15142 (DSF) Compaction Testsetc j
LEIGHTON and ASSOCIATES
July 30, 1986
TO: Kam Construction
724 Eugene Road
Palm Springs, California 92262
ATTENTION: Mr. Leonard Meier
UYrEARS E C E y V�_ ID
SEP Jr 1���QQ
COh7MLiI'l TV DIENELOPME 1T DEPT
GROUND WATER HAZARDOUS WASTES
Project No. 5861325-01
SUBJECT: Report of Compaction Tests, Single Family Residence
53-3*55—Avenida Bermudas, La Quinta, California 92253
33s
As per your authorization, we have performed five compaction tests on the
subject site. The test results and approximate test locations are detailed
in the attached sheets (Plates 1 and 2). The maximum density and optimum
moisture was determined as per ASTM D1557-78. The field density tests
Were performed in accordance with Nuclear Gage method, ASTM D2922-78.
The scope of the work was to perform compaction tests only and not soil
engineering.
Should you have any questions regarding this report, please contact us.
Respectfully submitted,
LEI TON AND SSOCIATES, INC.
Paul R1 Hoersti Brent J. Ing ram RCE 40264
Supervi\sor� Tech ian Senior Engineer/Operations Manager
PH/BJI/bls
Distribution: (3) Addressee
Attachments: Plate 1, Compaction Test Summary,
Plate 2, Sketch
r
74-240 HIGHWAY 111, PALM DESERT, CALIFORNIA 92260 (619) 568-0993 • (800) 253-4567
IRVINE • WESTLAKENENTURA • DIAMOND BAR/WALNUT • SAN BERNARDINO/RIVERSIDE • SAN DIEGO
PALM DESERT 0 SANTA CLARITANALENCIA • CARLSBAD 0 TEMECULA/RANCHO CALIFORNIA
02 6 DAILY FIELD REPORT
No:
Job Nome:V.r ej
Project No.:�
a (O \325 - � 1
Date, 1 29
$!o
Location: L a, o Ni K
Contractor:
Weather:
Day: -jvES
Foreman:
Field Technician: p,\k
Miles:
Hours:
Equipment Working:
Inspection / Testing of
Test
No.
Test
Location
Elevation
or Depth
Soil
Type
Optimum.
Moisture
Field
Moisture
Maximum
Density
FieldRel.
Density
Comp.
i
STE SV, IC,l1
0.6 - \s
A -
\2.8
(o .5
Wo (b
108.3
93
\\2.3
9(A
3
11.0
Wo • a
9
o.G
9.A-
S
f •G
93
Summary of
Operations:
GRk \\Sy13
S\t'\ SPNp GRa\\
Supervisor:
Engineer:
Geologist:
Todoys Yardage:
Yardage to Date:
LEIGHTON and ASSOCIATES
17975 Sky Park Circle, Suite E. Irvine, California 92714
I
Tel: (714) 556-1421 556-1422
IOOA (4.TT)
� Q
o
LEIGHTON and ASSOCIATES
INCORPORATED
co
,.
� Q
o
LEIGHTON and ASSOCIATES
INCORPORATED
o� 2s k LA 7
I D s Z
IZ.$!�'-?
�,c> L- A CC I t'.3 T.A. i:,- rcs.
N y$\11,. ZS -L? X, ZZ 3 3 4
3 3 00
rlJ T A c_ -
VCX 4^11,1 (•"-�
-Z,12SSa
-331ZT
3rV )A
HOURLY AND ANNUAL Form 2R
BUILDING HEAT LOSS RATE (8/81)
Check One: Proposed Oesigny
Standard Design
K�.T-A G-zi, S IL%>f<w fiC11" 7mm r-GtJCj
O Wner project
y 1 A
L� Q v'Foe�� A► C
project location sys em type
fZ
documentation autnor Qdte
Enforcement Agency Use Only
our ding permit numper
CneCKed by
to
SITE INFORMATION
Heating Degree Day (from Appendix) . . . .... ...... .. .. . HDD Z�Z °F• day.-
Outside
ay-Outside Design Temperature (from Appendix) ................. Tow_ °F
Outside January Moen Temperature (from Appendix) ............. T,an of
PROPOSED BUILDING ENVELOPE INFORMATION .r
Gross Floor Ane (from plans) ...... ............ .... ..... Af t1, h2
Grose Will Area (from plans) ................. ... .. .. .. . AW f12
Designed Glazing Area (from plans) ........ . .. .. . .. . . A9 ft2
Basic Glazing Area 06%of Af if low-rise or 40%of A,N if high-rise) . . . . . . .Abp Z-� ft2
HOURLY HEAT LOSS
DESIGN TEMPERATURE DIFFERENCE
For All Assemblies Other Than The Three Below ...70°F - °F •0Th 1 °F
Tow from above
For Insulated Floor Over Vented Unheated Space .......... Line 1 =2 -AThi 2 of
For Uninsulated Floor Over Vented Unheated Space........ Line 2 - eF -AThu 9 °F
For Sla"n Ground Floors ........... 70°F - °F -AThs 4 °F
Tian from above
CONDUCTIVE HEAT LOSS
x x
Average U
Other
Q I M>✓'� (� X U (� L P
Area, ft2 or
of Assembly.
or F2 from
GT hourly heat
Oescriptlon of Assembly
Len th, ft
Graph 4-1
from above loss. q
S I H�— a:t�'� t-4 i'
g -S
1 ' 1 3
:19_ 951 5 3 Btu/hr
Glazing
X
x
Well S T'V Cl._�O - 1 !� 1)�
Cailing/Roof 1 LAS-L'v 0 0 D �
t'x0-1 LA.—
p a x.TV 1-7 x moi_ >, '3 B a 2.
x x
Ia
S '1 1 x x 711 _ I-1-1
Floor
x x
IN
Other
Q I M>✓'� (� X U (� L P
0 Zti y y
Ic�c�SZ
vol •came Subtotal
5 um o e above q to/hr
INFILTRATION ....... 1ft2 x g,J ft x' d 1 e x3 'F a
6 G3 yU
Al from above weignted from Th from
Average Table 3.7 Uns 1
Calling Height
Subtotal
Q i�
L4 Z 1 �I Z
7 to/hr
nea • Ione
^-�
7 LA
DUCT HEAT LOSS (Enter 0 if there are no ducts) ................. 0.15 x Line 7
B ,��
,
TOTAL HOURLY HEAT LOSS, q�
9W��
tu/hr
—Mn -4-7• ins
ANNUAL HEAT LOSS, OL
17-
2.32.
v Q
°F W1 Ll 1 ` '•
�.0 F
A
Z 1 , T 1
Btu/yr
day/yr X Btu/hr X X 24 hr/day
10
HOa
Hourly Heat Loss C from Th from
from above
from Line 9 Tacle 3.6 Une 1
�1f1Ep
Desert Sands Unified School District
Mr BERMUDA DUNES r
RANCHO MIRAGE 82-879 HIGHWAY 111 6 INDIO, CALIFORNIA 92201-5678 • (619) 347-8631
a INDIAN WELLS N
PALM DESERT
J' LA OUINTA
'gyp INDIO N?
e
July 14, 1986
City of La Quinta
Department of Community Development
78-105 Calle Estado
La Quinta, CA 92253
Re: Lot 6, block 215, Tract Santa Carmelita at Vale., La Quinta.
Gentlemen:
The developer of the above referenced lot
has mitigated i-ts impacts on our overcrowde.d schools by payment
of the amount of $628 per unit to be applied to the cost of
district educational faci-li.ties made necessary by such new
development.
Sincerely,
J � 1.
John D. Brooks
Assistant Superintendent
Business Services
JDB/crm
HEAT TRANSFER COEFFICIENT
(: PROPOSED CONSTRUCTION ASSEMBLY
•
li
Sketch of Construction Assembly
WEIGHT: Ib/ft2
Check one:
Wall
Roof
Floor
11
Form 3
List of Construction Components R
,. 8�? � �• S � vc�o . IS
3. J 0 N D %Z AV
4.
5.
6.
7.
13.
Inside Surface Air Film
Outside Surface Air Film
Total Resistance Rt
U•Value 11/Rt) � 1 y� I�
.uly
- .(Da
cooling
hosting
cooling
hosting
IZ.SIP
cooling
hating
cooling
hosting
t HEAT TRANSFER COEFFICIENT
J PROPOSED CONSTRUCTION ASSEMBLY
0
Sketch of Construction Assembly
WEIGHT: Ib/ft2
Check one:
Wall
Roof V
Floor
0
Form 3
List of Construction Components
R
�. TZ00`r ILE
hating
s. , Z S �� �► C4, W 0JI>
,\7
3. 1 t.ISJ1..d �dL3 ( z 'i3)
5.
'
6.
7.
Inside Surface Air Film
Outside Surface Air Film
Total Resistance Rt
LACI 0 �
cooling hating
U -Value OA411 - C) . 1 �4 / Q1'� ,01/A8
cooling
,0289
hating
I
cooling
hating
.z5
,\7
cooling
heating
LACI 0 �
cooling hating
U -Value OA411 - C) . 1 �4 / Q1'� ,01/A8
cooling
,0289
hating
I
J
BUILDING DESIGN AND EQUIPMENT SUMMARY Form 2
project title climate Zone
�.. 4 Q %OYA, C;" ki-t--e-
Z' i'1\. �'AJ ".- , � Lk oG` '6t5
documentation autnor date
page 1 of 2
plan crack/permit numoer
cneCked Dy
Gate
�r-1 C+ 1-1-. Enforcement Agency Use Only
comatiance matnod (prescrlative or oerrormance. aescriae)
BUILDING EHYELcm tJEr;,tia l Description of Item Dimension
Points
Floor I ft,
Total
N 1 a S� (:Zii
Area
�'j
1. Floor: Slab Perimeter, Type 1
.FZ ft
FZ ft
Ty� .8rmd', Type 1 � 1 k"J cC" /�-T C Oil e'>!-
Type 2 CSit" 2'119 OV 1CACP
I e h:
Z Ceiling: Type � i ►.lt v L--A.T 1 O �1
��_
Type 2
ft=
I
- 1 I S v �.. aT� 1�>~)
1 (a 3
3 wall: , ype t
ft=
1-4
Type 2
ft=
51..1 .
4. Glazing: West, Type 1 �
Z.ZZ 33 ft,
%
I +3
Type 2
North, Type 1 S 1 SV41-P- j ->A J M
% ft=
7 Z It �, �� ft.
'
Type 2
East, Type 1 1 � ZAZ 1 ,�tJL
r� ft=
t;� % — fta
I ,
Type 2
South. Type t t w.14 LS. P.L�tJ<�.
% fts
�� •/, Z`T ft=
--
' Type 2
ft=
Skylight. Type 1 Iy n
_SC W
Nq
I
Type 2
_SC ft=
6. Shading Coefficient: West 'Nt F>�2 t_Ass Se �z�-,.+ S
Z •ZL% ,Zsllp Sc
_ 1
North
East
3im o.Z1 4sc
y,,z� 0 S C
71
i
--3
South ,� ,, a
T, (o�, .Z b SC
n
6. Horizontal South Overhang
Z ft
7. Movable Insulation
: ft=
N A
8. infiltration Contro
S:T
9. Thermal Mass:. Type 1
Type 2
ft=
Type 3 _R
FIr PiG h=
Type 4 _.R
HC MC h=
L\
Type 5 _.,Q
`144 MC h=
)
Point Total This Page
1183 — 420 — CEC
284_66 (2/83)
SUMMARY FQCCiI 2
page 2 of 2
llro(ect title climate zone
aroject address
HEATING, VENTILATING, AIR CONDITIONING SYSTEM Points
10. Heating (fill in information on proposed system)'
Central Gas Furnace I %
brand and model number SE
Btu/hr
tteaeingoacity _
Heat Pump LEOQOk 140 ((Q J Z•4 i
Grand and model number ACpp
Btu/hr
beating Capacity at 47 P
Active Solar
type (liquid or air) collector brand and model number solar fraction
ha o
coll•etor area collector orientation collector tilt ratea rated Slope
y •Intercept
Other
d•aCt1b•
11. Cooling (fill in information on proposed system)
Electric Air Conditioner
brand and model number seasonal EER
Btu/hr
cooling Capacity at 95 R
Electric Heat Pump L.�I.ItJOx i�i e� 5� Y 6,i8
C.� IZ-51b EEK
r .•y � � O�
cooling capacity at 9311 F Btu/hr
Other NQ- 12L..F—CTZ-1C Mt&'T% u Ct
• O•acrlD•
12. Mechanical Ventilation AC.H
aescrlp•
DOMESTIC WATER SYSTEM
13. Heating (fill in information on proposed system)
Gas Only A S M F ` H P4�"— y� y0 Gallons
Rana and model number tank size
Heat Pump w/Electric Backup Gallons
brand and model number tank size
Active Solar
collector brana dna moo•► numberateo rated slope solar traction
y • intercept
fta
• backup neater type, brand and model number collector area collector
orientation
Other
describe
Point Total from Page 1
Total Point Score
3483.420 • CEC
Eli".
HP16 SERIES
HEAT PUMP OUTDOOR UNITS
*18,700 to 56,000 Btuh Cooling Capacity
*19,900 to - 61,000 Btuh Heating Capacity
*ARI Standard 240 Certlfed Ratinge
A
"ur.wr 1
• �� Cl11TrRl1gN {I,IR{ ONtr
!lMNU!lO NIIN ,wM111
�' COY{ON�lNli w{11ltlD
Reliability, Economy and Outstanding Efficiency for Year
Round Operation are Featured in Line Of HP16 Series Heat Pumps
The Lennox HP16 series heat pump outdoor units consist of seven models
ranging from 1-1 /2 thru 5 tons. This family of energy efficient outdoor units
have SEER's of up to 9.8 with a cooling capacity range of 18,700 to 56,000
Btuh and COP ratings of up to 3.1 with heating capacities of 19,900 to 61,000
Btuh. A variety of matching up-flo, down-flo and horizontal blower powered
indoor units, with optional supplemental electric heat, provide selective sizing
and installation versatility. For complete data on indoor units see individual
bulletins. Several refrigerant line sets are available in various lerigths, see
line kit table for selection. Line sets are optional and must be ordered extra.
The HP16 cabinet is heavy gauge galvanized steel with a durable baked -on
enamel paint finish. Special paint process protects cabinet against all kinds
19 of weather. Design of cabinet with louvered inlet air panels and horizontal
air discharge protects fan, fan motor, compressor and other internal com-
ponents from the weather. Heavy duty base support channels elevate unit
above mounting surface. Dual outdoor coils provide extra large surface area
for highest heat transfer. Coils are protected by rugged steel guards.
Automatic defrost control system operates only when required. Compressor
crankcase heater and heating -cooling thermostat with emergency heat sub-
base and warning lights are furnished as standard.
Outdoor units are test operated at the factory to insure proper operation
and are shipped ready for installation. Installer has only to locate unit and
make refrigerant line and electrical connections to complete installation.
:'
ENGINEERING DAT<
HEAT PUMPS
MATCHED REMOT
SYSTEMS
Page 11
July 1, 1983
Supersedes 9-1-82
.,i
Typical Applications
W-01
V
k..
: - 3
E-1
3
SELECTOR
*Sound Rating Number in accordance with ARI Standard 270.
1Rated in accordance with ARI Standard 240 and DOE; At 450 cfm (maximum) indoor air volume per ton of cooling capacity.
Cooling Ratings - 95°F outdoor air temperature and 80OF db/67°F wb entering indoor coil air.
High Temperature Heating Ratings - 47°F db/43°F wb outdoor air temperature and 70°F db entering indoor coil air.
Low Temperature Heating Ratings - 17OF db/15°F wb outdoor air temporature and 70°F db entering indoor coil air.
'Heating Seasonal Performance Factor.
*Requires field installed check and Expansion Valve Kit (LB-34792BD). Must be ordered extra.
tARI Standard 240 Ratings
c
Lennox Indoor
Unit Used
Lennox
High
Low
Total Unit Watts
Outdoor Unit
5
✓-
SEER
EER
Cool.
Temp.
Temp.7Coollng
v u
Model No.
Cap.
Htg.
Htg.Btuh/
Btu/
High
Low
E 016
Up -Flo
Down -Flo
Horizont
*ARI Std.
Temp.
HSPF
C.O.P.
Temp.
C.O.P.
3 to
Stuh
Cap.
Cap.Watt
Watt
v
27O SRN (bels
Htg.
Htg.
d
Stuh
Btuh
Phase
3 Phase
p
•
CPR12-26V----
18,700
20,600
11,000
2140
9.30
2030
7.20
2.95
1604
2.00
31%
ICP12-26V
HP16-211V
/E12Q2
/ES12Q2
(7.6)
CPS12-2E
19,100
19,900
11,000
2140
9.40
1955
7.20
3.00
1585
2.00
26%
----
-
/ES120:
CP12.26V
CPR12-26V
22,600
25,000
14,000
2630
9.00
----
2525
7.40
2.90
2060
2.00
24%
1•---
/E12Q2
/ES1202
H P 16-261 V
CPS 12-2E
23,400
25,600
14,500
2650
9.30
----
2475
7.30
3.00
2095
2.05
25%
----
....
(7.8)
/ES120:
CP12-31V
CPR12-31V
24,400
26,000
14,000
2723
9.60
----
2478
7.50
3.10
2004
2.05
18%
--
/E12Q3
/ES12Q3
CP12-31V
28,800
32,000
18,100
3400
9.10
----
3139
7.40
3.00
2599
2.05
22%
----
----
/E1203
CPR12-31V
CPS12-31
29,000
31,800
17,800
3380
9.10
----
3119
7.40
3.00
2579
2.05
22%
----
HP16-311V
/ES12Q3
/ES12(X
18.0)
CP12-41V
30,200
32,200
18,200
3410
9.25
----
3035
7.50
3.10
2650
2.10
22%
----
----
/E12Q3
CPR12-41 V
30,200
32,200
18,100
3445
9.10
----
3070
7.50
3.05
2549
2.05
22%
-
----
/ES12Q4
CPR12-41V
/ES1204
CPS12-41/•
35,200
35,800
19,600
4115
9.10
8.60
3636
7.55
2.90
2928
1.95
23%
HP16-411/
CPR12-46V
/ES120-
(Use SEER)
/E12Q4
HP16-413V
CP12-41V
.
EER) ERI
EE
'
35,200
35,800
19,600
4053
9.30
8.70
3584
7.55
2.95
2875
2.00
23%
----
- -
1e
-
/ E12Q3
CP12-46V
35,000
36,000
19,800
4140
9.00
8.50
3661
7.60
2.90
2953
1.95
23%
----
----
11
/E12Q4
42,000
38,000
21,000
4347
9.00
8.85
4250
6.70
2.60
3180
1.95
21%
----
----
•CH16-51
H P16-461 V
CPR12-46V
CPS12-41/•
(Use SEER)
41,500
42,500
26,000
5048
8.70
8.20
4488
7.60
2.75
3696
2.05
24%
----
HP16-413V
/E12Q4
/ES120•
(Use EER)
CP12-46V
(8.2) -
41,500
42,500
26,200
5093
8.70
8.10
4533
7.60
2.75
3741
2.05
24%
----
•--•
.
-
.
/E1204
HP 16-511 V j
46,500
49,5W j
29,500
5570
9.00
8.35
4363
8.05
3.00
3835
2.30
22%
•CH 16-51
(Use SEER)
CP12-51V
CPR12-51V
HP16-51Wr
45,500
50,000
30,200
5614
8.80
8.10
4939
7.85
2.95
3988
2.20
20%
----
(Use EER)
/E1204
/E1204
46,500
49,500
29,800
5570
9.00
8.30
4872
8.05
3.00
3844
2.30
20%
----
----
CH16-65'
18.2) ��'
HP16-6555,500
59,500
34,400
6789
8.15
8.20
6005
7.40
2.90
4715
2.15
22%
---
----
CH16-65'
(Use SEERL,
CP12-65V
CPR12-65V
HP16.653V
(Use EER)
55,500
62,500
37,600
7177
8.05
7.75
6340
7.50
2.90
5032
2.20
23%
----
18.21
/E1205
/E12Q5
*Sound Rating Number in accordance with ARI Standard 270.
1Rated in accordance with ARI Standard 240 and DOE; At 450 cfm (maximum) indoor air volume per ton of cooling capacity.
Cooling Ratings - 95°F outdoor air temperature and 80OF db/67°F wb entering indoor coil air.
High Temperature Heating Ratings - 47°F db/43°F wb outdoor air temperature and 70°F db entering indoor coil air.
Low Temperature Heating Ratings - 17OF db/15°F wb outdoor air temporature and 70°F db entering indoor coil air.
'Heating Seasonal Performance Factor.
*Requires field installed check and Expansion Valve Kit (LB-34792BD). Must be ordered extra.
REFRIGERANT LINE KITS
!MJ
3.
Outdoor Unit
Model No.
Line Set Length of
Model No. Lines (ft.)
Liquid Line
(o.d. in.)
Vapor Line
(o.d. in.)
HP16-211V
HP16-261V
L 10-26-20 20
3/8
'5/8
L10-26-25 25
L10-26-35 35
L10-26-50 50
HP16-311V
HP16-410V
L10.41-20 20
3/8
3/4
L10-41-30 30
L10-41-40 40
L10-41-50 50
HP16-460V
L 10-65-30 30
3/8
7/8
L10-65-40 40
L10-65-50 50
1
*Not Available ----
----
----
L".1
3
DISCHARGE
0
AIR
SIDE VIEW
INSTALLATION CLEARANCES (inches)
oil
1 1001
A
HPt6 510V
-r
D
HP16 650V
,•
'Field fabricate.
L".1
3
DISCHARGE
0
AIR
SIDE VIEW
INSTALLATION CLEARANCES (inches)
oil
1 1001
A
B
-r
D
E
,•
G
OUTDOOR
HP16.211V, HP16-261V
UNIT
24-1/4
��ol
IUI
15-1/4
lol
I I
CdMPRESSOR
• �-
' CONTROL BOX
NOTE — In multiple installations, maintain a minimum
of 4 ft. between units and position so the >
discharge air from one unit does not enter the
Intake of adjacent unit. '
DIMENSIONS (inches)
DISCHARGE * AIR
I OUTDOOR COIL
A
B
-r
D
E
,•
G
H
HP16.211V, HP16-261V
32-1/8
24-1/4
��ol
IUI
15-1/4
lol
I I
CdMPRESSOR
• �-
' CONTROL BOX
INLET 1 t AIR
PLAN VIEW
�I INLET
rJ AIR
SUCTION LINE
ACCUMULATOR
ELECTRICAL
INLETS
L=Jt1 VAPOR
r—JLl0UINE
�'LINER
D
I I H
3-15/16 3-15/16
FRONT VIEW
G
SIDE VIEW
SUPPORT
CHANNEL
Model No.
A
B
C
D
E
F
G
H
HP16.211V, HP16-261V
32-1/8
24-1/4
29
5
15-1/4
1
2-1/2
25.1/2
HP16-311V
34-1/8
24.1/4
29
5
14-3/4
1
2-1/2
27-1/2
HP16-411 V -413V
H P16-461 V -463V
36-1/8
28-1/4
33
5
16-3/4
1
2-1/2
29-1/2
HP16-511V-513V
40
30-1/4
35
27.1/2
1.5/8
1-1/2
1-3/4
33-3/8
HP16 651V 653V
1 30 1/4
Sri
1 27 112
t �!P
1 114
1.1/2
33-3!8
SPECIFICATIONS
Model No.
HP76-211V
HP16-261V
HP16-311V
H P16 -411V
HP16-461V
HP16-463V
HP16-511V
HP16-513V
HP16.651VHP16-413V
HP16-653V
Outdoor
Coil
Net face area (sq. ft.1
6.67
6.67
8.00
10.11
10.11
12.9
12.9
Tube diam. (in.) 3/8 3/8 3/8 3/8 3/8 3/8
3/8
No. of rows 3 3 3 3 3 3
4
Fins per inch 15 15 15 15 15 15
15
Outdoor
Fan
Diameter (in.)
18
20
20
22
24
24
24
No. of blades 4 4 4 4 4 4
4
Motor hp 1/10 1/5 1/5 1/4 1/3 1/3
1/3
Cfm (factory setting) 1750 2400 2900 3100 3800 3600
3800
Rpm ffactory setting) 1085 1115 1040 830 830 840
810
15.7 1
Watts (factory setting)
135
205
305
285
395
370
425
Refrigerant -22 (charge furnished)
7 lbs. 14 oz.
8 lbs. 7 oz.
9 lbs. 4 oz.
11 lbs. 0 oz.
12 lbs. 4 oz.
14 lbs. 4 oz.
19 lbs. 8 oz.
Liquid line connection (sweat)
3/8
3/8
3/8
3/8
3/8
3/8
1/2
Vapor line connection (sweat)
5/8
5/8
3/4
3/4
7/8
7/8
1-1/8
Shipping weight (lbs.)
245
250
275
322
333
403
411
Number of packages
II 1
1 1
1
1
1
1
1
ELECTRICAL DATA
Model Number
HP16.211V
HP16-261V
HP16-311V
HP16-411V
HP16-413V
Line voltage data
208/230V
60hz/lph.
208/230V
60hz/1ph.
208/230V
60hz/lph.
208/230V
60hz/lph.
208/230V
60hz/3ph
Compressor
Rated load amps
9.7
11.5
14.7
17.9
12.5
Power factor .95 .96 .95 .94
.89
Locked rotor amps 1 48.0 54.0 65.0 83.5
66.0
Outdoor Coil
Fan Motor
Full load amps
0.70
1.3
1.5
2.0
2.0
I Locked rotor amps 1.0 3.5 3.5 4.0
4.0
Rec.maximum fuse or circuit breaker size (amps)
20 1
25 1
30
1 40 1
30
'Minimum circuit ampacity
12.8 1
15.7 1
19.8 1
24.4 1
17.6
'Refer to National Electrical Code manual to determine wire, fuse and disconnect size requirements.
NOTE - Extremes of operating range are plus 10% and minus 5% of line voltage.
ELECTRICAL DATA
Model Number
HP16-461V
HP16-463V
HP16-511V
HP16-513V
HP16-651V
HP16-653V
Line voltage data
208/230V
60hz/lph.
208/230V
60hz/3ph
208/230V
60hz/lph
208/230V
60hz/3ph
208/230V
60hz/lph
208/230V
60hz/3ph
Compressor
Rated load amps
21.5
13.7
25.6
15.9
28.0
19.0
Power factor 1 .96 .88 .96 .90 .97
.90
Locked rotor amps 95.4 82.0 116.0 92.0 142.0
107.0
Outdoor Coil
Fan Motor
Full load amps
2.5
2.5
2.5
2.5
2.5
2.5
Locked rotor amps 5.5 5.5 5.5 5.5 5.5
5.5
Rec.maximum fuse or circuit breaker size lamps)
50 1
30 1
60
1 35 1
60
1 45
'Minimum circuit ampacily
29.4 1
19.6 1
34.5
1 22.4 1
37.5
1 26.3
*Refer to National Electrical Code manual to determine wire, fuse and disconnect size requirements.
NOTE - Extremes of operating range are plus 10% and minus 5% of line voltage.
FIELD WIRING
------ ------ Et----------
LENNOX
SCONNECT'
(DISCONNECT r LENNOX
A -Two or Three wire power (see Electrical Table)
THERMOSTAT
,
i SWITCH i
I SWITCH Om&" OPTIONAL
(furnl&had)
:(BY OTHERS) ,'
I (BY OTHERS), AUXILIARY I
B - Two or Three wire power (size to heater capacity)
•--
-.-J
a-------- ELECTRIC I
; HEATER UNIT I
C - Two wire power (size to indoor coil blower motor)
E
A
r--------
I OPTIONAL a
J
D -Two wire low voltage (18 ga. minimum)
OUTDOOR
r THERMOSTAT I F
E - Eight wire low voltage (18 ga. minimum) with Electric Heat
- Ten wire low voltage with Optional Outdoor Thermostat
OUTDOOR
UNIT
r------�
)DISCONNECT I
SWITCH
�(BY OTHERS))
L ------J
F - Four wire low voltage (18 ga. minimum)
G - Three Wire low voltage (18 ga. minimum)
LENNOX
INDOOR UNIT - field wiring not furnished -
NOTE - All wiring to conform to NEC and local electrical codes.
14
3-7
RATINGS
NOTE- To determine Sensible Cepaciry, Leaving Wet Bulb and Dry Bulb temperatures not shown
in the cooling table see Miscellaneous Engineering Data section, Page 9.
HP16-511V-513V COOLING CAPACITY WITH CH16-65V INDOOR COIL UNIT
NOTE - All values are gross capacities and do not include indoor coil blower motor heat deduction.
HP16-511V-513V HEATING CAPACITY
Indoor
Unit
Model
No.
Indoor Coil
Air Volume
(cfm)
70F db
Outdoor Air Temperature
Entering Outdoor Coil 1°F)
85
95
105
115
Enter.
Total
Wet
Air
Sensible
Total Comp.
Sensible
Total Comp.
Sensible
Total Comp.
Sensible
Total Comp.
Bulb
Vol.
Cool Motor To Total
Cool Motor To Total
Cool Motor To Total
Cool Motor To T(S/'
1800
1 63,600 1
Ratio
Ratio
Ratio
Ratio IS/
(°F)
Icfm)
Ca Watts
Cap. D Bulb (°F)
lb (O
Ca Watts
lb (O
p' D Bulb (OF)
Ca Watts
lb (O
p' Dr Bulb (OF)
Ce Watts
p' Dry Bulb
2555
13,900 1900
(Btuh) Input
(Btuh) Input
(Btuh) Input
IBtuh) Input
2750
28,800
76 80 1 84
76 80 1 84
76 80 84
76 80
2565
1600
147,700
1 4060
.79 .92 1.00
45,000
1 4400 .82 .95 1.00
142,300
4700 1 .84 .98 1.00
39,500
4980
1 .88 1.00 1
63
1800
48,700
4100
.83 .96 1.00
46,200
4430 .85 .99 1.00
43,300
4760 .88 1.00 1.00
40,800
5050
.92 1.00 1
2000
49,500
4130
.86 1.00 1.00
47,000
4480 .89 1.00 1.00
44,500
4810 .92 1.00 1.00
41,800
5110
.96-1 1.00 1
1600
50,900
4170
.62 .74 .85
47,900
4520 .63 .76 .88
44,900
4830 .65 .78 .91
41,800
5110
.67 .81
67
1800
51,700
4200
.64 .77 .90
48,700
4550 .66 .79 .93
45,600
4870 .68 .82 .96
42,400
5140
.70 .86 1
2000
152,400
4220
.66 .80 .94
149,300
4570 .68 .83 .97
46,200
4890 .70 .86 1.00
42,900
5170
.73 .90 1
1600
54,400
4290
.46 .57 .68
151,300 1
4650 1 .47 .59 .70
48,000
4980 .47 .60 .73
144,700 1
5260
.48 .62
71
1800
55,200
4320
.47 .59 .72
52,000
46.80 1 .48 .61 .74
48,600
5010 .49 .63 .76
45,200 1
5290
.50 .65
2000
55,900
4340
.48 .61 .75
52,600 1
4700 1 .49 1 .63 1 .77
49,100 1
5030 1 .50 .65 .80
145,600 1
5320
.51 .67
NOTE - All values are gross capacities and do not include indoor coil blower motor heat deduction.
HP16-511V-513V HEATING CAPACITY
Indoor
Unit
Model
No.
Indoor Coil
Air Volume
(cfm)
70F db
Air Temperature Entering Outdoor Coil (°F)
65
45
25 11
5
-15
Total
Heating
Capacity
(Btuh)
Comp.'
Motor
Watts
Input
Total Comp.
Heating Motor
Capacity Watts
(Btuh) Input
Total Comp.
Heating Motor
Capacity Watts
(Btuh) Input
Total Comp.
Heating Motor
Capacity Watts
(Btuh) Input
Total Comp
Heating Moto
Capacity Watt.
(Btuh) In u•
CH16-65V
1600
62,600
4720
1 47,600 3830 11
33,400 3050
24,100 2580 11
13,500 1920
1800
1 63,600 1
4605
48,200 1 3760
33,800 1 3035
24,400 2565
13,700 1910
2000 11
64,500 1
4505
48,700 1 3705
34,300 1 3025 124,800
2555
13,900 1900
NOTE - Heating capacities include the effect of defrost cycles in the temperature range where they occur.
J
HP16-511V-513V HEATING PERFORMANCE
at 1800 cfm Indoor Coil Air Volume (CH16-65V)
*Outdoor
Temperature
IDe ree F)
Compressor
Motor Watts
Input
Total
Output
IBtuh)
65
4605
63,600
60
4390
59,900
55
4185
56,200
50
3970
52,200
47
3850
49,900
45
3760
48,200
40
3550
44,200
35
3355
40,100
30
3160
36,100
25
3035
33,800
20
2910
31,400
17
2830
30,000
15
2750
28,800
10
2690
26,800
5
2565
24,400
0
2435
22,100
-5
2275
19,500
-10
2095
16,700
-15
1910
13,700
-20
1805
10,500
'Outdoor lempommin at 70% rulaliva hm,m(li1v Indoor temperature at 701.
E,
31.
4.
f
E12 SERIES SPECIFICATIONS
Model No.
E12Q2.05
E12Q2-10
E12Q2-15
E1203-05
E12Q3-10
E1203-15
E12Q3-20
E1204-10
E12Q4-15
P E12Q4-20
E12.Q4-25
E1205-15
E12Q5-20
E1205-25
E12Q5-30
Blower wheel nominal diam. x width lin.)
9 x 7
10 x 8
10 x 8
12 x 12
Blower motor hp
1 1/4
1/3
1/2
3/4
Up -Flo
Models Only
Net free filter area (sq. ft.)
1 5.3
6.3
7.8
8.7
I Filter cut size (in.) 30 x 26 x 1 40 x 26 x 1 44 x 26 x 1
50 x 26 x 1
Tons of cooling that can be added
1-1/2 or 3
2-1/2 or 3
3, 3-V2 or 4
4 or 5
Shipping weight (lbs.)
121
127
160
192
Number of packages in shipment
1
1
1
1
Electrical characteristics
E1205-20
208-240v/60hz/1 phase
100°x6
tOptional Return Air
Cabinet (Up -Flo only)
Model No.
100%
RA10-16-49
RA10-16-53
100%
Shipping weight (lbs.) 54 56
tOptional Additive Coils Horizontal
tOptional Additive Coils
Model No.
Up -Flo
CP12-26V
CP12-31V, CP12-41V
CP12-46V, CP12.51V
CP12-65V
Down -Flo ---- CPR12 46V, CPR12-51V
CPR12-65V
tDown-Flo Additive Base (Optional)
----
----
LB -346956C
LB -346958D
tFilter Kit (Optional) Down -Flo Models Only
----
----
"LB-51349CA
tMust be ordered extra.
•2 kits are required for down-flo applications.
E12 SERIES' ELECTRIC HEAT RATINGS
Model Number
tOutput Btuh
tA.F.U.E.
E12Q2-05
16,000
100%
E12Q2-10
31,000
100%
E12Q2-15
45,000
100%
E1203-05
16,000
100%
E12123-10
31,000
100%
E1203-15
46,000
100%
E1203-20
61,000
100%
E12Q4-10
31,000
100%
E1204-15
46,000
100%
E1204-20
61,000
100%
E1204-25
75.000 1
100%
E1205-15
46.000
100%
E1205-20
62.000
100°x6
E1205.25
75,000
100%
E1205.30
91,000
100%
tAnnual Fuel Utilization Efficiency based on DOE test procedures and according to
FTC labeling regulations.
ES12 SERIES SPECIFICATIONS
0
tMust be ordered extra.
ES12 SERIES ELECTRIC HEAT RATINGS
Model Number
tOutput Btuh
ES12Q3-05
ES12Q4-05
15,000
98.8%
ES12Q2-05
ES12Q3-10
ES12Q4-10
ES12Q5-15
Model No.
ES12Q2-10
ES12Q3-15
ES12Q4-15
ES12Q5.20
ES1203-10
ES12Q2-15
ES12Q3-20
�-ES12Q4-20
45.000'
Blower wheel nominal diam. x width (in.)
9 x 7
9 x 7
10 x 8
12 x 9
Blower motor hp
1/4
1/3
1 1/3
3/4
Tons of cooling that can be added
1-1/2 or 3
2-1/2
3 or 3-1/2
4 or 5
Shipping weight (lbs.)
121
131
140
1
116
Number of packages in shipment
1
1
1
1
Electrical characteristics
208-240v/60hz/1 phase
tOptional Additive Coils Horizontal
CPS12-26V
CPS12-31V
CPS12-41/46V
CH16-51FF or CH16-65V
Model No. Down -Flo
CPR12-26V
CPR12-31V
CPR12-41V
iDown-Flo Additive Base (Optional)
LB -346958A
I LB -3469588
L8-3469588
tFilter Kit (Optional)
LB-51349CA
tMust be ordered extra.
ES12 SERIES ELECTRIC HEAT RATINGS
Model Number
tOutput Btuh
tA.F.U.E.
ES12Q2-05
15,000
98.8%
ES12Q2-10
30,000
98.8%
ES12Q2-15
47,000
98.8%
ES1203-05
16,000
99.0%
ES1203-10
31,000
99.0%
ES12Q3-15
45.000'
99.0%
ES1203-20
63.000
99.0%
ES1204-05 1
16,000
99.0%
ES12Q4-10
31.000
99.0%
ES1204-15
46,000
99.0%
ES1204-20
64,000
99.0%
ES1205-15
46,000 1.
99.3%
ES12Q5-20
65,000 1
99.3%
tAnnual Fuel Utilization Efficiency based on DOE test procedures and according to
FTC labeling regulations.
_13_
LA9ffffffX6 E12 & ES12 SERIES ELECTRIC FURNACES
UP-FLO — DOWN-FLO — HORIZONTAL
31 13,000 to 102,400 Btuh Electric Heating Capacity
Add -On Cooling — 1-1/2 thru 5 Nominal Tons
ES12 MODEL — DOWN-FLO
WITH FIELD INSTALLED CPR12 COIL
1 __=_^
ES12 MODEL — HORIZONTAL
WITH FIELD INSTALLED CPS12 COIL
ENGINEERING DAT!
HEATING UNIT:
ELECTRIC
Page 11'
July 1, 1983
Supersedes 9.1-82
E12 MODEL — UP-FLO
WITH FIELD INSTALLED CP12 COIL
Multi -Position Line Of Electric Furnaces Provide High Efficiency Performance And Installation Flexibility
The Lennox E12 and ES12 electric furnaces are designed for multi -position
installation in a basement, utility room, alcove, closet, crawispace or
attic. Versatile units are applicable to heating only, heating -cooling or heat
pump applications. Several models are available in varying sizes with a wide
range of heating and cooling capacities. E12Q2 and E1203 models are for
up-flo applications only. The E12Q4 and E12Q5 series models are applicable
to either up-flo or down-flo installation. The ES 12Q2, ES 1203 and ES 1204
series can be installed in the horizontal or down-flo position and the ES12Q5
models in the horizontal only. ,
The optional field additive "slide -in" coil installs internal to the cabinet (up
stream from the blower and electric heat elements) and is specially
matched to the unit for efficient air delivery and maximum capacity. For
up-flo applications optional return air cabinets are available for installation
on either side of the unit.
The cabinets are trim and attractive appearing with a durable electro -bonded
paint finish. Removable front panels provide complete service access to
Down -Flo Installation
cabinet interior. Variable speed direct drive blowers have sufficient capacity
to handle cooling air volume requirements. Hammock style fiberglass air.
filters are furnished on E12 up-flo models only. Nichrome heating elements
give long service life and efficient heating operation. Factory installed cir-
cuit breakers are accessible external to the cabinet. Optional accessories
available include thermostat, return air cabinets, down-flo additive base,
outdoor thermostat and filter kits.
Units have been tested and rated according to Department of Energy (DOE)
test procedures and Federal Trade Commission (FTC) labeling regulations
in the Lennox Research Laboratory. Furnaces are U.L. listed. In addition,
units and components within are bonded for grounding to meet safety
standards for servicing required by UL and NEC. Blower performance data
is from unit tests conducted in the Lennox Laboratory air test chamber.
Each unit is test operated at the factory and shipped assembled (except
for the DX coil) with all controls mounted and prewired. The installer has
only to make the necessary field duct and electrical connections.
Typical Applications
Horizontal Installation
With Electronic Air Cleaner
And Humidifier
NOTE — Specifications, Ratings and Dimensions subject to change without notice.
Ism i
lL
.T r
Up -Flo Installation
With Return Air Cabinet
hJIMENZI Iv,uo ili1c.110si
UP-FLO MODELS
]ELECTRICAL
INLET
SUPPLY AIR
OPENING
TOP VIEW
0 inch
Plenum and Outlet duct
E12424
Series
TERMINAL STRIP
ILow Volley —
0 inch
EIECTR
w•mo} o
49
HEAT
.m„or"„•,nu.,,n,a.,oarl
otMr eldelEs
duct within 3 ft. of cabinet
moiNENTmrI>vonor•no�
Floor
AIR
l:
C
Flow
19-1/8
ELECTRICAL
—r----i
i F` •�
INLETS
t
I
i'
r
Moth Skits)
1
1 BLOWER t
I
I l aIOWER 1
14
I 1
26
F
SUCTION IVAPO III
3-5/8
A
NEKGUN
G
5-1/2
7
10-1/2
13
v M-
21-1/8
0
24-11/16
22
J
OPTIONAL.
tit 'CPI2 COIL
22 2
10-3/8
IField I,ntsll.drr
RETURN AIR
2
2-3/16
I D OPENINGFLLTEII
5-1/4
4-G
IEHher Side I
2
.t L.
, or Bottom) I�
M11
1-3/16
1-3/16
$4
22 [-*2-318 CONDENSATE DRAIN G
RETURN AIR F `E F
OPENING RETURN AIR
SIDE VIEW OPENING
FRONT VIEW
DOWN-FLO MODELS
U. L. INSTALLATION CLEARANCES
Cabinet
0 inch
Plenum and Outlet duct
E12424
Series
E12Q5
Series
0 inch
on blower/coil units
49
Plenum and warm air
53
duct within 3 ft. of cabinet
1 inch
Floor
*Combustible
'When unit is installed in the down-flo position with electric heat on
a combustible floor the optional down-flo base is required.
r7 `
Model
No.
E12Q2
Series
E1120.3
Series
E12424
Series
E12Q5
Series
A
49
49
53
53
B
16-1/4
21-1/4
26-1/4
31-1/4
C
14-1/8
19-1/8
24-1/8
29-1/8
D
14
14
18
18
E
11
14
21
26
F
2-5/8
3-5/8
2-5/8
2-5/8
G
5-1/2
7
10-1/2
13
H
21-1/8
21-1/8
24-11/16
22
J
7-1/4
9-7/8
10-3/8
14
K
2
2-3/16
4-3/4
5-1/4
L
2
2
1-3/4
1-5/16
M11
1-3/16
1-3/16
7/8 1
1/2
Model
No.
ES12Q2
Series
ES12Q3,
ES12Q4
Series
E12Q4
Series
E12Q5
Sories
A
49
49
53
53
B
16-1/4
21-1/4
26-1/4
31-1/4
C
14-1/8
19.1/8
24-1/8
29-1/8
D
11
14
21
26
E
2-5/8
3-5/8
2-5/8
2-5/8
F
1-1/2
1-1/2
1-1/2
4-3/4
G
7-1/4
9-7/8
10-3/8
14
H
2
2
4-3/4
5-1/4
J
2-3/8
2-3/8
1-3/4
5-3/16
K
12-13/16
•14-13/16
••17-3/16
21-5/16
L
5-5/8
8-1/8
10-5/8
13-1/8
•17-3/8 with CPR12.41V coil.
••21-3/4 with CPR12.51V coil.
NOTE — When installing on a combustible floor an additive base
is required. Make an opening in the floor - 26-3/8 in. wide by
20-1 /8 front to rear for LB-34695BC base (E12Q4 - Series), 31-3/8
in. wide by 20-1 /8 in. front to rear for LB-34695BD base (E1205
- Series), 15-5/8 wide by 20-1 /8 in. front to rear for LB-34695BA
base IES1202 - Series), 21-3/8 in. wide by 20-1/8 in. front to
rear for LB -3469588 base IES1203, ES1204 - Series).
III
E
22
D RETURN AIR
OPENING
E
f
TOP VIEW
AIR FLOW
� ;BLOWER r
, f
I ff'
suwZL4v&TRn.u6numN
HEAT I
ELEMUM a,"
1.11164P 17.716
SUPPLY AIR
OPENING
SIDE VIEW
—16—
�I4W H G
4-2.316 LIQUID / 4-t OPTIONAL' )VAPOR
LINE t, CPH12 COIL, UNE K
(Field Installed)
CONDENSATE
DRAINS
FRONT VIEW I
(E12Q6 MODELS)
01B__
-01 H
--
H sG
, SUCT10
LIQUID LINE , , r I (VAPOR)
OPTIONAL' / LINE
4-t COIL) —
(Field
W Inst Inetlllad)
t I i
iT
CONDENSATE
A DRAINS ( �L
1 ,
1
ELECTRICAL INLETS i 1
(Both Sides) I I
I 1
TERMINAL STRIP
(Low Voltsae)
314 1-t116�1 4-+—G— 1.1116
SUPPLY AIR
OPENING
FRONT VIEW
L14
i
;a
C
BLOWER DATA
E12Q4 SERIES UPFLOW WITH
tELECTRIC HEAT AND CP12-46 COIL
BLOWER PERFORMANCE
Externa) Static
Pressure
lin. wg.)
Air Volume (cfm) @ Various Speeds
High Medium Low
0
1920
1460
1070
.05
1885
1450
1070
.10
1840
1440
1080
.15
1810
1430
1080
.20
1770
1415
1085
.25
1730
1400
1085
.30
1690
1380
1085
.40
1620
1335
1070
.50
1540
1280
1050
60
1450
1210
1000
NOTE - All cfm is measured external to the unit with the air filter in place.
tElectric heat resistance reflects heater with maximum resistance (5 elements). To
determine resistance of heater with less elements, deduct 0.05 external static
Pressure (in, wg.) per element.
�►p E12Q4 SERIES UPFLOW
VAT44-tELECTRIC HEAT AND CP12-51 COIL
BLOWER PERFORMANCE
External Static
Pressure
(in. wg-)
Air Volume Icfm) @ Various Speeds
High Medium Low
0
1930
1420
1070
.05
1900
1410
1080
.10
'1865
1400
1080
.15
1830
1390
1090
.20
1790
1380
1090
.25
1760
1370
1090
.30 1
1720
1360
1080
.40
1640
1320
1070
.50
1560
1280
1060
.60
1460
1220
1010
NOTE - All cfm is measured external to the unit with the air filter in place.
tElectric heat resistance reflects heater with maximum resistance 15 elements). To
determine resistance of heater with less elements, deduct 0.05 external static
pressure lin. wg.) per element.
E12Q5 SERIES UPFLOW OR DOWNFLOW
WITH tELECTRIC HEAT
BLOWER PERFORMANCE
External Static
Pressure
lin. wg.)
Air Volume (cfm) @ Various Speeds
High Med-High Medium Med-Low Low
0
2855
2610
2315
1985
1715
.05
2830
2585
2290
1970
1695
.10
2800
2560
2265
1945
1670
.15
2775
2535
2240
1925
1645
.20
2745
2510
2210
1905
1620
.25
2715
2480
2185
1880
1590
.30
2680
2445
2160
1850
1560
.40
2605
2375
2100
1795
1500
.50
2510
2295
2030
1725
1430
.60
2380
2190
1955
1640
1360
NOTE - All cfm is measured external to the unit with the air filter in place.
tElectric heat resistance reflects heater with maximum resistance 16 elements). To
determine resistance of heater with less elements, deduct 0.05 external static
pressure (in, wg.) per element.
E12Q4 SERIES DOWNFLOW
WITH TELECTRIC HEAT AND CPR12-46 COIL
BLOWER PERFORMANCE
External Static
Pressure
(in w )
Air Volume Icfm) @ Various Speeds
High Medium Low
0
1870
1495
1150
.05
1820
1480
1130
.10
1770
1460
1120
.15
1730
1440
1110
.20
1700
1420
1100
.25
1660
1395
1100
.30
1630
1370
1090
.40
1550
1320
1080
.50
1480
1270
1050
.60
1400
1200
1010
NOTE - All cfm is measured external to the unit.
tElectric heat resistance reflects heater with maximum resistance (5 elements). To
determine resistance of heater with less elements, deduct 0.05 external static
pressure (in. wg.) per element.
E12Q4 SERIES DOWNFLOW WITH
tELECTRIC HEAT AND CPR12-51 COIL
BLOWER PERFORMANCE
External Static
Pressure
(in. wg.)
Air Volume
High
(cfm) @ Various Speeds
Medium
Low
0
1870
1500
1130
.05
1830
1480
1130
.10
1790
1460
1140
.15
1755
1440
1140
.20
1720
1420
1135
.25
1680
1390
1130
.30
1650
1360
1120
.40
1570
1310
1090
.50
1480
1250
1050
.60
1390
1190
1010
NOTE - All cfm is measured external to the unit.
tElectric heat resistance reflects heater with maximum resistance (5 elements). To
determine resistance of heater with less elements, deduct 0.05 external static
pressure (in. wg.) per element.
E12Q5 SERIES UPFLOW WITH
tELECTRIC HEAT AND CP12-65 COIL
BLOWER PERFORMANCE
External Static
Pressure
lin. wg.)
Air Volume (cfm) @ Various Speeds
High Med-High Medium Med-Low Low
0
2525
2340
2105
1860
1655
.05
2490
2305
2080
1835
1610
.10
2450
2270
2050
1805
1575
.15
2410
2240
2020
1775
1540
.20
2370
2205
1990
1745
1505
.25
2330
2170
1960
1715
1470
.30
2290
2135
1930
1785
1440
.40
2210
2060
1860
1615
1370
.50
2120
1970
1790
1545
1295
.60
2020
1 1880
1700
1465
1215
NOTE - All cfm is measured external to the unit with the air filter in place.
tElectric heat resistance reflects heater with maximum resistance (6 elements). To
determine resistance of heater with less elements, deduct 0.05 external static
pressure (in. wg.) per element.
e
r.,
4
NO&A A Mr -C, &-Lj A:r
M.
qlar.: fietipgtance
qlaf.-Abso,rptal
AS
hading. Oqff[pi6q-
U s i n g -.-'p', r� 6 . cOuies...0 u Utfirle
atm ta
t hai o i a r t ra n s, c,... ,.
pr
ppig
V41ugs.petegffinec Nn
i9us:.;
Atal
I
r
7
FRODUCT4',-,
�,usja op
451"T
, r . Call oil
(in'Alabama D45-212koflej
11 0/7M -' p T )LE ?t
PH
IF E
on Ave. City oUndust
•
PhOn 21 /9
7
'.LOS ANGELES/NEW Y RK/OALJC�AGO
PA—ST .P ,E/SAL LAKE;
.
ILA M C-34 S7\ RQ ZA 1.3 �
1�
� 058:10 R2 3/28/84 VH/dr
Attachment D
"� �e FVooe
Form 2
(Revised 3/84)
Climate Zones 2. 4. 6. and 8-15
COMPLIANCE CHECKLIST
For Low -Rise Residential Buildings
(except hotels and motels)
Step 1: Enter on the form the values for each measure from your building plan
and specifications sheet.
Step 2: Enter points on this page while working through the point system
Building Shell
*Total Floor Area -
1. Slab -on -Ground; Perimeter ft..•Depth• in. .
2. Raised Floor R -Value.. . . . . . . . . . .
3. Ceiling Insulation or Construction Assembiy .
Attic. Percent of Roof Over Conditioned Space )Oo S .
4. Wail Insulation or Construction Assembly. . . . . . . . . . . .
Glazing; Total % Floor Area
Single
Double
Triple
5.
North -Facing.
3`Z S f
ye ft2
ft2
ft2
6.
7.
East -Facing
South -Facing.
.���=
T��Z{{—��S
ft2
ft
ft
ft2
ft
ft2
ft2
ft
ft
8.
West -Facing
. 2..Z2i
9.
Skylight. . .
.
�_ft
ft
ft
10.
11.
12.
13.
14.
Measure Points
)y% FJ
R.7!S—
a.
ft2
Shading Coefficient C LcZ��.rJ i 1
'ti, •tcL�S+���S
(excluding overhang)
a. East . . . . . . . . . . . . . . •2�iOSC .
b. South . . . . . . . . . . . . . . . I SC . . . . . . . . . . . .
c. West . . . . . . . . . . . . . . SC . . . . . . . . . . . . .
d. North . . . . . . . . . . . . . . . SC . . . . . . . . . . . . .
e. Skylight. . . . . . . . . . . . SSC . . . . . . . . . . .
Horizontal South Overhang Length. . . . ft . . . . . . . . . . . . .
Movable Insulation. S Floor Area. %
Infiltration (indicate Standard. Medium 677-19,;h) SI wild R.0
Thermal Mass
Exterior Wall Thermal Mass
Area, Heat Capacity_. R -Value . . . . . . ft2, HC. R -
Interior Thermal Mass
Area, Heat Capacity, R -Value . . . . . . ft2. S.4 HC. R. -Le
P-27, -t.S
HVAC System '•
15. Gas Furnace without Refrigeration•Cooling
(Seasonal Efficiency). . . . . . . . . .\. . .
16. Heat Pump (Energy Efficiency Ratio) . . . . . . . . . . . .
17. Gas Furnace with Refrigeration Cooiing
Seasonal Efficiency and Seasonal
Energy Efficiency Ratio 8 y SE
18. Active Solar (Net Solar Fraction, X)� .
19. Zonally Controlled Electric
Resistance Space Heating . . . . . . . . . . . . . (Yes/No)
Domestic Water Heating••
20. Solar With Gas Backup (Net Solar Fraction, 5) . . . . . . . . .
21. Other Water Heating (Describe type)
Point System Compliance Total . . . . . . . . . . . . . . .
• nec ist items; not a point system measure.
"Attach documentation for efficiencies and NSF.
—3
3
SE NA
EER ';7A
) tD.0 SEER 1 1 1
%NSF —;T4—
NA
:NSF
nJ A
+T
1
do S
3
s
I
:7)
A
J
1. SLAB -ON -GROUND FLOOR
Locate the R -value of the proposed
slab -edge insulation and planned
depth of insulation from line 1 of
the Compliance Checklist, find the
corresponding point value in Table
3-1 and enter it on the appro-
priate line below. Enter the
length of insulated slab and total
length of slab perimeter from
line 1 on the appropriate lines
below. Subtract the insulated
length from the total length and
enter the difference on the line
belovx marked, "length -'of uninsu-
lated." Perform the required
calculations for lines a and b
below and add the results
together. Enter this sum on line
c below and also on line I in the
"Points" column of the checklist.
Note: If the proposed building
has both a slab and a raised
floor, multiply the value on line
C by the square footage area of -
the slab floor and divide this by
the total floor area. Enter the
result of this calculation in the
"Points" column on line 1.
C-49 ECM 15
76
Table 3-1. Slab Floor Points
j Insula-
I R -Value of
Insulation I
I tion
I
I
I Depth,
1 inches
( 0-2
1 3-4 I
5-6
1 7f 1
I
I
I i
I I-•
I 0* - 11
1 -4 I
-4
-4
1 12 - 15
1
-2 1
-1
I -1 I
16-19i-4
1-1
I-1
1
0 I
I 20 f
I
l -4 I
I I
-1 1
I
0 1
I
0 1
I
Insulated Slab:
x a
points length total
insulated length
Uninsulated Slab:
x -r b
points length total
uninsulated length
a +-bac
2. RAISED FLOOR
Using the R -value indicated on Table 3-2. Raised Floor -Points
line 2 of the. Compliance Check- I ...
list, . find the corresponding
1 R -Value of— 1."':-''•
7 • - I
point value from Table 3-2 and
Insulation *1
' Points '
enter it on the appropriate part
of line a below. Enter on the
appropriate part of line's, the
up to 2
-6
area of insulated floor which is
2 - 5
-4 �
• over a crawl space or vented
6 - 18 A�
-2
basement from line 2 of the
Iv
19 up I"
0
checklist.. Enter the total area
from "Total Floor Area" line of
the checklist on the appropriate
part of lines a and b.' Subtract
Insulated Floor:
the floor area over a vented
space from the total area and
x
a
enter the difference on the part
points floor area
total
of line marked "area over a
over vented
area
vented space." Perform the
space
required calculations for lines a
and b, and add their' results
Uninsulated Floor:
together. Enter this sum on
line c below and also in the
x
= b
"Points" column on line 2 of the
points floor area
total
.checklist.
over open
area
space
If part of a raised floor is over
an open area, use Table 3-4a or
3-4b to determine its
corresponding points.
77
C-4 9 ECM 15
a F b - c
3
3. CEILING
Using the R -value of the ceiling
insulation from line 3 of the
Compliance Checklist, find the
corresponding point value from
Table 3-3a' and enter it in' the
"Points" column on line 3 of the
checklist.
or
Using the R -value of the ceiling
construction assembly from line 3
of the Compliance Checklist, find
the corresponding point value from
Table 3-3b and enter it in the
"Points" column on line 3 of the
checklist. -
If -you have different levels of
R -values, you may calculate the
average of the R -values Weighted
by their respective areas or use
the the lowest of the R -values to'
determine the points. If the
calculation is done, attach the
documentation to the checklist and
indicate the level of insulation
and location of each on the
building plans. Be sure that this
average R -value equates to having
a minimum of R-19 insulation
uniformly distributed over the
ceiling.
C-4 9 ECH 15
78
Table 3=3a. Ceiling Insulation Pts.
R -Value of Insulation I Points
I I I
j 19 -10 I
22 -8 ...
I 30 ( -4 I
I 3 0 I
I I 0 I
I I I
Table 3-3b. Ceiling Assembly Points
R -Value of
Assembly I
I
I (excluding
I
air films) I
I
Points I
I
I 19 -
20 I
-12 I
I 21 -
22 I
-10 I
I 23 -
27 I
-8 I
I 28 -
31 I
-6
I 32 -
36 I
-4 I
I 37 -
38' I
-2. I
I 39 -
51 I
0 I
I 52-
75 I
1-2 I
I 76 up I
I I
f4 I
4. WALL
Using'* the R -value of the ' insula-
tion from line 4 of the Compliance
Checklist, find the corresponding
point value from* Table 3-4a and
enter it in the "Points' column on
line 4 of the checklist.
or
Using the R -value of the wall
construction assembly from line 4
of the Compliance Checklist, find
the corresponding point value from
Table 3-4b and enter it in the
"Points" column on line 4 of the
checklist.
If you have different levels of
insulation, follow the third para-
graph of the ceiling instructions,
except that the average R -value
must be equivalent to having a
minimum of R-11 insulation uni-
formly distributed over the wall
if the wall has wood framing.
Table -3-4a. Wall Insulation Points
R -Value of Insulation Points. I
r •.
I • - (11 -6 I
J1-2 I
J
24 •
30 i 1-3 i
I I I
Table 3-4b. Wall Assembly Points
I R -Value of
Assembly I
1
I (excluding
I
air films) I
I
Points I
I
t
1-10 I
70.0 -498.0
i
t
•
i
1-6 I
26.7 -
79
Table -3-4a. Wall Insulation Points
R -Value of Insulation Points. I
r •.
I • - (11 -6 I
J1-2 I
J
24 •
30 i 1-3 i
I I I
Table 3-4b. Wall Assembly Points
I R -Value of
Assembly I
1
I (excluding
I
air films) I
I
Points I
I
J 499 up I
1-10 I
70.0 -498.0
i
1-8 I
I 37.0 -
69.0 I
1-6 I
26.7 -
36.9 I
1-4 I
J 20.2 -
26.6 J
1-2 I
J 15.7 -
20.1 I
0 I
I 13.4 -
15.6 I
-2 I
11.3 -
13.3 I
-4 I
I 9.8 -
11.2 I
-6- I
8.8 -
9.7 1
-8 I
7.7 -
8.7. .' I
-10
7.0 -
7.6 • ' I
-12
I 6.4 -
6.9 I
-14 1
5.8 -
6.3 I
-16 . I
J 5.3 -
5.7 I
-18 I
J 4.9 -
5.2 I
-20 I
J 4.5 -
4.8 J
' -22 I
J 4.2 -
4.4 (
.. -24
i 3.9-
4.1': J
-26
J 3.6 -
3.8 (
-28 I
J 3.4 -
3.5 I
-30 I
J 3.2 -
3.3 I
-32 I
J 3.0 -
3.1 I
-34 I
I 2.8 -
2.9 1
-36 I
I 2.7
I
-38 I
2.5 -
2.6 I-40
2.4
I
-42 I
I 2.3
I
-44 I
I 2.2
I
-46 I
J 2.1
I
-48 I
2.0
I
-50 I
I 1.9
I
i
J
-52 I
J
LI
C
C
5. GLAZING, NORTH-FACINQ...\aJ:c'L.:,.,.-,%*t.;f'�4
Nor -%Fati'hg Glazing-1ts-P
, * * ith n7,
Using - total t4orth-facing' ..-Table' 3
glazing percentage frqM.,line,5 df- -i I I t -., . .
the Compliance Checkk&9t,•.find ..-tht i1:IJ ,Total ., I I Glazing T� pe e
corresponding poLnt)cr.1+4a,1yeq,,:fpr -.2 Of*, "..I i Y. ') f - I I ...
- .1 T -On -sl - 1. 1- : .:I . yrpill, 1) 1�1 Irr
each glazing type " it*. sbe r, used i ri oor Dbl
(single, double., andlor' moke) IV .. C Ar..Iqa U U U
P-66 0.42�d %4V 1)-:1.2-- 1
Table 3-5. Enter the5se values - -:-,
the appropriate linqs..belov-i [,'On- "Vi 11a0 1 0.651 11 Idbwzi 1):65 1
the adjacent lines'._ -c enter- A.: -,the, r -I
square footage of each 1:11az3bg up, tto 1#41 1 SAM 1 13
type indicated on Vie chockllat-;` 1 �2- 2
.3- 3A I:.* -i o
Next, enter the total-Squate. foot -4 ji
age of all north-fackrig glazing.. 1 1; :.3.5- 4:.8 -3
-1
Perform the requiredid-alculationd. 1 -.4.14- S-0 -6. , 1-!-. !)-4!.
i i 1 1, -61 i-5
and enter the result&. An. �heit'.; 1 1 c 6.1--,7i.4 -8. . . -
respective lines a and ba' ...Total.. 13. 7.5- ;8-.17 1 J -10. -:.. I -i . r8: .3
lines a and b, and enter ..the -skim i 8.8- 9.9 1 1,-12 ...,:-10!
on line c, below ;and !it ;,..the. AI 10.0-11.3 I 1-15 .1=12!
"Points" column on line .3.k:of .,the -11.4:,-12.5 I :6 -117 I 1 -, !-141 I lil 2 I I -114
checklist. cr, 12.6-13.4 I 1 -20. 1 �:3 7161
13.5-15.0 -22. It -, -+18'
Be sure to use the.. total,-. north-.- I.',' - - :-".I I I i
facing percentage instead !,O_f, the .:i;. J
individual percentaged. gorz:.each,_-:--
of glazing A% :'given First ..Type (indicate'. i-:-!
type g_ Sngl', Dbl, or T-rpt)_�� oc
orientation.
X x a
points . area total :;.-::a
first area ftrit r a
second - Type (kpdicate,;;-n .: -;. Z #3
• Sngl9 Dbl, or Trpt)_LIV Oc
X Xb l b
points area :- -.1 total
second area z;;:c-nd ar,,a
a I. b - c a 11 b .1 c_ _.
If there is no,*I)or-th7,.fating,glazing;
enter 1-2 on line,,. c, ant Iinlef, 5. 5
C-4 9 EC.4 15
80
C-4 9 EC.4 15
6. GLAZING, EAST -FACING
• Using the total _ east -facing
Table 3-6. East -Facing Glazin Pts.
glazing percentage from line 6 of
= .: .,
the Compliance Checklist, find the'
Tot ".�
.Z
Glazing
Type
corresponding ' point values for
I of..: i
each glazing type to' be. used.
is � Floor
Sngl,.
Dbl,
Trpl,
(single, double, and/or triple) in
I .Area`; I
U 10=
U
Table 3-6. Enter these values on
I :',. 10.66-
10.42-
10.41-I
the appropriate lines below. 0n
11.10
10.65
I
down I
the' adjacent :lines," enter the
square footage of each glazing
I up to 1.5 I
1-3 I
w4 I
A' I
type indicated on the checklist.
( 1.6— 2.3 I
1-1 I
1-2 I
*3 i
Next, enter the total square foot-
I 2.4- 3.4 )
-1
0 )
a
age of all east -facing glazing.
I 3.5- 4.3
-3I_
-2 I
0
Perform the required calculation
I .4-
I
-2 I
and enter t he -results on their
I - .3
-8 I
)
-4 I
respective lines a and b. Total
) 6.4- 7.3
-11
-8 I
-6
lines a and b, and enter the sum
7.4- 8.4 I
-12
-10
-8
on line c below and in the
I 8.5- 9.4 I
-16
-12
-10
"Points" column on line 6 of the
9.5-10.4 I
-18 I
-14
-12
checklist.
10.5-11.8
-22
-17
-15
111.9-13.5)
-25
-20 I
-18 I
Be sure to use the total east-
13.6-15.0
-29 I
-23 I.
-20
facing percentage instead of.the
I
I
I
individual percentages for. each
type of glazing in 'a given
orientation.
First Type (indicate
Sngl, Dbl, or Trpl)
:
x
4-
= a
points area
total
first
area
Second Type (indicate
Sngl, Dbl, or
Trpl)
:
X
•-
b.
.
points area
total
;
second
area
a I- b c.
If there is no
east -facing glazing,
enter 1-7 on line c and
line 6.
C-4 9 EC:i 15 81
7.
GLAZING. SOUTH -FACING
Using the total south -facing
glazing percentage from line 7 of
the Compliance Checklist, find the
corresponding point values' for
each glazing type to be used
(single, double, and/or triple) in
Table 3-7. Enter these values on
the appropriate lines below. On
the adjacent lines, enter the
square footage of each glazing
type -indicated on the checklist.
Next, enter the total square foot-
age of all south -facing glazing.
Perform the required calculation
and enter the results on their
respective lines a and b. Total
lines a and b, and enter the sum
on line c below and in the
"Points" column on line 7 of the
checklist.
Be sure to use the total south -
facing percentage instead of the
Individual percentages for each
type of glazing in a given
orientation.
C-4 q rr%f 15
Table 3-7. South -Facing Glazing Pts
First Type (indicate
Sngl, Dbl, or Trpl)
a - a
points area total
first area
Second Type (indicate
Sngl, Dbl, or Trpl) :
x c___—_— b
points area total >
second area
a 1 b - c
If there is no south -facing glazing,
enter 1.3 on line c and line 7.
82
I Total
I Glazing Type
I
I Z of
I
V'
I
I Floor
Sngl,
Dbl, I
Trpl,
I Area
l U.
I U
i_�
I
1 0.66-
10.42-
1
0.42
I "
1 1.10
0.65 I
down I
I 1.3 dwoi 1-2 I
1-2 I
.I
1.- . 1
-4 1
-2 I
-2 i
1 5.5- 7.3 i
-6 I
-4 i
-3 I
I 7.4- 9.1 1
-9 I
-6 I
-5 I
I 9.2-10.8.1
-12 1
-8 I
-7 I
i 10.9-13.3
I -16 I
-11 i
-10 I
1 13.4-15.7
I
1 -20 1
I I
-14 1
I
-12 1'
I
First Type (indicate
Sngl, Dbl, or Trpl)
a - a
points area total
first area
Second Type (indicate
Sngl, Dbl, or Trpl) :
x c___—_— b
points area total >
second area
a 1 b - c
If there is no south -facing glazing,
enter 1.3 on line c and line 7.
82
S. GLAZING, WEST -FACING
Using the total West -facing
glazing percentage from line 8. of -
the Compliance Checklist, find the
corresponding :'point . values for
each glazing type' to be used
(single, double, and/or triple) in
Table 3-8. Enter these values on
the - appropriate lines below. On
the ajdjacent lines, enter the
square footage of each glazing
type indicated on the checklist.
Next, enter the total square foot-
age of all west -facing glazing.
Perform the required calculation
and enter the results on their
respective lines * a and b.' Total
lines a and b, and enter the sum
on line c below and in the
"Points" column on line 8 of the
checklist.
Be sure to use the total west -
facing percentage instead of the
Individual percentages for each
type of glazing in a given
orientation.
Table 3-8. West-Facinz Glazing Pts.
I Total
1 : Glazing Type
Z of
1 ..
.
_ . .
I Floor
Sngl,
I Dbl,
I Trpl,
I; Area
I U-
I U-
I U- I
f'
1 0.66-
1 0.42-
1 0.41 1 _.
1
1 1.10
1 0.65
1 down I
I up to 1.0 I
f8
I fs
I f8 I
I 1:1- 6 1
}6
1
I F6 I
1 1.7- 2.
K4"N
I F5 1
I 2.- .9I
a
1
i 0 i
1 3.0- 3.4 1
-1
1 0
1 1-1 J
I 3.5- 4.2 I
-4
I -2
J -1' I
J 4.3- 4.8 1
-7
1 -4
1 =3 i
I 4.9- 5.4 I
-9 I
-6 I
-5 I
I 5.5- 6.1 1
-12 1
-8 I
-7 I
6.2- 6.7 1
-14 1
-10- I
-9 1
1 6.8- 7.3 (
-16 1
-12 (
-10 j
1 7.4- 7.9.1
-19 1
-14 1
-12 1
1 8.0- 8.5 1
-21 1
-16 1
-14 I
1 8.6- 9.1 I
-24 1•-18
1
-16 I
I 9.2- 9.7 1
-26 J
-20 I
-18 I
I 9.8-10.3 J
-29 J,
-22 J
-20 1
J 10.4-11.3 J
-32 J
-25 i
-22 I
111.4-12.0 1
-35 I
-28 I
-25
First Type (indicate
. Sngl, Dbl, or Trpl)
x = a
points area total
first area
Second Type'(indicate
Sngl, Dbl, or Trpl)
x =b�
points area total
second area
a #- b - c
If there is no west -facing glazing,
enter }10 on line c and line S.
83
C-49 ECX 15
9. SKYLIGHTS
Using the* total skylight glazing
percentage from line 9 of the
Compliance Checklist, find the
corresponding point value for each
glazing type to be used (single,
double, and/or triple) in Table
3-9. Enter these values on the
appropriate lines below. On the
adjacent lines, enter the square
footage of each glazing type indi-
cated on the checklist. Next,
enter the total square footage of
all skylight glazing. Perform the
required calculation abd enter the
results on their respective lines
a and b. Total lines a and b, and
enter 'the sum on line c below and
In the "Points" column on line 9
of the checklist.
C-4 9 ECM 13
Table 3-9. Skylight Points
I Total
1 1
sing Type
I
I x of
!
I
I Floor
Sngl,
I Dbl,
Trpl,
I area
lU-
IUs IU-
I
I
10.66-
10.42- !
0.41 I
"
11.10
( 0.65 I
down
1 up to 1.0 I
-2
I'-2 I
-2 I
1 1.1- 1.6 1
-4
I -4
I 1.7- 2.3 1
-7
'I -6
-5. I
j 2.4- 2.9 I
-9
I -8 (
-7 I
1 3.0- 3.4 I
-10
I -10 I
-9 I
I 3.5- 4.2 I
-14
I -12 I
-11 I
I 4.3- 4.8 I
-17
( -14 I
-13 I
I 4.9- 5.4 I
-19
I -16 I
-15 I
I 5.5- 6.1 !
-22
) -18 I
-17 I
I 6.2- 6.7 (
-24
I -20 I
-19 I
I 6.8- 7.3 I.
-26
I -22 I
-20 I
I 7.4- 7.9 I
-29
I -24 I
-22 I
I 8.0- 8.5 I
-31
I -26 I
-24 I
j 8.6- 9.1 (
-34 I
-28 I
-26 I
I 9.2- 9.7 I
-36 (
-30 I
-28 I
I 9.8-10.3 I
-39 I
-32 I
i
-30 i
f
First Type (indicate
Sngl, Dbl, or Trpl)
x -r- - a
points area total
first area
Second Type (indicate
Sngl, Dbl, or Trpl)
x - -b
points area total
second area
a I- b - c
If there Is no skylight glazing,
enter 0 on line c and line 9.
84
10. SHADING COEFFICIENT
Locate the. percent of total
glazing to floor areas on lines 5,
6, 7,, 'and 8 of the Compliance'
Checklist and the Shading Coeffi-
tient (SC) for the shading ddvice,-
for each orientation shown below..
Select Shading Coefficients that
are for devices used with single
glass only from Table 1 in Part 2;
ASHRAE HAMBOOK OF FUNDAMENTALS;
or manufacturers' data. Find the
corresponding point values from
Table 3-10 and enter it in the
"Points" column on the corres-
ponding lines 10a, 10b,•10c, and
10d of the checklist.
Please note this applies to all
glazing orientations except north.
East:
X x a .
SC of _ SC of SC of Net SC
glazing device 1 device 2
South:
X - * a ..%
SC of SC of SC of Net SC
glazing device 1 device 2
West:
X
SC of SC of
glazing device 1
Skylight:
X
SC of Net SC_
device 2
If there is no glazing in an x a •
orientation, enter zero (0) in the SC of SC of SC of Net SC
"Points" column on the corres- glazing device 1 device 2
ponding lines of the checklist.
Table 3-10. Shadinx Coefficient Points
1 SC by I ( SC by ( 1
1 Orien- i x Floor Area 1 Orien- I x Floor Area 1
I tation I 1 tation I I
Vr
r r
I East 1 0- 10.8-11.6-13.2-14.8-16.4-18.0-1 West 1 0- 10.8-11.6-13.2'-14.8-16.4=18.0-1
1 10.7 11.5 13.1 14.7 16.3 17.9 19.6 1 10.7 11.5 13.1 14.7 16.3 17.9 19.6 1
I I I I I I i I I I• i I I I I I I
I
1 0 -.151-'01 0 1 0 1 01 01 01 0 0 -.15 1 0 1 0dl
1 01 01 01 .0 1
y 1.16 . - .32 1 0 1 -1 1 -1 1 -2 I - -4 1 -5 16 - .30 1 0 1 01 72 j -3 1 -4 I -5 1
1.33 - .49 1 0 1 -1 1 -2 1 -4 1 =7 1 -8 1-10 .31 - .46 1 0 1 -1 1 -2 1,-4 1 -6 1 -8 1-10 1
1.50 - .68 1 0 1 -1 1 -3 1 -6 1 -9 1-12 1-15 1.47 - .62 1 0 1 -1 1 -3 1 -6 1 -9 1-12 1-15 1
1.69 - .86 1 0 1 -2 1 -4 1 -8 1-12 1-16 1-20 1.63 - .79 1 0 1 -2 1 -4 1 -8 1-12 1-16 1-20 1
1 .87 up 1 0 1 -2 1 -5 1 -9 1-13 1-18 1-23 1 .80 up 1 0 1 -2 1 -5 1-10 1-17 1-22 1-27 1
I South 10.1-1 1.6-1 3.2-1.4.8-1 6.4-1 8.0-1 Skylight 1 0- 10.4-10.8-11.6-12.4-13.2-14.0-1
1 11.5 1 3.1 1 4.7 1 6.3 1 7.9 1 9.6 1 10.3 10.7 11.5 12.3 13.1 13.9 14.8 1
I
t o -.151 01 0 l 0 1 01 01' 0 1 0 -.15 l 0 1 0 1 0 1 0 1 0 1 01 0 1
N.16 - .30 1 0 1 �'1 -1 1 -1 1 -2 1 -3 J.16 - .30 1 0 1 0 1 -1 I -2 ! -3 I -4 I -5 I
1.31 - .46 1 0 1. -1 1 -2 1 -3 1 -4 1 -5 1.31 - .46 1 0 1 -1 1 -2 1 -4 1 -6 1 -8 1-10 1
1.47 - .62 1 0 1 -1 1 -3 1 -4 1 -6 1 -7 1.47 - .62 1' 0 1 -1 1 -3 1 -6 1 -9 1-12 1-15 1
1.63 - .79 1 0 1 -2 1.-4 1 -6 1 -8 1 -10 1.63 - .79 1 0 1 -2 1 -4 1 -8 1-12 1-16 1-20 1
1 .80 up 1 0 1 -3 1 -5 1 -8 1 -11 ( -14 1 .80 up 1 0 1 -2 1 -5 1-10 1-17 1-22 1-27 1
85
C-49 E04 15
r;
t r
11. HORIZONTAL SOUTH OVERHANG
Using the percent of south glazing
area to floor area from line 7'
of the Compliance Checklist, find
the corresponding point value in
Table 3-11. Enter it in the
"Points" column on line 11 of the
checklist.
12. MOVABLE INSULATION
Using the percent of floor area
from line 12 of the Compliance
Checklist, find the corres-
ponding point value from Table
3-12. Enter this value in the
"Points" column on line 12 of the
checklist.
C -b 9 ECH 15
Table 3-11. Horizontal South
Overhang Points
South Glazing
J Length Out J Area, 2 of Floor 1
from Wall J J
I ft
J J 0-6.3 1 6.6 up J
0 - 1.9 -2
2.0 3.9 1 � 1 0 1
J .O up I Fl 1 1-2 1
1 1 1 i
Table 3-12. Movable Insulation
Points
J Moveable Insulation 1 1
Area, % of Floor J Points J
I •I I
J All ( 0 1
11
13. INFILTRATION CONTROL
Identify the proposed infiltration
Table 3-13.^ Infiltration Control...
control features and find the
Features Points
corresponding point value in Table
3-13. Enter the ' point value in
._ Control' Features_• Points I
the "Points" column on line 13 of
the checklist.
_:•
Standard ..•
I(D11
Standard means caulking Weather-
,%
stripping, sealing, etc. as
air changes per hr
described in Part 1, Mandatory
Features and Devices.
I Tight FO
Tight means all the features in
I
the standard control plus gaskets
._i 0.6 air changes per hr f
on electric outlet and switch
boxes in all exterior walls poly-
ethelene sheets over the inside
face of all exterior walls, and a
mechanical ventilation system
capable of ventilating at the rate
of 0.7 air changes per hour for
the whole building with an air-
to-air heat exchanger. Other
measures may be used for the 0.6
Infiltration rate if justified
with documentation and attached to
the checklist. However, the
mechanical ventilation with a heat
exchanger must still be used.
C-4 9 E04 15 87
14. THERMAL MASS
This section of the point system
applies to both exterior and
Interior thermal mass building
elements because. *equivalent ther-
mal mass factors have been deter-
mined.which are relative to their
performance. Lines a, b, c, and d
at the end of this section 'are
used to calculate the thermal mass
capacity of different mass types:"
Determine the heat capacity (HC)
and •R -value of the mass element
from Table 3-14a or 3-14b, or if
the tables do not apply to the
proposed mass type, calculate HC
and R using the equation below.
Enter the two values in the appro-
priate place on line 14 of the
Compliance.Checklist.
Table 3-14a. Masonry or Concrete
Wall HCO Btu/'F-ft2
I Wall Weight, lb/ft2 i HC I
I
1 10 - 13 I 2 I
I 14 - 18 I 3 I
19 - 23 I 4
I 24 - 28' I 5
1 29-32 I 6 1
33 - 37 I ' 7
I 38 - 47 I 8 1
I 48 - 66 I 10 I
1 67 _ °4 1 14 1.
1 95 up i 20 1
Table 3=14b. Solid Wood Wall HC and .
R -Value
I I Wood Density, lb/ft3 1
I Average I
I Thick- 21 - 26-1 27 - 31 32. F
-37 1
1 mess, I Cedar i Pine 1 Dg•
I inches I Hem -Fir 1 Bemlk. 1 SO.Pine 1
1
HC/R HC/R. HC/R.
I 3 1 2/4.3 I 3/3.6 I. 3/3.1 1
1 4 ( 3/5.7 I 4/4.8 I 4/4.2 I
1 5 1 3/7.1 I 4/6.0 i 5/5.2 I
I 6 I 4/8.6. I 5/7.2 I 6/6.3 I
1 7 1 5/10.0 I 6/8.4 I 7/7.3 1
1 8- 9 1 6/11:4 i 7/9.6 I 8/8.3 I
lo'- 11 17/14.3 I 9/11.9 1 11/10.4 I
1 12 up 18/17.1 111/14.3 1 13/12.5
HC and R Total Calculation:
S
C D t HC
� Y_ :.2 ..,-t e
r Zt R total
Where:
C Specific heat in Btu/lb-'F
D density in lb/f t3
t thickness in ft
r ' resistance per foot in
hour -f t2-'F/Btu-f t
88 9
C-4 9 ECM 15 ,
Using the HC and R factors deter-
mined In the first step, determine _...
the equivalent mass capacity fac -t-. _
for from the appropriate. ?able 3-`' - -
14c or' 3-14d, and • 'enter it *oa
line A, following,. and line.. 14- of- •- - �' - - • • r.
checklist.
?able 3-14c. Pass Ca acity Factors for Interior Masa
T) R -Value of Interior Mass Element Excluding Air Films T
I Beat Capacity, I o.3. 10.4-'I 0.8- 1 1.3- 1.1.8- 1 2.6- 1 4.1- 1 7.6 1
1 Btu/ft -'F 1 Down 10.7 j 1.2 1 1.7 1 2.5 1 4.0 1 7.5 1 Up i
I. -
I 1.5 -
1.7
1 '1
1. 2.8,.
12.8
1
1 2.8
1
12.7
1
j 2.6
1
1 2.4
1 _
1 2.3
i I.
1 1.9 1
j 1.8 -
2.2
j 3.2
1 3.2
j 3.2
j 3.1
1 3.0
) 2.9
12.6
12.1.1
j 2.3 -
2.7
j 3.7
) 3.7
1.3.6
13.5
i 3.3
1 3.0
1 2.8
12.2 j
I 2.8 -
3.2
) 4.3
) 4.3
14.1
13.8
13.6
13.3
13.0
12.3 j
I 3.3 -
3.7
j 4.8
14.7
j 4.4
1 4.1
1 3.8
j 3.4
1 3.1
j 2.4 j
3.8 =
.4.2
) 5.2
) 5.0
) 4.7
i 4.3
1 4.1
1 3.6
) 3.2
) 2.5 !
4.3 -
4.7
) 5.6
j 5.3
j 5.0
1 4.6
) 4.3
1 3.7
1 3.3
j 2.6 )
j 4.8 -
5.5
) 5.9
1 5.6
) 5.2
14.8
) 4.4
j 3.8•
j 3.5
12.6 j
I 5.6.-
7.0
) 6.
j 6.1
15.5
) 5.0
) 4.7
) 4.1
.1 3.6
1 2.8 1
7.1--
9.0
) 7.3
j 6.4
j 5.9
1 5.3
15.0
1 4.4
j 4.0
j 3.1 1
I 9.1 -
12.0
1
1 6.8 .1
6.1
i 5.6
) 5.2
) 4.7
j 4.3
1 3.4 I
j 12.1 -
17.0
( 8.2
) 7.1
j 6.4
( 5.8
15.5
j 5.1
1 4.7
1 4.0 )
1 17.1 -
22.5
1 8.5 1
7.6
16.9
16.4
1 6.1
1 5.7
15.3
j 4.7 I
I 22.6 -
27.5
1 8.7 .I
7.9
17.2
16.8
1 6.4
j 6.0
) 5.8
1 5.2 )
27.6 -
35.0
1 8.9 i
8.1
1 7.4
17.1.1
6.8
1 6.4.
1.6.1
1 5.7 1
1 35.1
up
j 9.2 1
8.3
1 7.8
17.4
17.2 '1
7.0
1 6.8
( 6.4 I
C-49 ECH 15
89
Table 3-14d. Hass Capacity Factors for Exterior Mass Wall
I I R -Value of Exterior Mass Assembly Excluding Air Films I
I Beat Cap j
�ty, I 2.0- i 2.5- I 3.0- I .3.5- I 4.0- I 4.5=5.0- 1•
I Btu/ft2F,. I • 2..4 j 2.9 ) 3.4 ) 3.9 1 4.4 ( 4.9 ) 5.4 1
( 1.5 -
1.
\ ( 1.3..).
1.4
( 1.5
I 1.6
( 1.7
) 1.8
) 1.8
j 2.0 -
2.4
�,j 1.6 I
1.7
I 1.8
I 1.9
I 2.0
I 2.1
j 2.2 j
j 2.5 -
2.9
`) 2.2
) 2.3
I 2.4
i 2.4
j 2.5
) 2.7
) 2.8 j
I 3.0 -
3.4
�� 2.7 I
2.8
) 2.9
I 3.0
( 3.1
( 3.2
I 3.3 )
3.5 -
3.9
) x.,3.2 )
3.3
) 3.4
) 3.5
) 3.6
) 3.6
j 3.7 )
j 4.0 -
4.4
3.7 (
3.8 I
3.9
i 4.0
) 4.1
) 4.2
I 4.2 i
j 4.5 -
4.9
1 4'12 1
4.3 1
4.4
j 4.5
1 4.6
1 4.6
1 4.6 )
) 5.0 -
5.4
j 4.7• I
4.8 I
4.9
I 5.0
I 5.1
1 5.1
I 5.1
_
j 5.5 -
5.9
I 5.6 •�
5.3 j
5.4
j 5.5
j 5.6
I 5.6
I 5.6-
.6-6.0
6.0-
6.9
( 7 ,,1
5.9 )
6.0
1 6.1
) 6.1
( 6.1
i 6.1
i 7.0 -
7.9
I 6. (
6.9 I
7.0
( 7.1
I 7.1
I 7.1
j 6.9
j 8.0 -
8.9
) 7. v,
8.0 1
8.1
1 8.2
1 8.1
1 7.9
) 7.5 )
I 9.0 -
9.9
I 8.8 11
9.1 i
9.2
I 9.2
( 9.0
j 8.4
I 7.8 j
10.0 -
11.9
( 9.7
s9.8 )
9.9
( 9.8
) 9.5
) 8.8
( 8.2
12.0 -
13.9
j 11.6
1'1.5 1
11.1
i 10.5
j 9.8
I 9.1
I •8.5 j
14.0 -
19.9
j 13.6 I
35.0 j
11.8
( 10.9
) 10.0
j 9.4
I 8.7 j
j 20.0 -
29.9
115.1 I
�7 )
12.4
111.4
110.5
j 9.7
I 9.1 j
( 30.0 -
39.9
( 16.1 (
1 .3 (
13.2
( 12.0
( 11.1
( 10.4
( 9.8
40.0
up
j 17.0 )
15. j
13.8
112.6
1 11.7
j 11.1 'I
10.5 j
Beat Capacity,
1 5.5- 1
6.0-`..
7.0- j
8.0-)
10.0-
( 15.0-
) 20.0 j
I Btu/ft2-'F
I 5.9. I
6.9 I
7.9 I
9:9 (
14.9 119.9
I
up i
I 1.5 -
1.9
I 1.8
I 1.9
i rel 9 I
1.9
I 1.8 I
1.7
I 1.6 I
I 2.0 -
2.4
) 2.2
I 2.2
) 2. I
2.4
) 2.5 I
2.4
) 2.3 )
I -
2.9
I 2.8
I 2.9
) 2. I
2.9
( 2.9 I
2.8
( 2.5
--.21.5
3.0 -
3.4
I 3.3
) 3.3
) 3.4 (
3.4
( 3.4 )
3.1
I 2.9 )
i 3.5 -
3.9
I '3.8
I 3.8
) 3.8
3.8
j 3.7 I
3.3
j 3.0 I
4.0 -
4.4
) 4.2
I 4.2
j 4.2.,
4.1.
j 3.9 )
3.5
I 3.1 j
4.5 -
4.9•
1 4.6
1 4.6
( 4.6; j
4.4
) 4.2 1
3.6
I 3.1 1
I 5.0 -
5.4
i S.1
j 5.1
i 4.9 `:1
.7
) 4.3 1
3.8
1 3.2
I 5.5-
5.9
I 5.6 •�
5.5
I 5.2 (
8
I 4.5 (
3.9
( 3.3
I 6.0 =
6.9
I 6.0
I 5.9
I 5.4 j
5.
I 4.6 (
4.0
j 3.3 )
7.0 -
7.9
1 6.7
1 6.4
j 5.7 j,,
5.
1 4.8 1
4.1
1 3.4 )
j 8.0 -
8.•9
1 7.0
1 6.6
1 5.9 j
5.4.
j 5.0 (
4.3
I 3.5 I
j 9.0 -
9.9
. 7.3
I 6.8
i 6.1 )
5'. 6 •
5.2 )
4.4
j 3.6 I
I 10.0 -
11.9
I 7.6
I 7.1
I 6.4 )
5..8
) 5.3 I
4.5
i 3.8 I
j 12.0 -
13.9
) 8.0
I 7.4
I 6.6 I
61
) .5 )
4.8
) 4.0 I
I 14.0 -
19.9
I 8.2
i 7.6
I 6.8 )
6:3
I S I
5.0
I 4.3 I
20.0 -
29.9
( 8.5
I 8.0
( 7.2 j
6.7
) 6. j
5.6
( 5.0 )
.'30.0-39.9
1,9.2
I 8.8
I 8.1 I
7.6'.
( 7.3 (
6.7
I 6.2 I
40.0
up
i 10.0
i -9.6
1 9.0 1
8.6 A
8.4 1
7.8
1 7.1
C-49 EC:! 15 90
Determine the exposed surface area , z�_ a�Z
of the mass and enter it on linea Exposed Mass Factor 1
and on line 14 of the checklist Area of Type 1:.•
adjacent to its' corresponding SC ' "" " "^"`- b
and R values. z
Exposed Mass Fac ,
Multiply the factor times the area Area of Type
and enter the result' on line a.
Do the same for other mass types.
on lines b through d. Exposed Mass Factor 3
Aran of Tvne 3 ...
Add lines a through d together and
enter the sum in the appropriate.
place on line e.
Enter the floor area *from "total
floor area" 1, of the Compliance
Checklist in the appropriate place
on line e. Perform the required
calculation and enter the result
as "Total Thermal Mass Capacity."
Using this total, find the corres-
ponding point value in Table
3-14e and enter it in the
"Points" column on line 14 of the
checklist.
Section 4 WALL must also be used
in conjunction with exterior mass
walls. There is no minimum R -
value requirement for mass walls.
Table 3-14e. Thermal Mass Points
I Total Mass Capacity I
1
I in, Btu/'F per sq ft I
Points I
.� of floor area
Points I
0 - 0.1 I
.2 - 0.4
.5 - 0.7;,
I o.8 - I
1-Z i
P I
1.2 - 1.4 I
_1-8
1.5 - 1.7 I
1.10
I 1.8 - 2.1 I
1-12 I
2.2 . - 2.5 I
1-14
I 2.6 - 2.8 I
1-16 I
I 2.9 - 3:1 I
1-18 I
3.2 - 3.5' i
1-20
i 3.6 - 4.0 I
1-22 I
.4.1 - 4.4 i
1-24
s � d
Exposed Mass Factor 4
Area of Type 4 .
(a1-bOa) Floor Total.
Area Mass
Capacity
Table 3-14e. (Continued)
I Total Mass -Capacity
I
1
I in Btu/'F
per sq ft I
Points I
of floor area
4.5 -
4.8' I
1-26 I
4.9 • -
5.2 I
1-28
I 5.3 -
.5.7 I..
1-30.
I. 5.8 -
6.2 I
1-32.
6.3 -
.6.7 I
.. 1-34
6.8 -
7.2 I
1-36.:
7.3 -..7.8
I .
1-38 I
I 7.9 -
8.4 I
1-40 I
I 8.5 -
9.2 I
.. 1-42. I
I 9.3 -
9.9 I
1-44. I
I 10.0 -
10.8 I
.. K46 I
10.9 -
11.8 11-48..
I 11.9 -
12.8 I
1-50 I
12.9 -
14.0.. 11-52.
I
I 14.1 -
15.2 I
.. 1-54 I
I' 15.3 -
16.6. ° 11-56
I
16.7 -
18.1 I
1-58
18.2 -19.7
(...
1-60•
I 19.8 -
21.2 11-62.
I
21.3 -
22.7 I
. 22.8
up :.
1-66
91
C-4 9 ECH 15
15. .GAS FURNACE WITHOUT REFRIGERATION
COOLING
Using the Seasonal Efficiency (SE)
shown on line 15'on the Compliance
Checklist, find the corresponding
point value for the gas furnace 'in
Table 3-15. Enter this value 'in
the "Points" column on line 15 of
the checklist. If no gas furnace
is proposed, enter zero (0) in the
"Points" column and write "NA" in
the place on line 15 marked (SE).
16. HEAT PUMP
Using the Energy Efficiency Ratio
(EER) shown on line 16 of the
Compliance Checklist, find the
corresponding point value for the
heat pump from Table 3-16. Enter
this value in the "Points" column
on line 16 of the checklist. If
no heat pump is proposed, enter
zero'(0) in the "Points" column
and write "NA" in the place. on
line 16 marked "EER."
The heat pump points are a total
of both cooling and heating bene-
fits associated with improved
EERs. The percent of the points
-associated with heating range
between 30 and 60 percent of the
total.
C-49 EOf' 15
92
Table 3-15. Cas Furnace Without
Refrigeration Coolie
Seasonal Efficiency I Points I
(SE), E I ...
I I I
I All I 0
Table 3-16. Heat Pump Points
J Energy Efficiency I
Points J
Ratio
�
(EER)
�
I
7.5 -
7.7
-5 I
I 7.8 -
7.9 I
-2 1
8.0 -
8.3 I
1-1 .
8.4 -
8.6 (
1-4
I 8.7 -
9.0
1-7 I
I 9.1 -
9.4 I
1-10
9.5 -
9.9
1-13
I 10.0 -
10.4 I
1-16 I
I 10.5 -
10.9
1-19
I 11.0 -
11.5 I
1-22 I
I 11.6 -
12.2 I
1-25 I .
I 12.3-12.9
1-28
13.0
I
up i
I
1-31 I
I
•
�'
17. CAS FURNACE WITH REFRIGERATION
_, ., .,.;__ .�.
.. ,...
COOLING
,
Using'the gas furnace SEand the
Table 3-17. Cas
Furnace with.. •-
refrigeration cooling_ SEER shown
:•-'•- Refrigeration Cooling
_
;
on line 17 ' of - 'the Compliance
7 Points'.. -
Checklist, find the corresponding
-
total point value from Table 3-17.
V Refrigeration
Cas Furnace SE x
...
Enter this value in the "Points"
I • Cooling
column on line 17 of the check-
I (SEER)
All
list. If no gas furnace with
refrigeration cooling is proposed,
enter zero (0) in the "Points"
8.0 - 8.2
0
column and write "NA" in the
8.3 - 8.6
1-3
places on line 17 marked "SE" and
8.7 - _9.0
F6
"SEER".
9.1 - 9.4•
1.9.
9.5 - 9.8
1
The points in this table represent
9.9 - 10.3
}15
: total of both .cooling and
10.4 - 10.9
1-
heating* benefits associated with
( 11.0 - 11.5
- 1-21
improved SEERs and SEs.
11.6 - 12.2 j
}24
12.3 - 12.9 I
#-27
13.0 - 13.8
1-30
13.9 up
f33 I
18. ACTIVE SOLAR SPACE HEATING WITH
GAS BACKUP
Using the Net ' Solar Fraction
(NSF) shown on line 18 of the
Compliance Checklist, find the
corresponding point value in
Table 3-18. Enter this value in
the "Points" column on line 18 of
the checklist. Attach the docu-
mentation justifying the NSF to
the checklist. If no active
solar.space heating is proposed,
enter zero (0) in the "Points"
column and write "NA" in the
place marked "NSF" on line 18.
19. ZONALLY CONTROLLED ELECTRIC
RESISTANCE SPACE HEATING
If zonally controlled electric
resistance space heating is pro-
posed, enter the points from
Table 3-1.9 in the "Points" column
-on line 19 of the Compliance -
Checklist. Single zone cgnvec-
tion, radiant, or forced -air
resistance heat must use the com-
puter performance method outlined
in Part 4 of this manual. This
does not include the supplemen-
tary electric resistance- heat
strip in heat pump systema.
C-49 ECM 15
Table 3-18. Active Solar Space
Heatin& with gas points
I Net Solar Fraction I Points I..,
I (NSF), x I I
I 0- 51 I 0 I
I 52 up I 1-2 I
I i I
Table 3-19. ' Zonally Controlled
Electric Resistance
Space Heating Points
Points for this measure will I
I be completed after the ' CEC I
has approved an Alternative
I Component Package for Resistance I
I Heat.
IA11 others (per building points)
1 800-899 1
0
20. SOLAR HATER HEATING WITH GAS
•BACKUP...
E
+22
1 +26
Using the floor area from "Total..
-
Floor Area" and the percent Net
+4 I
Solar Fraction. (NSF) , from line 20..
I +12
of the Compliance' Checklist, find ' '
'
the corresponding' point value In
•
.
Table 3-20.' If the building is
0 1
multifamily, multiply -the points
_
In the table by the number of
+14 (
dwelling units in the building and
1 +20
enter the product in the points
1,200-1,499 1
column on line 20 of the Check-
+3. I
list. If the building is single
+8 1
family, enter the table value in
+14
on line 20 of the checklist.
-
Attach the documentation justi-
'0 1
fying the NSF to the checklist.
'
If no solar water heating is
+9 I
proposed, enter zero (0) in the
I +13
"Points" column. and write "NA" in '
2,000-2,999 i
the place marked "NSF" on
+1 (
line -20.
+4 I
Net solar fraction is the total
+7 I.+9
system solar contribution
+10 I
Including storage tank losses,
0 1
piping heat losses, and pumping
+2 I
+4 I
+5 I
energy.
+7 I
able 3-20. Solar Nater Heating With Gas Backup
Points '
IMultifamil (per unit points)
I Floor Area I Net Solar Fraction (NSF), x
I per unit, I
• I ', ft2
I 10.9 110-19 120-29 130-39 140-49
t I I I I I
150-59 160-69 170-79 i
I I I i
I 600-799 I 0' I +3 I +7 I +10 I
+13 i +16 I +20 I +23 I
1 800-999 I 0 1.+3 i +5 I +8 j
+10 I +13 I +15 I +17 I
1 1,000-1,499 I 0 j +2 I +4 I +5 I'+7
I +9 I +11 I +13 I
11,500-1,999 I 0 I +1 I +3 I +4 I
+5 1 +7 i +8 I +9 I
IA11 others (per building points)
1 800-899 1
0
V +4 T_+9
T +13
1 +18 1
+22
1 +26
1 +30. 1
I 900-999 1.
0 I
+4 I
+8
I +12
1'+16 i
+20
1 +24
1 +28 I
11,000-1,199 1
0 1
+3 I
+7 I
+10 1
+14 (
+17
1 +20
1 +24 1
1,200-1,499 1
0 1
+3. I
+6 I
+8 1
+11 1
+14
1 +17
1 +20 1
1,50048999 I
'0 1
+2 I
+4 1
+6 I
+9 I
+11
I +13
1 +16 I
2,000-2,999 i
0 1
+1 (
+3 I
+4 I
+6 I
+7 I.+9
I
+10 I
13,000 and up 1
0 1
+1 1
+2 I
+4 I
+5 I
+6 1
+7 I
+8 1
95'
I
21. OTHER WATER HEATING SYSTEMS
Using the water heating system
shown on line 21 of the Compliance
Checklist, find the corresponding
point value in Table 3-21. Enter
this value in the "Points" column
of the checklist .on line 21.
POINT SYSTEM COMPLIANCE TOTAL
Sum the "Points" column of the
Compliance Checklist and enter
results. If the total is zero (0)
or greater, the proposed building
complies. If the total is less
than zero, levels of measures with
more positive points or less nega-
tive, points must be used. Be
certain to meet the requirements
of Part 1, Mandatory Features
and Devices. A building permit
cannot be issued until the Part l
requirements are also met.
..tip
Table 3-21. Other Water Heating Pts.
J System Type J
I �
Points J
I
I Gas Only I
I i
0 I
I•
Beat Pump I
0 I
I Solar with Electric I
I
I Resistance Backup- I
I
Meeting the Require-
ments in Part 2 (
0
Electric Resistance
Only J
-40
APPROXIMATE TOTAL CONSUMPTION
(Space Conditioning and Water Heating)
Z (a) kBtu/yr
total per ft4 space total floor area
conditioning budget .
Water Beating Budget'- (b) kBtu/yr
Total Budget (af-b) - (c) kBtu/yr
X 0.5 x - (d), kBtu/yr
points total floor area
Approximate Total Consumption (c -d) - (e) kstu/yr
6-4 9 ECH 15
96
14
i
PROJECT DATA SUMMARY
.0 oto S7zy4t1 10 ►J .
S I �Jc4,f—V— CAM t
project
system type
�\ H PAy 4-- Li OC i �i S
documentation author date
Form 1
checked by
date
SITE INFORMATION C 1 (�-)
17,37—
OF-
Heating Degree Day (from Appendix C) ..........................................................
HDD
1
day
Outside Design Temperature (from Appendix C or Appendix G) ............. .........
T ow
2 1
0 F
PROPOSED BUILDING ENVELOPE INFORMATION
10485-
048SGross
Gro"Floor Area if Low -Rise (from Calculations) ............................................
At
3
ft2
Gross Wall Area if High -Rise (from Calculations) ............................................
Aw
4.
( S
ft2
Designed Glazing Area (from Calculations).......................................................
Ag
5
ft2
Basic Glazing Area 116%of Line 3 if low-rise or 40%of Line.4 if high-rise)........
Abg
6 �- 3 g
ft2
Description of sembty
1 �4
'' 1
Glazing
U91
7
Btu/ (hr.ft2•oF)
Ug2
8
Btu/(hr•ft2.oF)
1
Ug3
9
0
Btu/ (hr.ft2•OF)
Wally«.� 1 ��
Uw1
10
Btu/(hr•ft2•oF)
Uw2
11
Btu/ (hr•0•0F)
Uw3
12
Btu/ (hr. ft2 • oF)
Ceiling/Roof TA
Uw4
Uc1
13
14 ` 0? -SR
Btu/ (hr•f12•OF)
Btu/ (hr•ft2 •oF)
Uc2
15
Btu/ Ihr•ft2.OF)
Floor
Uf1
16
Btu/ (hr. ft2 .OF)
U12
17
Btu/ (hr:ft2•OF)
PROPOSED SPACE HEATING SYSTEM (Chapter 7)
Gas Furnace
I
Building Design Hourly Heat Loss (from Form 2) .....................................
q
18 _.----1 (�-
t S 3
Stu/hr
Maximum Allowed Bonnet Capacity, 1.5 x Line 18 ......................................h......
19 �Y
Stulhr
Proposed Furnace
Make
Model Description
Rated Bonnet Capacity
Electric Resistance Alone
Electric Resistance Life Cycle Cost (from Form 5) ....................................
sLCC.
20
$
Lowest Life Cycle Cost of the Other Systems Ifrom Form 5) ...................
sLCCO"221
$
Non•Depletable Energy w/Electric Resistance Back -Up
Percentage of Annual Heat Loss Met by Non•Depletable Energy
Source(from Calculations)...............................................................................
22
%
Heat Pump with Electric Resistance Supplementary Heat
Percentage of Annual Heat Loss Met by Electric Resistance
(from Calculations)............................................................................................
23
%
PROPOSED WATER HEATING SYSTEM INFORMATION (Chapter 8)
Electric Ralstance Alone
Electric Resistance Life Cycle Cost Ifrom Form 6) .................................
wLCCa
24
$
Lowest Life Cycle Cost of the Other Systems (from Form 6) ...................
wLCCIo,,,,gt 25
$
PROPOSED SWIMMING POOL HEATING SYSTEM INFORMATION (Chapter
9)
Solar Life Cycle Cost (from Form 7)..............................................................
pLCCs
26
$
Natural Gas Life Cycle Cost (from Form 7) ......................................................
pLCCng
27
$
1. SLAB -ON -GROUND FLOOR
Locate the R -value of the proposed
slab -edge insulation and planned
depth of insulation from line 1 of
the Compliance Checklist, find the
corresponding point value in Table
3-1 and enter it on the appro-
priate line below. Enter the
length of insulated slab and total
length of slab perimeter from
line 1 on the appropriate lines
below. Subtract the insulated
length from the total length and
enter the difference on the line
below marked "length -'of uninsu-
lated." Perform the required
calculations for lines a and b'
below and add the results
together. Enter this sum on line
c below and also on line 1 in the
"Points" column of the checklist.
Note: If the proposed building
has both a slab and a raised
floor, multiply the value on line
c by the square footage area of
the slab floor and divide this by
the total floor area. Enter the
result of this calculation in the
"Points" column on line 1.
76
C-49 ECM 15
Table 3-1. Slab Floor Points
Insula-
I R -Value of
Insulation I
tion
Depth,
inches
1 0-2
1 3-4 1-5-6
1 71. 1
1
A
0' - 11
4I
-4.
-4
-4
12-15
-2
-1
j-1
16 - 19
-4
-1
-1
0
20 t
r
-4
a i
-1
r
0 (
I
0
i
Insulated Slab:
x -- a
points length total
insulated length
Uninsulated Slab:
x b
points length total
uninsulated length
a +- b - c
2. RAISED FLOOR
Using the R -value indicated on
line 2 of the. Compliance Check-
list, find the corresponding
point value from Table 3-2 and
enter it on the- appropriate part
of line a below. Enter on the
appropriate part of linea, the
area of insulated floor which is
over a crawl space or vented
basement from line 2 of the
checklist. Enter the total area
from "Total Floor Area" line of
the checklist on. the appropriate
part of lines a and b.' Subtract
the floor area over a vented
space from the total area and
enter the difference on the part
of line marked "area over a
vented space." Perform the
required calculations for lines a
and b, and add their' results
together. Enter this sum on
line c below and also in the
"Points" column on line 2 of the
.checklist.
If part of a raised floor is over
an open area, use Table 3-4a or
3-4b to determine its
corresponding points.
C-4 9 ECM .15
Table 3-2. Raised Floor•Points
R -Value of-'
j Insulation ' Points '
e up to 2 I -6 ('
2 - 5 ( -4
6 - 18 N�� -2
19 up ' " 0
Insulated Floor:
x a
points floor area total
over vented area
space
Uninsulated Floor:
x -- s b
points floor area total
over open area
space
77
a f b a c
3. CEILING
Using the R -value of the ceiling
insulation from line 3 of the
Compliance Checklist, find the
corresponding point value from
Table 3-3a' and enter it in the
"Points" column on line 3 of the
checklist.
or
Using the R -value of the ceiling
construction assembly from line 3
of the Compliance Checklist, find
the corresponding point value from
Table 3-3b and enter it in the
"Points" column on line 3 of the
checklist.
If -you have different levels of
R -values, you may calculate the
average of the R -values Weighted
by their respective areas or use
the the lowest of the R -values to
determine the points. If the
calculation is done, attach the
documentation to the checklist and
indicate the level of insulation.
and location of each on the
building plans. Be sure that this
average R -value equates to having
a minimum of R-19 insulation
uniformly distributed over the
ceiling.
78
C-4 9 EC.4 15
Table 3-3a. Ceiling Insulation Pts.
I R -Value of Insulation I Points I
I I I
19 I -10.
i 22 I -8
I 30 I -4 I
I '3 0
0
Table 3-3b. Ceiling Assembly Points
I R -Value of
Assembly I
I
(excluding
I
air films) I
I
Points
I
I 19 -.20
I
-12 I
I 21 -
22 I
-10 I
I 23 -
27 I
-8 I
I 28 -
31 I
-6 I
I 32 -
36 I
-4 I
37 -
38' I
-2-
2-
39
39-
51 I
0 I
I 52'-
75 I
1-2 I
I 76 up I
F4 I
.ter_
4 . WALL
Using' the R -value of the'insula-
tion.from line 4 of the Compliance
Checklist, find the corresponding
point value from' Table 3-4a and
enter it in the "Points" column on
line 4 of the checklist.
or
Using the R -value of the wall
construction assembly 'from line 4
of the Compliance Checklist, find
the corresponding point value from
Table 3-4b and enter it- in the
"Points" column on line 4 of the
checklist.
If you have different levels of
Insulation, follow the third para-
graph of the ceiling instructions,
except that the average R -value
must be equivalent to having a
minimum of R-11 insulation uni-
formly distributed over the Wall
if the wall has wood framing.
79
Table -3-4a. Wall Insulation Points
I R -Value of Insulation I Points. I
u -6
i 24 j 1-2 !
! 30 I 1-3 !
i I I
Table 3-4b. Wall Assembly Points
I R -Value of
Assembly I
I
I (excluding
I
air films) )
I
Points !
I
499 up I
1-10
! 70.0 -498.0 (
t8 !
I 37.0 -
69.0 I
f6 I
I 26.7 -
36.9 I
9 I
t 20.2 -
26.6 I
1-2 I
! 15.7 -
20.1 I
0 I
j 13.4 -
15.6 )
-2 I
11.3 -
13.3 I
-4
I 9.8-11.2
I
-6- I
I 8.8 -
9.7 I
-8 I
! 7.7 -
8.7• I
-10 !
7.0 -
7.6 I
-12
I 6.4 -
6.9 I
-14 I
5.8 -
6.3 j
-16 .
5.3 -
5.7 (
-18 I
4.9 -
5.2 I
-20 I
j 4.5 -
4.8 I
' -22 !
j 4.2-
4.4 j..
-24 j
j 3.9 -
4.1 ..•. j
-26 I
t 3.6 =
3.8 I
-28
j 3.4 -
3.5 !
-30 I
! 3.2 -
3.3 I
-32 t
I 3.0 -
3.1 I
-34 !
I 2.8 -
2.9 '
-36 I
I 2.7
I
-38 j
j 2.5 -
2.6 j
-40 I
2.4
I
-42 t
j 2.3
j
-44 I
j 2.2
i
-46 j
j 2.1
i
-48 j
j 2.0
I
-50 I
i 1.9
I
-52
C
5. GLAZING, NORTH -FACING
Using ... the - total ..-Table
3-5..,,
Northk-TatitS Glazing' -Pts:, G.I.
glazing percentage fr qm ,line ,S- df- -i
the Compliance Checkllat,•Jln:&Aht ? id,
T
;Total.,
Glazibg T� pe f. T;;
pe
corresponding point)cr,,VaJyeq ,:for
-1:1-1 of
f
b
each glazing type It*,! -iLe t,.,4sed i-.)
Floo r -1
*-
Dbl,J
t -:1 �Tlrp�,
J 0
Fl ,
U
(single, double., andlor'..tt.%tple)
.J. , Ariq4
-
I oil J;RUMI
P-66 1 0.42"
1 0). 4 V
1)-. 44 2.
1
Table 3-5. Enter these values
the appropriate linqs-:below-i POn-
%
X 10_ 1 0.651
11 ldbw�
1):65
1
the adjacent lines;-acenter. :-,thq,
square footage of cach ---�Slaziftg
:1i up tto
!J*4
1.4
--4
type indicated on the checklist:
1:2-
2
.3
-1-2
Next, enter the total. -,sq uatei footer
�-3 3; 4'
4--.8
0
�-
0
age of all north-faci-xig glazing'..'
el; :.3.5-
4.,9-- 16.0
341
-.4
Perform the required. it-a-1culation ,t
-:An.
I
'x-61
-6
and enter the resul-t-a theie.:- j
respective lines a and-,b.i .-..�Total..-.,,-
c -6.l-,1,.4
7.5-:8:t7
-9 -10. -� 1 , r8;
t o--7 I
.�7
lines a and b, and enter ,.the sum
-
8.8 9.9
01 -1-0-8
.'! :-I .
1
1 -10
1
on line c below ;and i.td ;,..the
.11 10.0-1-1.3
I 1 -15 i=12!
I -KO
"Points" column on line ,li:of -thd
.-I -11.4=12-5
:-17 11 -441
I 'H-1 2 1
1 -!14
checklist.
12.6-13.4
I :'-20. lk.-3:-261
4
13.5-15.0
-22 . It -.418!
Be sure to use the. to.taX,-.north7-
facing percentage instead -of, the .:i; -
individual percentaged. #orc:.each,::.-
type of glazing -ft .--'a .?given
,,
First ..Type (indicate.'
orientation.
Sngl, Dbl,
or T-r-pt)_L12,.; or.
X
-L. x a
points area total
.
first
area ftrit
-i a
Second - Type
(ftdicatetyr,
Sngl, Dbl,
or -Tr..pt)
X
b
points area I total Ca
for31
.
second
area
a I- b- c - a F b --' c - -
If there is no; tior-th7.fat-ing,gla.ztiig*,-�-li-.<-
enter 1-2 on line-•, e. and lint?. 5-,
80 ,O
C-4 9 ECM 15
6. CLAZING, EAST -FACING
' Using the total east -facing
Table 3-6.
East -Facing Glazin Pts.
glazing percentage from line 6 of
the Conpliaace.Checklist, find the
tal
1 To'".1,
Glazing Type
I.
corresponding'*point values for:
1 ;Z of''.
1'
1
each glazing type to be used
I: Floor
Sngl,
Dbl, I
Trpl,
(single, double, and/or triple) in
1 "Area;
I U= I
U B I
U- 1
Table 3-6. Enter these values on
I �'..
1 0.66- 1
0.42- 1
0.41'1
the appropriate lines below. 0n
1
i 1.10 1
0.65 1
down I
the' adjacent •lines," enter the
square footage of each glazing
1 up to l.5
1 0 1'
f4 1
A' 1
type indicated on the checklist.
1 1.6- 2.3
1 f-1 I'
1•2 1
f•3 1
Next, enter the total square foot-
I 2.4- 3.4
( -1 (
0 )
f•1` 1
age of all east -facing glazing.
13.5,5- 4.3
1 -3 1
-2 1
0
Perform the required calculation
1 ., .4-�
o---1-
4 1
-2 1
and enter !he results on their
1 . - .3
1 -8
-4 1
respective lines a and b. Total
I 6.4- 7.3
1 -11 (
-8 1
-6 1
lines a and b, and enter the sum
1 7.4- 8.4
1 -12 1
-10 1
-8 I
on line c below and in the
1 8.5- 9.4
1 -16 1
-12 1
-10 I
"Points" column on line 6 of the
1 9.5-10.4
1 -18'
-14 1
-12
checklist.
10.5-11.8
1 -22 1
-17 1
-15 I
1 11.9-13.5
1 =25 1
-20 (
-18 1
Be sure to use the total east -113.6-15.0
1 -29 1
-23 ,.
-20 1
facing percentage instead of the
1
1 1
I
1
individual percentages for. each
type of glazing in a given,
orientation.
First Type (indicate
Sngl, Dbl,
or Trpl)
x
s
=a
points area total
first area
Second Type (indicate
Sngl, Dbl,
or Trpl)
_
x
s
b
.
points area
total
second
area
a f•bc
If there is no
east -facing glazing,
enter 1-7 on line
c and
line 6.
C-4 9 ECH 15
81
C
7.. GLAZING. SOUTH -FACING
Using the total south -facing
glazing percentage from line 7 of
the Compliance Checklist, find the
corresponding point values- for
each glazing type to be used
(single, double, and/or triple) in
Table 3-7. Enter these values on
the appropriate lines below.- On
the adjacent lines, enter the
square footage of each glazing
type indicated on the checklist.
Next, enter the total square foot-
age of all south -facing glazing.
Perform the required calculation
and enter the results on their
respective lines a and b. Total
lines a and b, and enter the sum
on line c below and in the
"Points" column on line 7 of the
checklist.
Be sure to use the total south -
facing percentage instead of the
Individual percentages for each
type of glazing in a given
orientation.
C-49 cr_m 1_5
Table 3-7. South -Facing Glazing Pts
I Total
I Glazing Type
I
1 Z of
1
q
i
Floor
Sngl,
I Dbl, I
Trpl,
1" Area
I U-
I U- . 1
U. 1..
1 0.66-
1 0.42- 1
0.42
1
( 1.10
1 0.65 1
down 1
1 1.3 I F2 I 1
1-2 1
_
1 .4- 3.4
, 0 .1
0 1
—4
1 5.5- 7.3 1
-6 1
-4 (
-3 i
1 7.4- 9.1 (
-9 1
-6 I
-5 1
1 9.2-10.8.
-12 1
-8 i
-7 1
1 10.9-13.3 1
-16 1
-11 1
-10 I
13.4-15.7 1
-20 1
-14 1
-12 1
First Type (indicate
Sngl, Dbl, or Trpl)
x a
points area total
first area
Second Type (indicate
Sngl, Dbl, or Trpl)
xs b
points area total
second
second area
a I- b a c
If there is no south -facing glazing,
enter 1-3 on line c and line 7.-
82
A
S. GLAZING, WEST -FACING
Using the- total west -facing
glazing percentage from line 8. of -
the Compliance Checklist, find the
corresponding :'point , values for.
each glazing type' to be used
(single, double, and/or triple) in
Table 3-8. Enter these values on
the- appropriate lines below. On
the adjacent lines, enter the
square footage of each glazing
type indicated on the checklist.
Next, enter the total square foot-
age of all west -facing glazing.
Perform the required calculation
and enter the results on their
respective lines ' a and b.-.' Total
lines a and b, .and enter the sum
on line c below and in the
"Points" column on line 8 of the
checklist.
Be sure to use the total west -
facing percentage instead of the
Individual percentages for each
type of glazing in a given
orientation.
C-4 9 EC:! 15
11
Table 3-8. West -Facing Glazing Pts.
Total .I;
Glazing Type-.
I
X of
I
1
I Floor
Sngl,
I Dbl, I
Trpl,
I; Area
I U- '
I U- I
U- I
i
10.66-
10.42- 1
0.41 I _.
I
11.10
1 0.65 I
down i
up to 1.0 I
f8
I • F8 I
}8 I
_
2. -P.'9 1
}1I.
I
1-3
I 3.0- 3.4 1
-1
( 0 I
1.1 i
1 3.5- 4.2 i
-4
I -2 I
-l' i
4.3- 4.8 I
-7
I .-4 1
=3 1
1 4.9- 5.4 I
-9
1 -6 I
-5 1
5.5- 6.1 I
-12
1 -8 I
-7 I
I 6.2- 6.7 I
-14
I -10 I
-9 I
1 6.8- 7.3 1
-16 1
-12 1
-10 1
1 7.4- 7.9.1
-19 1
-14 1
-12 I
1 8.0- 8.5 1
-21 1
-16 1
-14 1
1 8.6- 9.1 1
-24 1
•-18 1
-16 1
I 9.2- 9.7 I
-26 i
-20 1
-18 I
I 9.8-10.3 I
-29 1,-2.2
1
-20 i.
1.10.4-11.3 1
-32 1
-25 1
-22 1
111.4-12.0 1
I I
-35 1
I
-28 1
I
-25 I
I
First Type (indicate
. Sngl, Dbl, or Trpl)
X - -a
points area total
first area
Second Type'(indicate
Sngl, Dbl, or Trpl)
X b
points area total
second area
a 1•b -c
If there is no west -facing glazing,
enter 1.10 on line c and line 8.
83
9. SKYLIGHTS
Using the ' total skylight glazing
percentage from line 9 of the
Compliance Checklist, find the
corresponding point value for each
glazing type to be used (single,
double, and/or triple) in Table
3-9. Enter these values on the
appropriate lines below. On the
adjacent lines, enter the square
footage of each glazing type indi-
cated on the checklist. Next,
enter the total square footage of
all skylight glazing. Perform the
required calculation and enter the
results on their respective lines
a and b. Total lines a and b, and
enter the sum on line c below and
in the "Points" column on line 9
of the checklist.
C-4 9 ECM 15
Table 3-9. Skylight Points
I TotalI
41
ting Type
1
I x of
I
I.
I Floor
S n g_ 1
1 Dbl, I
Trpl,
I Area
I
I U
I
1 0.66-.
1 0. 42- 10.41
1.10
10.65 I
down
I up to 1.0
I -2
I -2 I
-2
I 1.1- 1.6
I -4
I -4 (
-4 1
I 1.7- 2.3
I -7
) -6 I
-5. I
I 2.4- 2.9
I -9
I -8 I
-7 i
I 3.0- 3.4
I -10
1 -10 1
-9 I
I 3.5- 4.2
I -14
1 -12 I
-11 I
I 4.3- 4.8
1 -17
I -14 1
-13 i
I 4.9- 5.4
I -19
I -16 1
-15
I 5.5- 6.1
I -22
I -18 1
-17 I.
I 6.2- 6.7
I -24
I -20 1
-19 I
I 6.8- 7.3
I. -26
I -22 I
-20 i
I 7.4- 7.9
I -29
I -24 I
-22 I
I 8.0- 8.5
I -31
I -26 I
-24 I
I 8.6- 9.1
( -34
I -28 1
-26
I 9.2- 9.7
I -36
I -30 I
-28 i
I 9.8-10.3
I -39
I -32 1
-30 I
First Type (indicate
Sngl, Dbl, or Trpl)
x a
points area total
first area
Second Type (indicate
Sngl, Dbl, or Trpl)�:
x _ ab
points area total
second area
a I- b = c
If there is no skylight glazing,
enter.0 on line c and line 9.
84
W
10. SHADING COEFFICIENT
Locate the. percent of total
glazing to floor areas on lines 5,
69 7., 'and 8 of the Compliance'
Checklist and the Shading Coeffi-
cient (SC) for the shading device, -
for each orientation shown below..
Select Shading Coefficients that
are for devices used with single
glass only from Table 1 in Part 2;
ASHRAE HANDBOOK OF FUNDAMENTALS;
or manufacturers' data. Find the
corresponding point values from
Table 3-10 and enter it in the
"Points" column on the corres-
ponding lines 10a, 10b,_10c, and
10d of the checklist.
Please note this applies to all
glazing orientations except north.
East:
x
SC of SC of
glazing device 1
South:
X
SC of Net SC
device 2
X - x s ...
SC of SC of SC of Net SC
glazing device I device 2
West:
X
SC of SC of
glazing device 1
Skylight:
X 1
SC of Net SC_
device 2
If there is no glazing in an x x
orientation, enter zero (0) in the SC of _'§C of SC of Net SC
"Points" column on the corres- glazing device 1 device 2
ponding lines of the checklist.
Table 3-10. Shading Coefficient Points
SC by ! 1 SC by I
Orien- ! x Floor Area ! Orien-
tation i i tation
I East
1 0-
10.8-11.6-13.2-14.8-16.4-18.0-1 West
1
4.7 1
10.7
11.5
13.1
14.7
16.3 17.9
19.6
1
1
10 -.15!_'01
01
01
01
01
0!
01 01
0
0 -.15
X1.16 -
.32
1 0
1 -1
1 -1
1 -2
1.- -4
1 -5
16 - .30
1.33 -
.49
1 0
1 -1
1 -2
1 -4
1 -6 1 -8
1-10
.31 - .46
1.50 -
.68
1 0
1 -1
1 -3
1 -6
1 -9 1-12
1-15
1.47 - .62
1.69 -
.86
1 0
1 -2
1 -4
1 -8
1-12 1-16
1-20
1.63 - .79
1 .87
up
1 0
('-2
1 -5
1 -9
1-13 1-181-23
1 .80 up
South 10.1-1 1.6-1 3.2-1.4.8-1 6.4-1 8.0-1 .Skylight
I
011
11.5
1 3.1 1
4.7 1
6.3
1 7.9
1 9.6 1
1 671.�1-21-31-4l-5)
1
l 0 -.15
I -2
1 01
0 1
01
01
01'
0 1 0 -.15
1-10 1
X1.16 -
.30
1 0
1 �11
-1 I
-1
I -2 I
-3 J.16 -
.30
1.31 -
.46
1 0 1.
-1 1
-2 1
-3
1 -4 1
-5 1.31 -
.46
1.47 -
.62
1 0 1
-1 1
-3 1
-4 1
-6 1
-7 1.47 -
.62
1.63 -
.79
1 0 1
-2 1
.-4 1
-6 1
-8 1
-10 1.63 -
.79
1 .80
I
up
1 0 1
i I
-3 1
I
-5 1
I
-8 1
I
-11 1
I
-14 ! .80
l
up
85
C-49 ECM 15
X Floor Area
1 0- 10.8-11.6-13.2-14.8-16.4=18.0-1
10.7 11.5 13.1 14.7 16.3 17.9 19.6 1
! 0!
011
01
01
0!
01
! 0!
0
1 671.�1-21-31-4l-5)
1 -1
I -2
I -3
1 0
1 -1
1 -2 1,-4
1 -6
1 -8
1-10 1
l o
l -1
1 -3 1 -6
1 -9
1-12
1-15 1
1 0
1 -2
1 -4 1 -8
1-12
1-16
1-20 1
1 0 1
-2
1 -5 1-10
1-17
1-22
1-27 I
1 0- 10.4-10.8-11.6-12.4-13.2-14.0-1
10.3 10.7 11.5 12.3 13.1 13.9 14.8 1
10
1 0
1 0
1 0
1 0
1 0
1 0 1
1 0
1 0
1 -1
I -2
I -3
I -4
I -5 1
l o
l -1
1 -2
1 -4
1- 6
1- 8
1-10 1
1' 0
1 -1
1 -3
1 -6
V-9
1-12
1-15 1
1 0
1 -2
1 -4
1 -8
1-12
1-.16
1-20 1
1 0
1
1 -2
1
1 -5
1_
1-10
1
1-17
1
1-22
1_
1-27 1
1 1
5
11. HORIZONTAL SOUTH OVERHANG
Using the percent *of south glazing
area to floor area from line 7'
of the Compliance Checklist, find .
the corresponding point value in
Table 3-11. Enter it in I the
"Points" column on line 11 of the
checklist.
12. MOVABLE INSULATION
Using the percent of floor area
from line 12 of the Compliance
Checklist. find the corres-
ponding point value from Table
3-12. Enter this value in the
"Points" column on line 12 of the
checklist.
t-49 ECM 15
Table 3-11. Horizontal South
Overhang Points
South Glazing
j Length Out Area, x of Floor j
from Wall
I ft
0-6.3 j 6.4 up j
0 - 1.9 -2
X2.03, 3.9 ( 0 j 0 j
j .0 up ( Fh j 1-2 j
Table 3-12. Movable Insulation
.Points
j Moveable Insulation
j Area, Z of Floor j Points
All I 0
86
13. INFILTRATION CONTROL
o
Identify the proposed infiltration Table 3-13., Infiltration Control_
control features and -find the Features Points
corresponding point value in Table „
3-13. Enter the . point value in ._ Control Features.- ,Points
the "Points" column on line 13 of
the checklist. -�
~ Standard means caulking weather-
stripping, sealing, etc* as
described in Part 1, Mandatory
Features and Devices.
Tight means all the features in
the standard control plus gaskets
on electric outlet and switch
boxes in all exterior walls, poly-
ethelene sheets over the inside
face of all exterior walls, and a
mechanical ventilation system
capable of ventilating at the rate
of 0.7 air changes per hour for
the whole building with an air-
to-air heat exchanger. Other
measures may be used for the 0.6
infiltration rate if justified
with documentation and attached to
the checklist. However, the
mechanical ventilation with a heat
exchanger must still be used.
C-4 9 EC.4 15
Qftandard � � =4 � -•�
I air changes per hr
Tight to
� O �
0.6 air changes per hr
87
0
jl
14. THERMAL MASS
This section of the point system
applies to both exterior and
interior thermal mass building
elements because. *equivalent ther-
mal -mass factors have been deter-
mined.which are relative to their
performance. -Lines a, b, c, and d
at the end of this section* are
used to calculate the thermal -mass
capacity of different mass types:"
Determine the, heat capacity (HC)
and 'R -value of the mass element
from Table 3-14a or 3-14b, o_r if
the tables do not apply to the
proposed mass type, calculate HC
and R using the equation below.
Enter the two values in the appro-
priate place on line 14 of the
Compliance,Checklist.
C-49 EC:! 15
Table 3-14a. Masonry or Concrete
Wall HC9 Btu/'F-ft2
I Wall Weight, lb/ft2
I
i HC
I 10 - 13
2
I
Density,
I 19 - 23
4 _.
I I
I 24 - 28'
I 5 I
I 29-32
I 6 I
33 - 37
I ' 7
I 38 - 47
I 8 I
48 - 66
I 10
I 67 - 94
I 14 I .
i. 95 up
i 20 I
Table 3=14b. Solid Wood Wall HC and
88
HC and R Total Calculation:
C D t H
r t R total
Where:
C - Specific heat in Btu/lb-'F
D - density in lb/f t3
t - thickness in ft
r - resistance per foot 'in
hour-ft2-9F/Btu-f t
R -Value
Wood
Density,
lb/ft3
I Average
i
I Thick-
21 - 26
27 - 31
32 - 37`
I ness,
I Cedar
Pine
I Dg. Fir I
I inches
I Hem -Fir I
Hemlk.
I So.Pine
HC/R
HC/R
THC/R
1 3
I 2/4.3 I
3/3.6
I. 3/3.1 I
4
I 3/5.7
4/4.8
I 4/4.2 I
I 5
I 3/7.1 )
4/6.0
I 5/5.2
6
I 4/8.6. I
5/7.2
I 6/6.3
I 7
1 5/10.0 I
6/8.4
I 7/7.3 i
1 8- 9
1 6/11:4 i
7/9.6
I 8/8.3 I
110 - 11
7/14.3 I
9/11.9
1.11/10.4
I 12 up
J
8/17.1
I
11/14.3
113/12.5
I I
88
HC and R Total Calculation:
C D t H
r t R total
Where:
C - Specific heat in Btu/lb-'F
D - density in lb/f t3
t - thickness in ft
r - resistance per foot 'in
hour-ft2-9F/Btu-f t
Using the HC and R factors deter-
mined in the first step, determine
the equivalent mass capacity fac _
for from the appropriate. Table 3--
14c or 3-14d, and ''enter it -on
line a, following,, and line.. 14_of:, - �''= • • r.
checklist.
Table 3-14c. Mass Caeacity Factors for Interior Mass - -
I I R -Value of Interior :sass Element Excluding Air Films I
1 Heat Capacity,
i 0.3
j 0.4-
1 0.8-
1 1.3-
1.1.8-
1 2.6-
1 4.1-
1'7.6 1
I Btu/ft
-'F
1 Down
) 0.7
i 1.2
11.7
12.5
1
i 4.0
1 7.5
I Up I
-
1 1.5 -
1.7
1 2.8..1
2.8
12.8
12.7
( 2.6
12.4
1 2.3
11.9 I
j 1.8 .-
2.2
j 3.2
1 3.2
1 3.2
1 3.1
1 3.0
1 2.9
1 2.6
1 2.1-1 ..
j 2.3 -
2.7
1 3.7
1 3.7
1.3.6 )
3.5
13.3
i 3.0
1 2.8
j 2.2 1
2.8 =
3.2
i 4.3
j 4.3
1 4.1 1
3.8
1 3.6
13.3
( 3.0
i 2.3
i 3.3 -
3.7
1 4.8
1 4.7 14.4
1
4.1
1 3.8
1 3.4
1 3.1.
1 2.4 1
1 3.8 -
.4.2
i 5.2
1 5.0 1
4.7 1
4.3
J 4.1
1 3.6 1
3.2
1 2.5 1
1 4.3 -
4.7
1 5.6
1 5.3 1
5.0 1.4.6
1 4.3 1
3.7 1
3.3
1 2.6 1
1 4.8 -
5.5
15.9
1 5.6 1
5.2 1
4.8
1 4.4 1
3.8. 13.5
1 2.6 1
I 5.6.-
7.0
j 6.
j 6.1 1
5.5 15.0
1 4.7 1
4.1 .1
3.6
1 2.8 1
I =b 7.1--
9.0
1 7.3 1
6.4 1
5.9 1
5.3
1 5.0 1
4.4 1
4.0
1 3.1 1
1 9.1 -
i 12.1 -
12.0
17.0
) )
( 8.2 1
6.8 .)
7.1 i
6.1 1
6.4' i
5.6
5.8
j 5.2' j
15.5 15.1
4.7 j
1
4.3
4.7
j 3.4 j
14.0 1 `
17.1 -
22.5
1 8.5 1
7.6 1
6.9 1
6.4
1' 6.1 1
5.7 1
5.3
1 4.7 1
i 22.6 -
27.5
1 8.7 .)
7.9 i
7.2 16.8
1 6.4 1
6.0 1
5.8
1 5.2 1
{ 27.6 -
35.0
1 8.9 (
8.1 17.4
1
7.1
1 6.8 1
6.4. 1.6.1
1 5.7 1
1 35.1
up
1 9.2 1
8.3 1
7.8 (
7.4
( 7.2 1
7.0 •1
6.8
1 6.4 1
C-49 ECM 15 89
Table 3-14d. Mass Capacity Factors for Exterior Mass Wall
- \ I R -Value of Exterior Mass Assembly Excluding Air Films 1
I Beat cap ity,...I 2.0- I 2.5- i 3.0- I .3.5- I 4.0- I 4.5= I s.o- I
I Btu/f t, 'F\ I' 2.4 I 2.9 i 3.4 1 3.9 1 4.4 I 4.9 i 5.4 I
I 1.5 -
1.9
( 1.8
I 1.9
I T� 9 I
1.9 I
1.8
1 1.7
I 1.6 I
I 1.5 -
•1.
\ i 1.3.:1.
1.4 I
1.5
I 1.6
I 1.7
1 1.8
I . 1.8 )
I 2.0 -
2.4
1 1.6
1 1.7 I
1.8
I 1.9
1 2.0
I 2.1
1 2.2 I
I 2.5 -
2.9
N) 2.2
1 2.3 1
2.4
I 2.4
) 2.5
I 2.7
1 2.8 1
1 3.0 -
3.4
r 2.7
I 2.8 I
2.9
I 3.0
I 3.1
I 3.2 .1
3.3 )
3.5 -
3.9
I \3.2
1 3.3 I
3.4
1 3.5
I 3.6
I 3.6
I 3.7 i
4.0 -
4.4
3.7
1 3.8 )
3.9
1 4.0
) 4.1
1 4.2
) 4.2 I
i 4.5 -
4.9
i 4`�21
4.3 1
4.4
I 4.5
1 4.6
1 4: 6
1 4.6 1
1 5.0 -
5.4
1 4.7,•
I 4.8 I
4.9
I 5.0
I 5.1
( 5.1
I 5.1 I
I 5.5 -
5.9
I 6.0 i
5.3 I
3.4
I 5.5
1 5.6
I 5.6
1 5.6' I
I 6.0 -
6.9
I 7I 5.9 1
6.0
I 6.1
1 6.1
1 6.1
I 6:1 I
I 7.0 -
7.9
1 6.
1 6.9 I
7.0
i 7.1
I 7.1
( 7.1
1 6.9 1
i 8.0 -
8.9
1 7.
I' 8.0 1
8.l'
I 8.2
( 8.1
( 7.9
1 7.5 '1
9.0 -
9.9
1 8.8
19.1 I
9.2
I 9.2
( 9.0
1 8.4
1 7.8 1
1 10.0 -
11.9
1 9.7�9.8
i
9.9
1 9.8
1 9.5
1 8.8
I 8.2 I
12.0-13.9
I 14.0-19.9
111.6
11.5 111.1
7.6 I
110.5
I '9.8
I 9.1
)•8.5 1
I 14.0 -
19.9
( 13.6
I 3.0 111.8
8.0 I
i 10.9
1 10.0
) 9.4
I 8.7 I
20.0 -
29.9
115.1
1 N7 1
12.4
i 11.4
1 10.5
I 9.7
I 9.1 I
I 30._0-39.9
I 40.0
1 16.1
1 1 15 F13.2
-9.6 I
1 12.0
1 11.1
1 10.4
1 9.8 1
40.0
up
117.0
1 15. i
13.8 112.6
1 11.7
) 11.1
) 10.5 1
Beat Capacity,
1 5.5-
I 6.0-�
7.0- I
8.0- 1
10.0- (
15.0-
( 20.0 i
1 Btu/ft2-'F
1 5.9.
I 6.9 I
7.9 I
9:9 1
14.9 1
19.9
1 up 1
t
I 1.5 -
1.9
( 1.8
I 1.9
I T� 9 I
1.9 I
1.8
1 1.7
I 1.6 I
2.0 -
2.4
1 2.2
( 2.2
I 2• i
2.4 I
2.5
I 2.4
1 2.3 1
I -1.5 -
2.9
1 2.8
i 2.9
I 2. 1
2.9 I
2.9
( 2.8
1 2.5 1
I 3.0 -
3.4
1 3.3
1 3.3
I Y.-4 1
3.4 1
3.4
1 3.1
( 2.9 i
3.5 -
3.9
I 3.8
13 4
I 3.8
3.8 1
3.7
1 3.3
I 3.0 1
• 4.0 -
4.4
1 4.2
) 4.2
I 4.2;
4.1.1
3.9
I 3.5
1 3.1 )
4.5 -
4.9•
1 4.6
1 4.6
1 4.6 I
4.4 1
4.2
1 3.6
1 3.1 )
1 5.0 -
5.4
) 5.1
1 5.1
1 4.9 ��1
.7 1
4.3
1 3.8
1 3.2 1
5.5 -
5.9
( 5.6 •1
5.5
1 5.2
8 i
4.5 1
3.9
.3
1 3.3-
6.0
6.0 =
6.9
I 6.0 i
5.9
1 5.4 :I,
S. 1
4.6 1
4.0
1 3.3 1
1 7.0 -
7.9
I 6.7 I
6.4
1 5.7 I;
5. 1
4.8 1
4.1
i. 3.4 1
I 8.0 -
8.9
1 7.0 I
6.6
I 5.9 1
�a5.4 I
5.0 1
4.3
I 3.5 I
9.0 -
9.9
7.3 I
6.8 )
6.1 )
'S•.6
5.2 )
4.4 )
3.6 )
I 10.0 -
11.9
i 7.6 I
7.1 i
6.4 )
5,.8 .1
5..3 )
4.5 I
3.8
I 12.0 -
13.9
I 8.0 I
7.4 I
6.6
6:1 1
.5 1
4.8 i
4.0 I
I 14.0-19.9
I 8.2 I
7.6 I
6.8 1
63 I
S I
5.0 1
4".3 i
I 20.0 -
29.9
i 8.5 I
8.0 I
7.2 1
6.1% 1
6. i
5.6 I
5.0 I
30.0 -
39.9
I , 9.•2 1
8.8 1
8.1 1
7.6``I I
7.3 1
6.7 1
6.2
I 40.0
up
i 10.0 I
-9.6 I
9.0 I
8.6 11
8.4 I
7.8 i
7.1 I
C-4 9 ECM. 15 90
Determine the exposed surface area l , : �_ a
of the mass and enter it on line a Exposed Mass Factor 1.'
and on line 14 of the checklist Area of f Type
adjacent to Its corresponding RC " " "" -
and R values. X.
b
Exposed Mass Fac
Multiply the factor• times the area Area of Type 2,
and enter the result' on line a.
Do the same for other mass types. __ z c _.
on lines b through d. Exposed Mass Factor 3
Area of Type 3.
Add lines a through d together and ;
enter the sum in the appropriate. x '. d
place on line e. Exposed Mass Factor 4
Area of Type 4 .
Enter the floor area, from "total
floor area" 1. of the Compliance
Checklist in the appropriate place
on line e. Perform the required
calculation and enter the result
as "Total Thermal :lass Capacity."
Using tbis totals find the corres-
ponding point value in Table
3-14e and enter it in the
"Points" column on line 14 of the
checklist.
Section A WALLmust also be used
In conjunction with exterior mass
walls. There is no minimum R -
value requirement for mass walls.
Table 3-14e. Thermal Mass Points
I Total Mass Capacity i
I
I in, Btu/°F per sq ft I
Points I
of floor area
I
Points I
0 - 0.1 I
0
.2 - 0.4 i
.5 - 0.7
0.8 - .
1-2 I
1.2 - 1.4 I
1-8 I
I 1.5 - 1.7 I
1•10 I
1.8 - 2.1 I
1.12 i ..
2.2 . - 2.5 I
}14
2.6 - 2.8 I
}16
2.9 - 3:1 I
#.18
3.2 - 3.5 I
!•20
3.6 - 4.0 I
l•22
4.1 - 4.4 i
f24
7.8 I
(atb�cW) Floor Total
Area "lass '
Capacity
Table 3-14e. (Continued)
I Total Mass
Capacity I
1
I in Btu/°F
per sq ft I
Points I
I of floor
area
I 4.5 -
4.8':. I
X26 I
4.9' -
5.2 I
*28 I
I 5.3 -
.5.7 I..
1-30 I
I. 5.8 -
6.2- I
1-32. I
I 6.3 -
.6.7 I
... 04
6.8 -
7.2 I
1-36.: I
7.3 -
7.8 I
. 1-38
I 7.9 -
8.4 I
w0
I 8.5 -
9.2 I
.. w2 . I
9.3 -
9.9 I
#44 .
I 10.0 -
10.8 I
.. K46 I
I 10.9 -
11.8 I
K+8.. I
11.9 -
12.8. I
.. 1-50 I
I 12.9 -
14.0 . , I
1-52.
I 14.1 -
15.2 I
.. f•54 I
I' 15.3 -
16.6. ° 11-56
I
16.7 -
18.1 I
... M i
18.2 -19.7
I
... WO•
19.8 -
21.2 I
K2 . I
21.3 -
22.7 I
... K4
22.8
up :. I
I;
}66
I
91
C-4 9 EQ1 15
'r
15. .GAS FURNACE WITHOUT REFRIGERATION
COOLING
Using the Seasonal Efficiency (SE)
shown on line 15'on the Compliance
Checklist, find the corresponding
point value for the gas furnace in
Table 3-15. Enter this value'in
the "Points" column on line 15 of
the checklist. If no gas furnace
is proposed, enter zero (0) in the
"Points" column and write "NA" in
the place on line 15 marked (SE).
16. HEAT PUMP
Using the Energy Efficiency Ratio
(EER) shown on line 16 of the
Compliance Checklist, find the
corresponding point value for the
heat pump from Table 3-16. Enter
this value in the "Points" column
on line 16 of the checklist. If
no heat pump is proposed, enter
zero (0) in the "Points" column
and write "NA" in the place. on
line 16.marked "EER."
The heat pump points are a total
of both cooling and heating bene-
fits associated with improved
EERs. The percent of the points
associated with heating range
between 30 and 60 percent of the
total.
C-49 Edi • 15
92
Table 3-15. Gas Furnace Without
Refrigeration Coolie
I Seasonal Efficiency I Points I
(SE), S I ...
� � I
All 0
�• i i
Table 3-16. Heat Pump Points
Energy Efficiency I
Points I
I Ratio
I
(EER) I
I
I
I 7.5 -
7.7
-5 I
7.8 -
7.9 1
-2 I
8.0 -
8.3
1-1
I 8.4 -
8.6 i
1-4 I
I 8.7 -
9.0 I
1-7
I 9.1 -
9.4 I
1-10 I
I 9.5 -
9.9 i
1-13 I
I 10.0 -
10.4 I
1-16 I
I 10.5-10.9
(
1-1,9 I
I 11.0 -
11.5 I
1-22 I
I 11.6 -
12.2 (
1-25 I,
12.3 -
12.9 I
1-28 I
I 13.0
I
up I
I
1-31 I
�
17. GAS FURNACE WITH REFRIGERATION _ •- _..___..
COOLING
Using the gas furnace SEand the Table 3-17. Gas Furnace with...!-.
refrigeration co_6ling _SEER shown Refrigeration Cooling
on line 17 ' of the Compliance = Points*• �-
Checklist, find the corresponding -
total point value from Table 3-17.' V Refrigeration i Gas Furnace SE x _..
Enter this value in the "Points" Cooling
column on line 17 of the check- (SEER) All
list. If no gas furnace with i
refrigeration cooling is proposed,
enter zero (0) in the "Points" 8.0 - 8.2 0
column and write "NA" in the i 8.3 - 8.6 i 1.3 . ('
places on line 17 marked "SE" and 8.7 - _9.0 K
"SEER". 9.1 - 9.4 • 1-9.
I 9.5 - 9.8 1
The points in this table represent �•- 9.9 - 10.3 ( f15
a total of both cooling and 10.4 - 10.9 1-
heating* benefits associated with 11.0 - 11.5 - 1.21
improved SEERs and SEs. 11.6 - 12.2 f-24
12.3-12.9 1.27
13.0 - 13.8 00
13.9 up 1.33
' t
93
C-49 EC:! 15
c
I
18. ACTIVE SOLAR SPACE HEATING WITH
GAS BACKUP
Using the Net ' Solar Fraction
(NSF) shown on line 18 of the
Compliance Checklist, find the
corresponding point value in
Table 3-18. Enter this value in
the "Points" column on line 18 of
the checklist. Attach the docu-
mentation justifying the NSF to
the checklist. If no' active
solar .space heating is proposed,
enter zero (0) in the "Points"
column and write "NA" in the
place marked "NSF" on line 18.
19. ZONALLY CONTROLLED ELECTRIC
RESISTANCE SPACE HEATING
If zonally controlled electric
resistance space heating is pro-
posed, enter the points from
Table 3-19 in the "Points" column
-on line 19 of the 'Compliance
Checklist. Single zone cgnvec-
tion, radiant, or forced -air
resistance heat must use the com-
puter 'performance method outlined
in Part 4 of this manual. This
does not include the supplemen-
tary electric resistance heat
strip in heat pump systems.
94
C-49 ECM. l5 ,
Table 3-18. Active Solar Space
Heating with as points
I 'Net Solar Fraction I Points I_..
I (NSF), x I I
I I
I 0- Sl I 0 I
I 52 up 1-2 I
Table 3-19. Zonally Controlled
Electric Resistance
Space Heating Points
I Points for this measure will I
be completed after the CEC
I has approved an Alternative I
I Component Package for Resistance I
Heat.
f
1,
20. SOLAR WATER REATING WITH GAS
I
BACKUP _ •:• .
I +18
Using the floor area -from "Total
--
Floor Area" and the percent Net
I 900-999 i
Solar Fraction. (NSF)- from line 20..
of the Compliance' Checklist, find
+ the corresponding " point value in
;
Table 3-20. If the building is
1 +28 I
multifamily, multiply -the points
_
In the table by the number of
+7 1
dwelling units in the building and
+14 1
enter the product in the points
+20
column on line 20 of the Check-
11,200-1,499 1
list. If the building is single
+3. 1
family, enter the table value in
+8 I
on line 20 of the checklist.
-
Attach the documentation justi-
1 +20 I
fying the NSF to the checklist.
'
If no solar water 'heating is
+4 j
proposed, enter zero (0) in the
-'+9 j
"Points" column and write "NA" in '
+13
the place marked "NSF" on
1 28000-2,999 i
line 20.
+1 I
Net solar fraction is the total
+4 I
system solar contribution
+7 I.+9
including storage tank losses,
+10 1
piping heat losses, and pumping
0 I
energy.
+2 1
able 3-20. Solar Water 'Heating With Gas Backup
Points '
+6 1
IMultifamily (per unitpoints)
I
I Floor Area I Net Solar Fraction (NSF), x 1
per unit,
I f t2
1 1 0.9 I 10-19 1 20-29,1 30-39 f
I 1 I I I I
40-49 1 50-59 1 60-69 1 70-79 1
1 I I 1
600-799 1 0* 1 +3 1 +7' 1 +10 I
+13 I +16 ( +20 I +23 i
1 800-999 1 0 1.+3 1 +5 1 +8 I
+10 1 +13 1 +15 1 +17 I
1 1,000-1,499 j 0 j +2 j +4 f +5 1'+7
1 +9 1 +11 1 +13 1
1.500-1.999 i 0 I +1 ( +3 1 +4 I
+5 ' 1 +7 1 +8 1 +9 1
IAll others (per building points)
1 800-899 1
0 1
+4 1
+9
1 +13
I +18
1 +22
1 +26
I +30•
I 900-999 i
0 I
+4 j'
+8
I +12
1'+16
I +20
I +24
1 +28 I
11,000-1,199 i
0 1
+3 1
+7 1
+10 I
+14 1
+17 1
+20
I +24 1
11,200-1,499 1
0 I
+3. 1
+6 I
+8 I
+11 1
+14 1
+17
1 +20 I
1 l; 500-f ', 999 I
'0 j
+2 j
+4 j
+6 I
-'+9 j
+11 I
+13
j +16 I
1 28000-2,999 i
0 I
+1 I
+3 1
+4 I
+6 1
+7 I.+9
1
+10 1
1 3,000 and up 1
0 I
+1 I
+2 1
+4 1
+5 I
+6 1
+7 I
+8 1
95
►.^ 1S
21. OTHER WATER HEATING SYSTEMS
Using the water heating system
shown on line 21 of the Compliance
Checklist, find the corresponding
point value in Table 3-21. Enter
this value in the "Points" column
of the checklist .on line 21.
POINT SYSTEM COMPLIANCE TOTAL
Sum the "Points" column of the
Compliance Checklist and enter
results- If the total is zero (0)
or greater, the proposed building
complies. If the total is less
than zero, levels of measures with
more positive points or less nega-
tive points must be used. Be
certain to meet the requirements
of Part 1, Mandatory Features
and Devices. A building permit
cannot be issued until the Part l'
requirements are also met.
Table 3-21. Other Water Heating Pts.
j System Type I
Points J
Gas Only
�
0
I•
i
Heat Pump
0
Solar with Electric
Resistance Backup.
Meeting the Require-
ments in Part 2
0 i
Electric Resistance
Only
-40 i
APPROXIMATE TOTAL CONSUMPTION
(Space Conditioning and Water ideating)
x
total per ftl space
conditioning budget .
Water Beating Budget'- (b) kBtu/yr
total floor area
(a) kBtu/yr
Total Budget (afb) - (c) kBtu/yr
x 0.5 x = (d) kBtu/yr
points total floor area
Approximate Total Consumption (c -d) e) kBtu/yr
C-4 9 ECH 15
96
i