800 16 12 80
SF 900 900 958 1006 30 56 463 900 16 12 99
SF 1000 1000 1067 1107 30 56 514 1000 24 12 154
SF 1120 1120 1200 1248 30 56 574 1120 24 12 192
SF 1250 1250 1337 1380 30 56 640 1250 24 12 237
a b c d e f h N° Ø Kg
TIPO
TYPE
TYP
PESO
WEIGHT
POIDS
GEWICHT
Accessories
154
6.- Flexible connection
a b c d N° h1 h2 Kg
TIPO
TYPE
TYP
PESO
WEIGHT
POIDS
GEWICHT
VIBRATION - DAMPING COUPLINGSUse: the vibration-damping couplings are used to avoid the transmission of noiose and vibrations to canalization systems.
GA 50 50 84 104 8 4 140 - 0.7
GA 63 62 102 126 8 4 140 - 0.8
GA 80 80 118 143 8 4 140 - 1
GA 100 100 139 163 8 4 140 - 1.3
GA 112 112 151 175 8 4 140 - 1.4
GA 125 126 165 189 8 4 140 140 1.5
GA 140 140 182 215 8 8 140 140 1.6
GA 160 160 200 235 8 8 140 140 1.8
GA 180 172 219 252 8 8 140 160 2
GA 200 196 241 274 8 8 140 160 2.2
GA 224 218 265 298 8 8 140 160 2.5
GA 250 245 292 324 10 8 140 160 2.8
GA 280 277 332 365 10 8 140 160 3
GA 315 313 366 400 10 8 140 160 4.5
GA 355 352 405 440 10 8 140 160 5.5
GA 400 398 448 485 10 12 140 160 6
GA 450 442 497 535 10 12 140 160 6.5
GA 500 496 551 585 10 12 160 180 9.5
GA 560 561 629 666 10 12 160 180 10
GA 630 631 698 736 10 12 160 180 11
GA 710 712 775 816 12 16 160 180 12.5
GA 800 801 861 906 12 16 160 180 17
GA 900 892 958 1006 12 16 160 180 19
GA 1000 1000 1067 1107 12 24 200 200 27
GA 1120 1120 1200 1248 12 24 200 200 32
GA 1250 1250 1337 1380 12 24 200 200 37
GA 1400 1400 1491 1540 12 32 200 200 43
GA 1600 1600 1663 1730 14 32 200 200 48
GA 1800 1800 1856 1930 14 32 200 200 66
GA 2000 2000 2073 2130 14 32 200 200 73
h
NB: THE INDICATED WEIGHTS ARE CORRISPONDING TO FLEXIBLE “TYPE 5”.
155
Accessories
7.- Filter inlet side
AIR FILTER with VILEDON P15/500/S.
a b c d¹ d2 d³ E N° Ø m² m³/s kg
TIPO
TYPE
TYP
WEIGHT
MAX
RECOMMENDED
VOLUME
SUPERFICIES
OF
FILTER
BORES
DF 224 2255 332 344 8 8 0.25 0.82 4
DF 250/180 280 357 344 172 219 252 8 8 0.28 0.92 4.25
DF 280/200 305 382 344 196 241 274 8 8 0.30 0.99 4.3
DF 315/224 330 407 344 218 265 298 8 8 0.33 1.08 4.6
DF 355/250 355 432 396 245 292 324 8 10 0.41 1.35 5.4
DF 400/280 405 482 456 277 332 365 8 10 0.54 1.78 7
DF 450/315 455 540 506 315 366 400 8 10 0.68 2.24 8
DF 500/355 480 563 546 355 405 440 8 10 0.77 2.54 9.1
DF 560/400 580 662 614 400 448 485 12 10 1.06 3.49 11.3
DF 630/450 631 724 692 450 497 535 12 10 1.28 4.22 18.6
DF 710/500 706 799 785 500 551 585 12 10 1.61 5.31 23.8
DF 800/560 756 847 880 560 629 665 30 12 10 1.94 6.40 34.8
DF 900/630 957 1046 980 630 698 736 30 12 10 2.76 9.1 48.5
DF 1000/710 1058 1158 1100 710 775 815 30 16 12 3.38 11.15 71.5
DF 1120/800 1183 1283 1220 800 861 905 30 16 12 4.23 13.95 97.5
DF 1250 1260 1376 1340 30 12 4.98 16.43
140160
140160
182200
215235
9001000
9001000
9581067
10051107
1624
130.5126.5
Accessories
156
8.- Vibration dampers
CALOTTA IN ALLUMINIO | ALUMINIUM HUB | MOYEU EN ALUMINUIM | NABE IN ALUMINIUM
Vent. tipoES es. 4
Ammort.tipo
Vent. tipoEF es. 4
Ammort.tipo
Vent. tipoEF es. 9
Ammort.tipo
Vent. tipoEB es. 9
Ammort.tipo
Vent. tipoEFR es. 4
Ammort.tipo
Qu.n.
315/1 AM20 315/1 AM20 315/1 AM25 355/H AM25 250/M AM20 4355/H AM20 355/H AM20 355/H AM25 400/G AM25 280/P AM20 4400/G AM25 400/G AM20 400/G AM25 450/H AM30 315/M AM20 4450/H AM25 450/H AM25 450/H AM25 500/G AM30 355/P AM20 4500/G AM25 500/G AM25 500/G AM30 560/H AM40 400/M AM25 4560/H AM25 560/H AM30 560/H AM30 630/G AM40 450/P AM25 4630/G AM25 630/G AM25 630/G AM40 710/H AM40 500/M AM30 4630/1 AM25 63011 AM30 710/H AM40 800/G AM50 5601L AM30 4710/H AM30 710/H AM30 800/G AM40 900/1 AM75 630/P AM40 4800/G AM30 800/G AM30 900/1 AM50 1000/H AM75 710/M AM50 4900/F AM30 900/F AM40 1000/H AM50 1120/G AM75 800/L AM50 490011 AM40 900/1 AM40 1120/G AM75 1250/F AZ 39 41000/E AM30 1000/E AM40 1250/F AM75 1400/E AZ 39 41000/H AM40 1000/H AM50 1400/E AM75 41120/G AM75 1120/G AM75 41250/F AM75 1250/F AM75 41400/E AM75 1400/E AM75 4
CALOTTA IN ACCIAIO | STEEL HUB | MOYEU EN ACIER | NABE IN STAHL
Vent. tipoES es. 4
Ammort.tipo
Qu.n.
Vent. tipoEF es. 9
Ammort.tipo
Qu.n.
Vent. tipoEB es. 9
Ammort.tipo
Qu.n.
Vent. tipoEFR es. 4
Ammort.tipo
Qu.n.
900/H AM40 4 900/H AM50 4 900/H AM75 4 560/P AM30 41000/K AM50 4 1000/K AM50 4 1000/K AM75 4 630/Q AM40 41120/H AM75 4 1120/H AM75 4 1120/H AM75 4 710/P AM50 41250/H AM75 4 1250/H AM75 4 1250/H AZ 39 4 800/P AM50 41400/H AZ 39 4 1400/H AZ 39 4 1400/H AZ 39 4 900/P AM75 41600/H AZ 39 4 1600/H AZ 39 4 1600/H AZ 39 4 1000/P AM75 41800/H AZ 51 4 1800/H AZ 51 4 Vent. tipo
EB es. 12Ammort.
tipoQu.n.
1120/P AZ 39 4Vent. tipoEF es. 4
Ammort.tipo
Qu.n.
2000/H AZ 51 4 1250/P AZ 39 4Vent. tipoEF es. 12
Ammort.tipo
Qu.n.
900/H AM75 4 1400/P AZ 51 4900/H AM40 4 1000/K AM75 4 1600/P AZ 51 41000/K AM50 4 900/H AM75 4 1120/H AZ 39 41120/H AM75 4 1000/K AM75 4 1250/H AZ 39 41250/H AM75 4 1120/H AM75 4 1400/H AZ 39 41400/H AZ 39 4 1250/H AZ 39 4 1600/H AZ 51 41600/H AZ 39 4 1400/H AZ 39 41800/H AZ 51 4 1600/H AZ 39 42000/H AZ 51 4
157
Accessories
VIBRATION DAMPERSUse: they are used to avoid the transmission of noise and vibrations. They are of special metal-rubber. Working temperature - 20 °C + 180 °C.
TIPOTYPETYP
Carico x 4 supporti
Load ‘or 4 supports
Charge pour 4 Supports
Tragkraft von 4 Füben
Kg
b h Ø l i
PesoWeightPoids
GewichtKg
AM20 11÷40 20 20 M6 15 5 0,02
AM25 41÷80 25 20 M6 16 5 0,03AM30 81÷140 30 30 M8 20 6 0,05AM40 141÷224 40 30 M8 23 6 0,1AM50 225÷315 50 40 M10 28 7 0,2AM 75 316÷630 75 50 M12 37 10 0,5
TIPOTYPETYP
Carico x 4 supportiLoad ‘or 4 supports
Charge pour 4 SupportsTragkraft von 4 Füben
Kg
PesoWeightPoids
GewichtKg
AZ 39 531÷1250 0,7
TIPOTYPETYP
Carico x 4 supportiLoad ‘or 4 supports
Charge pour 4 SupportsTragkraft von 4 Füben
Kg
PesoWeightPoids
GewichtKg
AZ 51 1251÷2500 1,8
TIPOTYPETYP
Carico x 4 supportiLoad ‘or 4 supports
Charge pour 4 SupportsTragkraft von 4 Füben
Kg
PesoWeightPoids
GewichtKg
AZ 63 2501÷5000 2,5
TIPOTYPETYP
a b c N°
PESOWEIGHTPOIDS
GEWICHTKg
RC 112 86 161 10 4 0,1RC 125 110 185 10 4 0,1RC 140 134 209 10 4 0,1RC 160 134 233 10 4 0,1RC 180 158 233 10 4 0,1RC 200 182 257 10 4 0,2RC 224 206 281 10 4 0,2RC 250 230 329 10 4 0,3RC 280 254 353 10 4 0,3RC 315 302 377 10 4 0,4RC 355 350 425 10 4 0,5RC 400 398 473 10 4 0,6RC 450 449 521 10 12 1,1RC 500 498 569 10 12 1,5RC 560 546 641 10 12 1,8RC 630 619 713 10 12 2,2RC 710 691 809 12 16 4,3RC 800 788 881 12 16 5,1RC 900 885 977 12 16 5,9
RC 1000 982 1097 12 24 7,5RC 1120 1122 1230 12 24 15,3RC 1250 1234 1360 12 24 17,6RC 1400 1402 1520 14 30 22RC 1600 1598 1700 14 30 27RC 1800 1794 1900 14 30 32RC 2000 1990 2110 14 30 38
PROTECTION NETS: On request we supply protection nets having a mesh opening of 12 mm (RC) for an accident prevention object (UNI 10615).
Accessories
158
9.- Protection net “RC”
159
Accessories
10.- Protection net “RG”
TIPOTYPETYP
a b c N° Ø
PESOWEIGHTPOIDS
GEWICHTKg
RG 250 230 329 l0 0.3
RG 280 254 353 l0 0.3
RG 315 302 377 l0 134 0.3
RG 355 350 425 l0 134 0.4
RG 400 398 473 l0 134 0.5
RG 450 446 521 l0 158 0.6
RG 500 494 569 l0 4 158 0.8
RG 560 570 641 l0 4 158 1
RG 630 642 713 l0 4 158 1.3
RG 710 714 809 12 8 182 2.2
RG 800 810 881 12 8 210 2.7
RG 900 908 977 12 8 230 3.2
RG 1000 1004 1097 12 8 230 3.9
RG 1120 1124 1230 12 8 228 8.4
RG 1250 1236 1360 12 8 228 l0
RG 1400 1376 1520 14 8 284 12.5
RG 1600 1572 1697 14 8 284 16
RG 1800 1793 1913 14 8 284 25
RG 2000 1985 2105 14 8 284 32
PROTECTION NETS: On request we supply protection nets having a mesh opening of 12 mm (RG) for an accident prevention object (UNI 10615).
TIPOTYPETYP
a b c d h N° Ø
PESOWEIGHTPOIDS
GEWICHTKg
BA 315 315 366 400 464 160 8 l0 4.2
BA 355 355 405 440 513 170 8 l0 4.7
BA 400 400 448 485 567 180 12 l0 5.7
BA 450 450 497 535 639 190 12 l0 6.8
BA 500 500 551 585 700 200 12 l0 8
BA 560 560 629 666 785 212 12 l0 9.7
BA 630 630 698 736 871 212 12 l0 11.2
BA 710 710 775 816 968 224 16 12 16.3
BA 800 800 861 906 1077 250 16 12 20
BA 900 900 958 1006 1190 280 16 12 25
BA 1000 1000 1067 1107 1330 280 24 12 28.5
BA 1120 1120 1200 1246 1490 315 24 12 43
BA 1250 1250 1337 1380 1670 355 24 12 53
BA 1400 1400 1491 1540 1870 400 32 12 88
BA 1600 1600 1663 1730 2090 450 32 14 110
BA 1800 1800 1856 1930 2320 500 32 14 140
BA 2000 2000 2073 2130 2580 560 32 14 180
INLET NOZZLESUse: they improve the performance of the fan, reducing its noise level. They are normally installed on axial series EF and EB or on suction pipings.
Accessories
160
11.- Inlet nozzle
TIPOTYPETYP
a b Ø c Ø d e N°. 1 N°. 2 Ø
PESOWEIGHTPOIDS
GEWICHTKg
PA 315 474 440 320 366 15 4 8 10 2
PA 355 474 440 360 405 15 4 8 10 1.8
PA 400 590 550 405 448 20 4 12 10 4
PA 450 590 550 455 497 20 4 12 10 3.5
PA 500 710 670 510 551 23 4 12 10 7
PA 560 710 670 570 629 23 4 12 10 6
PA 630 800 750 644 698 25 4 12 10 7.5
PA 710 900 850 720 775 28 4 16 12 11.5
PA 800 950 900 815 861 28 4 16 12 11
PA 900 1080 1020 914 958 33 4 16 12 15
PA 1000 1180 1120 1015 1067 33 4 24 12 17
PA 1120 1340 640 1130 1200 39 8 24 12 31
PA 1250 1480 710 1260 1337 39 8 24 12 36
PA 1400 1650 790 1410 1491 45 8 32 14 56
PA 1600 1850 890 1610 1663 45 8 32 14 67
SQUARE BASESUse: they are used for the installation of propeller fans on to frames or cases.
161
Accessories
12.- Square bases
Accessories
162
13.- Supports PD (for EF)
TIPOTYPETYP
a b c e f h N² ز N¹ ع
PESO*WEIGHTPOIDS
GEWICHTKg
PD 315 315 366 50 250 200 236 2 8.2 2 10 0,8
PD 355 355 405 50 280 225 265 2 8.2 2 10 1,0
PD 400 400 448 50 315 250 300 2 8.2 2 10 1,2
PD 450 450 497 50 355 280 335 2 8.2 2 10 1,8
PD 500 500 551 60 400 315 355 2 8.2 2 10 2,2
PD 560 560 629 60 450 355 400 2 8.2 2 10 2,7
PD 630 630 698 60 500 400 450 2 8.2 2 10 4,1
PD 710 710 775 70 560 450 500 4 10.2 2 12 5,8
PD 800 800 861 70 630 500 560 4 10.2 2 12 7,4
PD 900 900 958 81 710 2x280 600 4 10.2 3 12 8,6
PD 1000 1000 1067 81 800 2x315 670 6 10.2 3 12 10,7
PD 1120 1120 1200 90 900 2x355 750 6 10.2 3 12 15,7
PD 1250 1250 1337 90 1000 2x400 850 6 10.2 3 12 19,6
PD 1400 1400 1491 101 1122 2x450 950 8 10.2 3 14 34,1
PD 1600 1600 1663 101 1252 2x500 1060 8 12.2 3 14 41,2
PD 1800 1800 1856 111 1402 2x560 1180 8 12.2 3 14 57,9
PD 2000 2000 2073 111 1602 2x630 1320 8 12.2 3 14 72,1
NB. * Il peso è riferito al singolo piedino.NB. * The indicated weight is that of one single foot.
NB. * Le poids indique est d’un pied seulement.NB. * Das angegebene Gewicht bezieht sich auf einen einzelnen Fuss.
SUPPORTSUse: the supports are installed on fans to keep the fans stable.
163
aAccessories
14.- Supports PD (for ES)
TIPOTYPETYP
a b c d e f h N¹ ع N² ز SP.
PESO*WEIGHTPOIDS
GEWICHTKg
PD/S 315 315 180 280 40 350 300 250 2+2 8 4 10 25/10 2.4
PD/S 355 355 190 280 40 380 330 265 2+2 8 4 10 25/10 2.3
PD/S 400 400 200 300 45 415 365 300 2+2 8 4 10 30/10 3.5
PD/S 450 450 212 315 50 455 405 335 2+2 8 4 10 30/10 4
PD/S 500 500 224 335 56 520 460 375 2+2 8 4 10 30/10 4.6
PD/S 560 560 250 355 63 570 510 400 2+2 8 4 10 40/10 7.5
PD/S 630 630 280 400 71 620 560 450 2+2 8 4 10 40/10 9
PD/S 710 710 315 450 80 700 630 500 4+4 10 4 12 40/10 11.3
PD/S 800 800 355 500 90 770 700 560 4+4 10 4 12 50/10 17
PD/S 900 900 450 630 112 870 790 610 4+4 10 4 12 50/10 22
PD/S 1000 1000 450 630 112 960 880 680 6+6 10 4 12 50/10 26
PD/S 1120 1120 500 710 125 1080 990 750 8+6 10 4 12 50/10 32
PD/S 1250 1250 560 800 140 1180 1090 850 8+6 10 4 12 50/10 39
PD/S 1400 1400 630 900 160 1320 1220 950 8+8 10 4 14 60/10 65
PD/S 1600 1600 710 1000 180 1450 1350 1060 8+8 12 4 14 60/10 71
PD/S 1800 1800 800 1120 200 1620 1510 1180 8+8 12 4 14 70/10 98
PD/S 2000 2000 900 1250 224 1820 1710 1320 8+6 12 4 16 70/10 121
SUPPORTSUse: the supports are installed on fans to keep the fans stable.
TIPOTYPETYP
a b c e f h N¹ ع N² ز
PDN315 322 366 25 250 200 235 2 8,5 2 10
PDN 355 362 405 25 280 225 260 2 8,5 2 10
PDN 400 407 448 25 315 250 290 2 8,5 2 10
PDN 450 457 497 25 355 280 325 2 8,5 2 10
PDN 500 507 551 30 400 315 355 2 8,5 2 10
PDN 560 568 629 30 450 355 385 2 8,5 2 10
PDN 630 638 698 30 500 400 430 2 8,5 2 10
PDN710 718 775 40 560 450 475 4 10,5 2 12
PDN 800 808 861 40 630 500 515 4 10,5 2 12
PDN 900 910 956 40 710 280x2 575 4 10,5 3 12
PDN 1000 1010 1067 40 800 315x2 630 6 10,5 3 14
PDN 1120 1130 1200 50 900 355x2 710 6 10,5 3 14
PDN 1250 1260 1337 50 1000 400x2 800 6 10,5 3 14
PDN 1400 1415 1491 50 1120 450x2 900 8 10,5 3 14
PDN 1600 1615 1663 50 1250 500x2 1000 8 12,5 3 14
PDN 1800 1815 1856 60 1400 560x2 1120 8 12,5 3 14
PDN 2000 2015 2073 60 1600 630x2 1250 8 12,5 3 14
SUPPORTSUse: the supports are installed on fans to keep the fans stable.
Accessories
164
15.- Supports PD/V (for vertical assembly)
AXIAL FANS
ABOUT FERRARI
166
ABOUT FERRARI 1.- General information
2.- Definitions and categories
3.- Construction characteristics
4.- Safety
5.- Performance, noise emissions and vibrations
6.- Documentation
167
About Ferrari
1.- General information The fans produced by F.lli Ferrari Ventilatori Industriali S.p.A. are designed and constructed for operation in severe conditions in in-dustrial environments. They are the result of over 40 years of experience in the industrial ventilation sector and a sophisticated pro-duction process with constant quality checks. The company uses technologically advanced machinery and systems to achieve thebest possible results in the manufacture of products. Exploiting its vast expertise acquired over the years, the production range cur-rently comprises 24 series of centrifugal ventilators and 12 series of axial ventilators, with rotor diameters from 180 mm to 2000mm, and high levels of component standardization have been perfected, ensuring products of prime quality.All metallic structures are designed by the company, and most are also constructed directly in its own production facility or out-sourced to exclusive suppliers of great experience that have worked with the company for many years. Both centrifugal and axialrotors are manufactured directly with the care, precision and finishing standards that have always distinguished our products. Sheetmetals and all other components received from suppliers are of excellent quality, to guarantee robust and reliable final products sui-table for the purposes they are designed to serve.
2.- Definitions and categoriesFans comply with the definitions and categories indicated by the UNI ISO 13349 standard. The dimensions of suction and deliveryflanges comply with the DIN 24154 – 24158 standards.
3.- Construction characteristicsCentrifugal impellers are made in sheet steel, with hubs in grey or nodular cast iron. The axial impellers of the series constructedentirely in aluminium are produced by die-casting and precision assembly. The axial rotors with steel cap have blades with wing pro-files made from cast aluminium and hubs in pressed sheet steel. Housings are made in flanged or welded sheet metal accordingto their intended use and overall ventilator dimensions. The cooling disks used on ventilators operating at temperatures over 60°Care made from aluminium.Production processes involving welding are carried out by workers qualified in compliance with the ASME standard, and the wel-ding processes comply with the ASME standard.The rotors are balanced to G 6.3 standards in accordance with the procedures indicated by ISO 1940-1. Paintwork is applied in amodern electrophoresis facility on all components of a suitable dimension to pass through the kilns (corresponding in size up to1250 mm). The standard painting process starts with degreasing and a light phosphate coating. After firing at 180°C, the alkyd water-based paint develops a thickness of about 40 mm. Components too large for kilns are finished with two-part vinyl epoxy paint afterthe same surface preparation. In both cases a final coating is obtained that is suitable for all climate conditions, offering good resi-stance to saline mist and resistant to temperatures up to 200°C. The standard colour is RAL 7045.For applications at higher temperatures a double coat of aluminium-based methyl silicone paint is applied, colour RAL 9006.Some products are hot-galvanized in standard versions. The treatment, applied by expert suppliers according to UNI EN ISO1461:1999 standard, gives average coating thicknesses ranging from a minimum of 55 to 85 mm, according to the thickness of steelto be galvanized.In soundproofed and insulated versions, housings have a cavity of 60 mm filled respectively with polyurethane foam or rock wool.In the first case a reduction of noise produced by the ventilator of around 3 dB with respect to standard versions is obtained. In thesecond case the filled cavity must mainly reduce heat flow and with this the external surface temperature, but an efficient sound-proofing effect is also achieved. For ventilators of medium-large dimensions with internal air temperatures of 300°C, external hou-sing surface temperatures can vary from 70 to 120°C. The corresponding values for an internal temperature of 200°C are between50 and 80°C. On request, C-type anti-sparking versions can be supplied, in compliance with the AMCA 99-0401-86 and UNI ISO13349 standards.The materials acquired for construction of the supports of our transmission ventilators are produced by major suppliers. The L10hduration of bearings has been calculated for a minimum of 20,000 hours in compliance with ISO 281/I, as long as all instructionson routine checks and lubrication indicated in product manuals are respected. All supports are supplied complete with a first fillingof lubricants.If belt transmissions are supplied, the service factor used for dimension calculations is minimum 1.5. Standard versions are fitted withV-type transmission belts with SPZ, SPA, SPB and SPC cross-sections. Belts are fitted, tensioned and aligned before shipment.
4.- SafetyFans are normally supplied for D-type installation, with ducting for inlet and outlet. Every product is complete with the shields re-quired to comply with the UNI 10615 (ISO 12499) standard for this installation category. Standard products are suitable for instal-lation with horizontal shaft. For fans acted by frequency converter is needed to know duty cycle. Sudden inversion of way of rotationis forbiden.
5.- Performance, noise emissions, vibrationsThe ventilation performance of products is determined by tests using the installation and calculation specifications indicated by theUNI 10531 standard. Using a tube of suitable dimensions for the ventilator to be tested, different airflow loads are applied by con-necting flanges calibrated at their free end. Pressure is measured in two sections of the test pipe with all the different end flanges.Air characteristics are also measured (temperature, relative humidity, barometric pressure), together with electrical data for themotor (current, voltage, power) and machine rotation speed. The test data collected are used for the calculations that provide the
About Ferrari
168
ventilation characteristics of the product: flow, total and static pressure and yield. These characteristics are represented in the formof pressure-operation diagrams for transmission ventilators and charts (pressure and suction) for ventilators with direct motor drive.The data are based on an air density of 1.226 kg/m3, corresponding to 15°C and zero metres above sea level.Noise emission is measured in a free field at a distance of 1.5 metres from the ventilator and a height of 1 metre above the sup-port surface, with the ventilator ducted only on the suction or delivery side for direct-drive versions, and with ducting on both sidesfor transmission ventilators. In both cases the dimensions and minimum length of the ducts used comply with the requisites of theUNI 10531 standard for ventilation trials. The net declared sound pressure value is the arithmetical mean of seven measurementsmade around the ventilator at the distance indicated earlier, in conditions of maximum ventilation performance. The frequency bandis always measured at a point opposite the ventilator delivery aperture, or laterally with respect to the cross-section of delivery flowfor axial ventilators.Mechanical vibrations are measured on the bearings of the motor or support, in an orthogonal direction to the rotation axis and ona horizontal plane. The values normally obtained represent vibration speed expressed as a root mean square. The criteria of ac-ceptability regarding this parameter are compliant with the indications of the ISO 14694 standard.
6.- DocumentationThe F.lli Ferrari Ventilatori Industriali S.p.A fans can be supplied with the following documents:
Constructor’s Declaration1
Atex EC declaration ofconformity
User manual1
Atex fan user manual1
Transmission data sheet1
Declaration of conformity to the test1
Impeller balancing 1
Painting1
Sparkleproof construction1
Seal Construction1
Declaration of conformity of the materials1
Running test1
Overall drawing
Assembly drawing
All the fans(any issue inall languagesavailables1 )
All the Atexfans
All the fans
All the AtexfansDirect drivenfans excepted
On request
On request
On request
On request2
On request2
On request
On request
On request
On request
This declaration attests the conformity of the product to the attachement II B of the98/37/EC Directive. This is applied to the machinery which aren’t able to meet all thebasic safety requirements as integrated in other machinery (or machinery assembly);it must be also applied to whole machinery which are put on the market incomplete.Who is in charge of the assembly must carry out the lacking safety requirements.
This document attests the conformity of the fan to the 94/9/EC Atex Directive accordingto the CEN EN 1127-1/97, EN 13463-1/01, EN 13463-5/03 standards and to the prEN14986/06.04 draft.
Warnings and instructions for use (to whom it may concern).
Warnings and instructions for Atex fan use (to whom it may concern).
Data sheet resuming the type of trasmission (pulleys, belts or flexible coupling, bearinghousing and bearings)
This declaration attests the conformity of the fan to the aeraulic test of the prototype andis not a result of any mechanical or aeraulic test of the machine subject of declaration..
This declaration attests that the impeller has been balanced according to the ISO1940-1 standard.
This declaration attests that the fan has been painted according to the internal speci-fication no.50016.
It attests that the fan has been constructed according to what specified in the AMCA-STANDARD 99-0401-86 type construction “C”. Currently this is the same as the spe-cification of UNI ISO 13349 DIS.
It attests that the fan has been constructed according to our internal specification no.50343 referring to ISO 13349 standard.
This declaration attests the conformity to the existing related norms of the materials usedin the manufacturing of the fan according the UNI EN 10204 - 2.1 standard .
This declaration attests the control of the electrical and mechanical parameters of the fan.
Normally a no-scale drawing is provided
Normally a no-scale drawing is provided
Note: 1 Currently these documents are available in the following versions: italian, english, french, german and spanish. TheConstructor’s Declaration and user manual contain also danish, finnish, swedish, dutch, portoguese and russian versions. 2 This document is issued only for the fans with the requirements which are the subject of the declaration.Documents sending: by fax, by e-mail or by post.