3709 Blackhawk Rd - Pool HVAC DEC/09/2014/TUE 09:48 AM City of Eagan FAX No. 651-975-5694 P, 001/001
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New Construction Energy Code Compliance Certificate
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�nergy Recorra Veqtilator RV)Cepaeiry in clht5: LOw: High; LOUtion of duct or yystem;
ContJnuous exhaunine fen(:)rated ca ci fn efms:
Loradonoffsns describe: (�12C�,v.e,h�-� oa^�.. Chn's
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TOtal ventlluion(intermittent+conpnpous)r►�e in cftns: /j p "i+�ettl duct
Created by BAM versbn 052009
Oct 21 2014 10: 03RM HP LRSERJET FRX page 1
� F��� Transmittal
Date: 10/21/2014 +� +�
Attn: Crt of Eagan
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Attn: Terry _ ",, -,-
Fax # 651.675.5694 651-777-7620 Phone
651-777-3252 Fax
Total Pages 10 1770 Gervais Ave.
(Including Ma lewood MN 55109
Transmittal Page): p �
Remarks: Following please find heat calcs, drawing, equipment schedule &
permit application for 3709 Blackhawk Rd. Please call for cc#
For job related questions, please call Jordan 612.328.3512
Thank You,
Diane ;
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Office Manager
Perfection Heating & Air
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� 3709 Blackhawk Rd
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� HVAC Load Calculafions
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� Rhvac is an ACCA approved Manual J and Manual D computer program. I
Calculat�ons are pertormed per ACCA Manual J 8th Edition, Version 2, and ACCA Manual D. j
Oct 21 2014 10: 03RM HP LRSERJET FRX page 5
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Project Title: 3709 Blackhawk Rd �
', Project Date: Monday, October 20,2014 j
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� Reference City: Minneapolis, Minnesota i
� Building Orientation: Front door faces North i
� Daily Temperature Range: Mediurn j
Latitude: 44 Degrees
Elevation: 834 ft.
Aititude Factor; 0.9T0 '
; Elevation Sensible Adj. Factor: 1.000 i
: Elevation Total Adj. Factor. 1.000 i
� Elevation Heating Adj. Factor: 1.000 ;
! Elevation Heating Adj. Factor: 1.000 �
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Outdoor Outdoor Outdoor Indoor Indoor Grains
Drv Bulb Wel Bulb Rel.Hum Rel.Hurn Drv Bulb Difference �
Winter: -16 -12.38 100°� n/a 70 n/a i
Summer: 89 73 47% 50% 75 34 j
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; Total Building Supply CFM: 343 CFM P�Square ft.: 0.235 '
' Square ft, of Room Area: 1,456 Square ft. Per Ton: 0 *•
' Volume (ft')of Cond. Space: (htg.) 14,56U
' Based on area of rooms being heated or cooled (whichever govems system)rather than entire floor area,
" Based on area of rooms being cooled. ;
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Total Heating Required Including Ventilatian Air: 25,599 Btuh 25.599 MBH '
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Rhvac is an ACCA approved Manual J and Manual D computer program.
` Calculations are perforrned perACCA Manual J 8th Edition,Version 2, and ACCA Manual D.
� All computed results are estimates as building use and weather may vary.
� Be sure to select a unit that meets bolh sensible and latent loads according to the manufacturer's performance data at j
your design conditions.
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C:\...1—UNTfLD.rhv Monday,October 20, 2014, 10:43 AM
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Oct 21 2014 10: 03RM HP LRSERJET FRX page 6
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MisceJlaneous Report
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! Winter: -16 -12.38 100% n/a 70 n!a �
I Summer: 89 73 47% 50% 75 33.54 �
Duct�t�iii In uts , Y , � � ,��� .,,. , r � � �:.,
.g% {p. ,"<;, �:T�' �:4r�Tft � a*a7.'.`�€�a ��,� ;�s l:� r z.,r ur{ y.. � �.�t =F �;�,� �-
Main Trunk Runouts '
Calculate: Yes Yes
Use Schedule: Yes Yes j
; Roughness Factor: 0.00300 0.01000 �
� Pressur9 Drop: 0.1000 in.wgJ100 ft. 0.1000 in.wgJ100 k. �
Minimum Velocity, 650 ft./min 450 ft./min
; Maximum Velocity: 900 ft./min ?50 ft./min
' Minimum Helght: 0 in. a in.
; Maxirnum Height: 0 in. 0 in.
��S���'.ltii�'Data . � , �< �.f r.,� � ;r� + s` 1 � c 'r �- .,� > .
ix_:�7 e t�,x,°y,�Pr��� ''^�k:.�5. � �x���q�" 3 Mi.....«.�-t�� �:�.`�i�'e�°+�i^��+E.�ik 4.;1.✓�f8S .
Winter Summer I
� Infiltration Specified: 0.450 AC/hr 0.000 AClhr
37 CFM 0 CFM
Infiltration Actual: 0.450 AC/hr 0.000 AC/hr i
` Above Grade Volume: X 4.950 Cu.fi. X 0 Cu.ft. ,
2,228 Cu.FI./hr 0 Cu.ft./hr
X 0.0167 X 0.0167
Total Building Infiltration: 37 CFM 0 CFM
Total Building Ventilation: 0 CFM 0 CFM
---System 1---
� Infiltration &Ventilation Sensible Gain Multiplier. 14.94 = (1.10 X 0.970 X 14.0�Summer Temp. Difference)
Infiltration 8 Ventilation Latent Gairs Multiplier: 22.13 = (0.68 X 0.970 X 33.54 Grains Difference)
Infiltratiun 8 Ventilaiion Sensible Loss Multiplier: 91.78 = ('1,10 X 0.970 X 86,00 Winter Temp. Difference) ,
Winter Infiltration Specified: 0.450 AClhr(37 CFM),Construction:Average
' Summer Infiltration Specified: 0.000 AClhr(0 CFM),Constnaction:Average ;
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C:\...1—UNTTLO.rhv Monday,October 20,2014, 10:43 AM
Oct 21 2014 10: 04RM HP LRSERJET FRX page 7
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_Load Pre�iew Report I
Sys Sys Sys
Net ft' Sen Lat Net Sen �9 C�9 A� Duct I
Scope Ton lTon Area Gain Gain Galn Loss CFM CFM CFM S¢e !
---.—. .---- -- — i
Building 0.00 0 1rt56 0 0 0 25,599 343 0 343 �
System 1 p.00 0 1,456 0 0 0 25,599 '3A3 0 343 8x8 i
Zone 1 1,456 0 0 0 25,599 3d3 0 343 8x8
1-Paol Raom 1�456 U 0 0 25,599 3��3 0 343 3�
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C:\...\-UNTTLO.rhv Monday, October 20,2014, 10:43 AM
Oct 21 2014 10: 04RM HP LRSERJET FRX page 8
� {tFi�ac��ersidantlal8 Ught Commercial HVAC L,oeds ^ s �lh�' �� I��� �
Pe.rfecq�kr Heating and A!C '. � � �a 't s � ,q��;, i
RAaGlewoo�.tv1N 55109 ; .�.�... .b b a rY���< - , > . ., , .� � _
t1�9,
-Sys�er�n 1, Z�ne 1 Summary Lo�ds (�4v�er��� �.o��d f??t�pcedc�re f�rr RQt�rns) �
� ��hE1,�fdflQn� „ `r u'��r�f� � � � x��rz��,�� ��,��(�,a,��J �.
y. � f f7 �� J�Y=�� :;�' 7}'. F "e �f' l$ tkr{'7+,r R �� .
�'1����iptioii". � �,, ��a +��' ��� �5S� �� >.��,C���� ������ '�
! 1 D-cw-o: Glazing-Double pane,operable window,Gear, 175.2 8,588 0 0 0
wood frame, u-value 0.57, SHGC 0.56
15A-10s3oc-8: Wall-Basement,concreie block wall, R-10 1212 7,225 0 0 0 �
foam board to 3', no framing, no interior finish,open
core, B'floor depth
12E-Osw:Wali-Frarne, R-19 insulation in 2 x 6 stud 212.8 1,244 0 0 0 `;
caviry, no board insulation, siding finish,wood studs
16A-38: Roof/Ceiling-Under Attic with insulation on Attic 1456 3,256 0 0 0 I
Floor(also use for Knee Walls and Partition
Ceilings), Unvented Attic, No Radiant Barrier,Any
Roofing Material,Any Roof Color, R-38 insulation '
21 B-28: Floor-Basement, Concreie slab, any thickness,2 1456 1,8T8 0 0 0 i
or more feet below grade, R-3 or higher insulation
installed belaw floor, any Floor cover, shortest side of '
floor slab is 28'wide �
; Subtotals for strucEure: 22,191 0 0 0
I Peopie: 0 0 0 0
� Equipment: 0 0 0
; Lighting: 0 0 0
Ductwork: 0 0 0 0
Infiltration: W inter CFM: 37, Summer CFM: 0 3,408 0 0 0
System 1, Zone 1 Load Totals: 25,599 0 0 0
[ I
heck Figures =< ryife,�} r� ¢ �71�i�`d�h�M� S� nt if�l`�, K v e � L1 r �,t,14f•t'�,d,' 1
F^r��'
; Supply CFM: 343 CFM Per Square ft.: 0.235 '
i Square ft. of Room Area: 1,456 Square ft. Per Ton: 0 *'"
' Volume(ft3)of Cond. Space: (htg:) 14,580
', ` Based on area of rooms being heated or cooled (whichever govems system)rather than entire floor area.
' "Based on area of rooms being cooled.
�r�one.�l,aa�s ;{X,.i.:'R�#t�Y��u,.�axirrr�r�rlkw � :.t '�G,'.� i " - r 5 '4i.�i s�2�; �
� Total Heating Requi�ed: 25,599 Btuh 25.599 MBH
I �KlOte� , `:; � .,: . �:;, ,;:�u,<� x`";���� �:�-}s�_}�. �''4' r'. :` •=� '�..�',��.�: �
Rhvac is an ACCA approved Manual J and Manual D computer program. '
! Calculations are performed per ACCA Manual J Bth Edltlon,Verslon 2, and ACCA Manual D.
! All computed results are es6mates as building use and weather may vary.
Be sure to select a unit that meets both sensible and lalent loads according io the manufacturer's performance data at
your design conditions.
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C:\ ...1--UNTTLO.fiv Monday,October 20, 2014, 10:43 AM
Venmar CES Inc. � HRV up to 2,800 CFM Page 1 of 2
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an,ar�r�ee�t c�s�
HRV (up to 2�V�O CFM) QUICKLINKS
News
HRV600i Parts&Service
Literature
The Venmar CES HRV600i provides a compact solution to your ventilation needs and is suitable for
installation in a ceiling space,mechanical room or suspended from a ceiling.This Heat Recovery Ventilator ' Software
delivers year round comfort by providing sensible heat recovery(with polypropylene or aluminum heat ° "
__ _.._.
exchanger options)between the exhaust and supply air with virtually no cross leakage between the hvo �� �
airstreams.The HRV600i is available with an HM(heat and moisture)exchanger which allows sensible and Sales BroChure
latent heat recovery.The HRV600i is designed to meet specifications established for a variety of light 3 HRV lup to 2.800 cfml
commercial applications.
Airflow 300-750 CFM[142-3541/s] IOMS
+ HRV600i.100i.1200i
Unit Dimensions(L x W x H) 34"x 28"x 25"[864 x 711 x 635 mm] � HRV2000i/e
Download the HRV600i Revit File HRV600i Revit Familv Parameters
� Start-up Forms
� — — - — -���� �" — �`�� � s HRV600i.700i.1200i
HRV700i �t�,, HRV2000i/e
;
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The Venmar CES HRV700i is designed specifically for removing excess humidity out of indoor spaces such R¢vit Filt NoteS
as pools or areas ihat have high levels of corrosive chemicals.Designed for extreme environments,this ; Revit families inGude the
Heat Recovery Ventilator features a fully powder coated cabinet,inside and out,with full floor ABS drain = following:
pans.In addition,fan housings are powder coated and custom designed motors are fully enGosed with � ■ MEP con�edors
stainless steel shafts.Designed with an oversized heat exchanger,the HRV700i is the solution for iight ■ Materials
commercial corrosive or humidity control applications. ■ Shared Parameters
Airflow 300-800 CFM[142-378 I/s] from the Revit Master
Unit Dimensions(L x W x H) 51"x 21"x 3T'[1,295 x 533 x 940 mm] Parameter list
■ Complete manufacturer
Download the HRV700i Revit File HRV700i Revit Familv Parameters metadata
- _. , __ __ . ...v _ _� ___.__� _ _. __ _ _ �� ■ Geometrythatis
HRV1200i constrained to
references
The Venmar CES HRV1200i provides up to 1,200 cfm[566 I/s]of ventilation white recovering a portion of �� " ■ Views that are 2D ready
the energy lost from conventional exhaust systems.This Heat Recovery Ventilator is one of our most cost-
effective models featuring the lowest first cost per cfm.The Heat Recovery Ventilator deiivers year round ; External Links
comfort by providing sensible heat recovery(with polypropylene or aluminum heat exchanger options) � AHRI Applied Directorv of
between the exhaust and supply air with virtually�o cross leakage between the two airstreams.The � Certifed Product
HRVt 200i is available with an HM(heat and moisture)exchanger which allows sensible and latent heat � : Pertormance
recovery.The HRV1200i is designed to meet specifications established for a variety of light commerciai ��� i AHRI Guideline V
applications. i AHRI Guideline W
Airflow 700-1,250 CFM(330-5891/s]
Unit Dimensions(L x W x H) 34'x 4Y'x 25"[864 x 1,041 x 635 mm]
Download the HRV1200i Revit File HRV1200i Revit Familv Parameters
i
-- -- -- --- --- �
HRV2000i/e
_ _, _..._ ___ ������
The Venmar CES HRV2000 generates up to 2,000 cFm[944 Us]of ventilation air at 1-inch w.g.[250 Paj of ' ���
eutemal static pressure.Featuring a powerful set of belt driven blowers,this Heat Recovery Ventilator also .,,,, '
rewvers sensible energy from the exhaust airstream with a plate heat exchanger made of polypropylene or - - , �
aluminum.The HRV2000 is also available with the option of an HM(heat and moisture)plate exchanger for �
applications that require sensible and latent heat recovery.This model features a uni-body frame design,
which allows for thin wall members to provide high structural strength whiie keeping the overall weight to a
minimum.A unique design for HRV rooftop applications featuring no screw hole peneirations into the roof,
provides 100%assurance of a leak-proof cabinet due to standing water.The unique mounting system of
the indoor model lends itself to installations above suspended ceilings or mechanical rooms,making it
suitable for a wide range of applications.This model is available in single or double wall construction,
depending on your needs to meet a demanding IAQ market.
Airtlow 1,200-2,800 CFM[566-1,322 I!s]
Indoor Unit Dimensions(L x W x H) 91"x 49"x 30"[2,311 x 1,245 x 762 mm]
Outdoor Unit Dimensions(L x W x H) 89"x 50"x 36"[2,260 x 1,270 x 914 mm]
Download the HRV2000i Revit File HRV2000i Revit Familv Parameters
Download the HRV2000e Revit File HRV2000e Revit Familv Parameters
http://www.venmarces.com/products/light-commercial-erv-hrv/hrv-up-to-2-800-cfm 10/21/2014
Ultra Gas S3 CT Gas Boiler � Weil-McLain � Product Detail Page 1 of 1
Ultra Gas S3 CT Gas Boiler
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� GAS-FIRED ftE51�ENTIAL
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Ultra Gas S3 CT Gas Boiler
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Advantages
Boiler Intelligence for Every Heating Need
Optimal Efficiency for Multiple Temperatures
Quick System Presets to Match any Application
Seamless Multiple BoilerControl
Features
Gas fired water boilerwith cast aluminum heat exchanger
Venturi mixing body mixes air and gas providing higher e�ciency
Designed to operate in low temperature condensing applications
Outdoor reset and domestic hot water priority standard
Negative regulated gas valve precisely tlelivers gas to the boiler .
U-Control gives you the power for easy set-up and maintenance
Modulates with 5 to 1 tum-down ratio
Variable speed motor matches combustion output to heating needs
High grade stainless steel bumer features quiet operation,high efficiency,and cleaner combustion for low NOx applications
Specifications
Model A.G.A.Input DOE Heating Capacity Net 1=6=R Ratings Min.Vent Size Annual Fuel Utilization Efficiency
(MBH) �MBH) (MBH) (AFUE)
UG-80 80 71 62 2 or 3 in. 93.5%
PVGCPVC
UG- 105 94 81 2 or 3 in. 94.0%
105 PVC/CPVC
UG- 155 139 123 3in.PVClCPVC 94.0%
155
UG- 230 207 183 3 or 4 in. 94.1%
230 PVC/CPVC
UG- 299 � 270 234 4 in.PVC/CPVC 92.5%
299
UG- 399 365` 317 4 in.PVC/CPVC 917%*
399
`Combustion Effciency
Sentinei X100 Water Treatment included with boiler
Click here for more information o�Sentinel products
Downloads
Brochures and Sales Collateral
�Ultre Senes 3-CT Brochure(1.6MB) �Ultra Series 3-CT Submittal Form(67M6) �
�Easy-up Manifold(1.3M8) �Ultra Series 3-CT Suggested Specifications Form(143K8)
Drawings
�Uttra 80-105 Series 3.dwg(12M8) �a.Ultra 80-105 Series 3.pdf(196K6)
�cUltra 155-230 Series 3.dwg(12MB) f�Ultra 155-230 Series 3.pdf(198K6)
�Ultra 299-399 Series 3.dwg(1.1M6) �Ultra 299399 Series 3.pdf(192K6)
iMa.nuals
i�Ultra Series 3-CT Manual Addendum(676KB) �Usefs Manual(1.6M6)
�`Ultra Series 3 Manual Addendum-Venting(3.1 MB) �Ultra Series 3-CT Boiler Manual(8.OMB)
i�Ultra Series 3-CT Boiler Manual-French(5.7M6)
aRe.sources
�+Ultra Series 3 Quick Start Guide(4.1 MB) �Ultra Series 3-CT Quick Reference Guide{5.4M6)
Revit
�Ultra Gas S3 CT BIM-Revit(1.4M8) �
!Wa.rranty Information
1�Ultra Gas Boiler Warranty Registration Card(572K8)�Homeowner Protection Plan(1.1MB)
�Ultra Series 3 Warranty(21 KB)
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Fan coil unit- Wikipedia,the free encyclopedia Page 1 of 5
� Fan coil unit
From Wikipedia, the free encyclopedia
A fan coil unit (FCU) is a simple device consisting of a
heating or cooling coil and fan. It is part of an HVAC system
found in residential, commercial, and industrial buildings.
Typically a fan coil unit is not connected to ductwork, and is
used to control the temperature in the space where it is '�'�I�����u� �
installed, or serve multiple spaces. It is controlled either by a '����
manual on/off switch or by thermostat.
Due to their simplicity, fan coil units are more economical to
install than ducted or central heating systems with air
handling units. However,they can be noisy because the fan is
within the same space. Unit configurations are numerous `�'� �°'�� „�,�
��
including horizontal (ceiling mounted) or vertical (floor ' ��,
mounted).
�,�l��:z��;�`���a\�a�s��;���\��
�
�
Contents
■ 1 Design and operation
■ 2 DC/EC motor powered units
■ 3 Areas of use
■ 4Installation
■ 5 Unit ventilator
■ 6 European market
■ 7 References
■ 8 See also
Design and operation
It should be first appreciated that'Fan Coil Unit' is a generic term that is applied to a range of products.
Also,the term'Fan Coil Unit' will mean different things to users, specifiers and installers in different
countries and regions,particularly in relation to product size and output capability.
A fan coil unit may be concealed or exposed within the room or area that it serves.
An exposed fan coil unit may be wall-mounted, freestanding or ceiling mounted, and will typically
include an appropriate enclosure to protect and conceal the fan coil unit itself, with return air grille and
supply air diffuser set into that enclosure to distribute the air.
http://en.wikipedia.org/wiki/Fan_coil unit 10/27/2014
Fan coil unit- Wikipedia,the free encyclopedia Page 2 of 5
' A concealed fan coil unit will typically be installed within an accessible ceiling void or services zone.
The return air grille and supply air diffuser,typically set flush into the ceiling, will be ducted to and
from the fan coil unit and thus allows a great degree of flexibility for locating the grilles to suit the
ceiling layout and/or the partition layout within a space. It is quite common for the return air not to be
ducted and to use the ceiling void as a return air plenum. �
The coil receives hot or cold water from a central plant, and removes heat from or adds heat to the air
through heat transfer. Traditionally fan coil units can contain their own internal thermostat, or can be
wired to operate with a remote thermostat. However, and as is common in most modern buildings with a
Building Energy Management System(BEMS), the control of the fan coil unit will be by a local digital
controller or outstation(along with associated room temperature sensor and control valve actuators)
linked to the BEMS via a communication network, and therefore adjustable and controllable from a
central point, such as a supervisors head end computer.
Fan coil units circulate hot or cold water through a coil in order to condition a space. The unit gets its
hot or cold water from a central plant, or mechanical room containing equipment for removing heat from
the central building's closed-loop. The equipment used can consist of machines used to remove heat such
as a chiller or a cooling tower and equipment for adding heat to the building's water such as a boiler or a
commercial water heater.
Fan coil units are divided into two types: Two-pipe fan coil units or four-pipe fan coil units. Two-pipe
fan coil units have one (1) supply and one (1)return pipe. The supply pipe supplies either cold or hot
water to the unit depending on the time of year. Four-pipe fan coil units have two (2) supply pipes and
two (2)return pipes. This allows either hot or cold water to enter the unit at any given time. Since it is
often necessary to heat and cool different areas of a building at the same time, due to differences in
internal heat loss or heat gains, the four-pipe fan coil unit is most commonly used.
Fan coil units may be connected to piping networks using various topology designs, such as "direct
return", "reverse return", or "series decoupled". See ASHRAE Handbook "2008 Systems & Equipment",
Chapter 12.
Depending upon the selected chilled water temperatures and the relative humidity of the space, it is
likely that the cooling coil will dehumidify the entering air stream, and as a by product of this process, it
will at times produce a condensate which will need to be carried to drain. The fan coil unit will contain a
purpose designed drip tray with drain connection for this purpose. The simplest means to drain the
condensate from multiple fan coil units will be by a network of pipework laid to falls to a suitable point.
Alternatively a condensate pump may be employed where space for such gravity pipework is limited.
Speed control of the fan motors within a fan coil unit is effectively used to control the heating and
cooling output desired from the unit. Some manufacturers accomplish speed control by adjusting the
taps on an AC transformer supplying the power to the fan motor. Typically this would require
adjustment at the commissioning stage of the building construction process and is therefore set for life.
Other manufacturers provide custom-wound Permanent Split Capacitar(PSC) motors with speed taps in
the windings, set to the desired speed levels for the fan coil unit design. A simple speed selector switch
(Off-High-Medium-Low) is provided for the local room occupant to control the fan speed. Typically this
speed selector switch is integral to the room thermostat, and is set manually or is controlled
automatically by the digital room thermostat. Building Energy Management Systems can be used for
automatic fan speed and temperature control. Fan motors are typically AC Shaded Pole or Permanent
http://en.wikipedia.org/wiki/Fan_coil unit 10/27/2014
Fan coil unit- Wikipedia,the free encyclopedia Page 3 of 5
' Split Capacitor. More recent developments include brushless DC designs with electronic commutation.
While these motors do offer significant energy savings, initial cost and return on investment should be
carefully considered.
DC/EC motor powered units
These motors are sometimes called DC motors, sometimes called EC motors and occasionally EC/DC
motors. DC stands for Direct Current and EC stands for Electronically Commutated.
DC motors allow the speed of the fans within a Fan Coil Unit to be controlled by means of a 0-10 Volt
input'Signal' to the motor/s,the transformers and speed switches associated with AC Fan Coils are not
required. Up to a signal voltage of 2.5 Volts (which may vary with different fan/motor manufacturers)
the fan will be in a stopped condition but as the signal voltage is increased,the fan will seamlessly
increase in speed until the maximum is reached at a signal Voltage of 10 Volts. Fan Coils will generally
operate between approximately 4 Volts and 7.5 Volts because below 4 Volts the air volumes are
ineffective and above 7.5 Volts the Fan Coil is likely to be too noisy for most commercial applications.
The 0-10 Volt signal voltage can be set via a simple potentiometer and left or the 0-10 Volt signal
voltage can be delivered to the fan motors by the terminal controller on each of the Fan Coil Units. The
former is very simple and cheap but the latter opens up the opportunity to continuously alter the fan
speed depending on various external conditions/influences. These conditions/criteria could be the 'real
time' demand for either heating or cooling, occupancy levels, window switches, time clocks or any
number of other inputs from either the unit itself,the Building Management System or both.
The reason that these DC Fan Coil Units are, despite their apparent relative complexity, becoming more
popular is their improved energy efficiency levels compared to their AC motor driven counterparts of
only a few years ago. A straight swap, AC to DC, will reduce electrical consumption by 50%but
applying Demand and Occupancy dependent fan speed control can take the savings to as much as 80%.
In areas of the world where there are legally enforceable energy efficiency requirements for Fan Coils
(such as the UK), DC Fan Coil Units are rapidly becoming the only choice.
Examples of EC/DC Fan Coil Units:
■ Ability Projects [1] (http://www.abilityprojects.com/products)
Areas of use
iiE�',�,��;� �, �� � � \ ������ � Fan coil units are typically used in spaces where economic
� ���°���'�' � installations are preferred such as unoccupied storage rooms,
corridors, loading docks.
In high-rise buildings, fan coils may be stacked, located one above
the other from floor to floor and all interconnected by the same piping
loop.
.��
http://en.wikipedia.org/wiki/Fan coil_unit 10/27/2014
Fan coil unit- Wikipedia,the free encyclopedia Page 4 of 5
` �, y� Fan coil units are an excellent delivery mechanism for hydronic
� ��" ������ chiller boiler systems in large residential and light commercial
�,,
F-
applications. In these applications the fan coil units are mounted in
bathroom ceilings and can be used to provide unlimited comfort
zones - with the ability to turn off unused areas of the structure to
save energy.
��,:;
� ,� Installation
�5����Ite�,4���u 1`����, �I�
�� �� ,��y,„,� , In high-rise residential construction, typically each fan coil unit
requires a rectangular through-penetration in the concrete slab on top
of which it sits. Usually, there are either 2 or 4 pipes made of ABS,
,..,.<� steel or copper that go through the floor. The pipes are usually
'�� � insulated with refrigeration insulation, such as acrylonitrile
`���� butadiene/polyvinyl chloride (AB/PVC)flexible foam(Rubatex or
Armaflex brands) on all pipes or at least the cool lines.
Unit ventilator
A unit ventilator is a fan coil unit that is used mainly in classrooms, hotels, apartments and
condominium applications. A unit ventilator can be a wall mounted or ceiling hung cabinet, and is
designed to use a fan to blow outside air across a coil, thus conditioning and ventilating the space which
it is serving.
European market
The Fan Coil is composed of one quarter of 2-pipe-units and three quarters of 4-pipe-units, and the most
sold products are "with casing" (35%), "without casing" (28%), "cassette° (18%) and "ducted" (16%).�1�
The market by country was split in 2010 as follows:
http://en.wikipedia.org/wiki/Fan coil_unit 10/27/2014
Fan coil unit- Wikipedia,the free encyclopedia Page 5 of 5
.
Countries Sales Volume in units�2� Share
Benelux 33 725 2.6%
Fr� ance 168 028 � 13.2%
;Germany 63 256 5.0%
�Gre����� 33 292 �2.6%
Italy 409 8�0 =32.1%
Poland 32 987 2.6%
Portugal 22 957 1.8%
Russia, Ukraine and CIS countries 87 054 6.8%
Scandinavia and Baltic countries 39 124 3.1%
Spain 91575 7.2%
Turkey 70 682 5.5%
UK and Ireland 69 169 5.4%
Eastern Europe 153 847 12.1%
References
1. ^ Eurovent Market Intelligence https://www.eurovent-marketintelligence.eu/
2. ^ Eurovent Market Intelligence https://www.eurovent-marketintelligence.eu/
See also
■ Thermal insulation Wikimedia Commons has
■ HVAC media related to Fan coil
■ Construction
unit.
■ Intumescent
■ Firestop
Retrieved from "http://en.wikipedia.org/w/index.php?title=Fan coil_unit&oldid=627796326"
Categories: Mechanical engineering � Heating, ventilating, and air conditioning � Fans
■ This page was last modified on 1 October 2014 at 10:10.
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may apply. By using this site,you agree to the Terms of Use and Privacy Policy. Wikipedia� is a
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