Air Conditioning Load Calculation Presentation-15-09-2017.pdf
zemesguerra
121 views
48 slides
Jul 16, 2024
Slide 1 of 48
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
About This Presentation
Air Conditioning Load Calculation by PSME-Qatar Chapter
Slide Content
AIR CONDITIONING
LOAD CALCULATION
PSME-Qatar
Members Development
Program
LOAD CALCULATION
PSME-Qatar
Members Development
Program
OBJECTIVE
The Main Objective of this Presentation
is to Provide the Participants Working
Knowledge in the Field of Air
Conditioning System Load Calculation
for Residential Commercial and
Industrial Buildings
The Main Objective of this Presentation
is to Provide the Participants Working
Knowledge in the Field of Air
Conditioning System Load Calculation
for Residential Commercial and
Industrial Buildings
Principlesof Heat Transfer
Heat energy cannot be destroyed.
Heat always flows from a higher
temperature substance to a lower
temperature substance.
Heat can be transferred from one
substance to another.
Heat energy cannot be destroyed.
Heat always flows from a higher
temperature substance to a lower
temperature substance.
Heat can be transferred from one
substance to another.
Methods of Heat Transfer
convectionconvection
radiationradiation
hot
water
hot
water
conductionconduction
cool aircool air
convectionconvection
radiationradiation
hot
water
hot
water
conductionconduction
cool aircool air
Conduction, Convection & Radiation
Measuring Heat Quantity
60°F 61°F
15°C
16°C
1 Btu
1 kcal
[4.19 kJ]
1 lb
Water
1 kg
Water
60°F 61°F
15°C
16°C
1 Btu
1 kcal
[4.19 kJ]
1 lb
Water
1 kg
Water
What is BTU?
BTU refers to British Thermal Unit.
Unit of Heat Energy in Imperial System
or I-P System.
1 BTU is the amount of Heat energy
required to raise the temperature of 1
lbwater by 1⁰F.
BTU refers to British Thermal Unit.
Unit of Heat Energy in Imperial System
or I-P System.
1 BTU is the amount of Heat energy
required to raise the temperature of 1
lbwater by 1⁰F.
WHAT IS AIR
CONDITIONING ?
Air Conditioning is …..
“The Science and Practice of Creating a
Controlled Climate in the Indoor Living or
Working Areas for Comfort of Human Beings
or Animals or for the Proper Performance of
Some Industrial or Scientific Process.”
CONDITIONING ?
Air Conditioning is …..
“The Science and Practice of Creating a
Controlled Climate in the Indoor Living or
Working Areas for Comfort of Human Beings
or Animals or for the Proper Performance of
Some Industrial or Scientific Process.”
Human Comfort
Conditions at which most people are likely to feel
comfortable
most of the time.
Also called as Thermal Comfort.
Temperature: 78⁰F (Summer) –68⁰F(Winter).
Relative Humidity: 30 %–60%.
Conditions at which most people are likely to feel
comfortable
most of the time.
Also called as Thermal Comfort.
Temperature: 78⁰F (Summer) –68⁰F(Winter).
Relative Humidity: 30 %–60%.
Indoor Design Conditions
Dry-bulb Temperature
Humidity Ratio
80°F
[26.7°C]
80°F
[26.7°C]
70°F
[21.2°C]
70°F
[21.2°C]
comfort zone
AA
Dry-bulb Temperature
Humidity Ratio
80°F
[26.7°C]
80°F
[26.7°C]
70°F
[21.2°C]
70°F
[21.2°C]
comfort zone
AA
Factors Affecting Human
Comfort
Dry-bulb temperature
Humidity
Air movement
Fresh air
Clean air
Noise level
Adequate lighting
Proper furniture and
work surfaces
Comfort
Dry-bulb temperature
Humidity
Air movement
Fresh air
Clean air
Noise level
Adequate lighting
Proper furniture and
work surfaces
Provide information for Equipment
Selection and HVAC System Design.
Provide data for evaluation of
optimum possibilities for Load
Reduction.
Permit analysis of partial loads as
required for system design,
operation and cont
rol.
PURPOSE OF LOAD
CALCULATION
.
Provide information for Equipment
Selection and HVAC System Design.
Provide data for evaluation of
optimum possibilities for Load
Reduction.
Permit analysis of partial loads as
required for system design,
operation and cont
rol.
PURPOSE OF LOAD
CALCULATION
.
Heat Gain Or Loss
Cooling Load Or Heating Load
Heat Extraction Or Heat
Addition
PRINCIPLE OF COOLING
LOADS
Heat Gain Or Loss
Cooling Load Or Heating Load
Heat Extraction Or Heat
Addition
PRINCIPLE OF COOLING
LOADS
Or Instantaneous Rate Of Heat Gain
Is The Rate Of Which Heat Enters Or
Generated Within A Space At A Given
Instant Of Time.
HEAT GAIN:
Or Instantaneous Rate Of Heat Gain
Is The Rate Of Which Heat Enters Or
Generated Within A Space At A Given
Instant Of Time.
HEAT GAIN:
TYPES OF HEAT GAIN
SENSIBLE HEAT GAIN
LATENT HEAT GAIN
SENSIBLE HEAT GAIN
LATENT HEAT GAIN
Sensible Vs Latent Heat
60°F
[15.6°C]
212°F
[100°C]
212°F
[100°C]
212°F
[100°C]
Sensible Heat
Latent Heat
60°F
[15.6°C]
212°F
[100°C]
212°F
[100°C]
212°F
[100°C]
Sensible Heat
Latent Heat
WHAT IS SPACE
COOLING LOAD ?
Rate of the Heat Removal from the
Conditioned Space that has to be
Maintained in Order to Provide the
Desired Inside Condition.
COOLING LOAD ?
Rate of the Heat Removal from the
Conditioned Space that has to be
Maintained in Order to Provide the
Desired Inside Condition.
Cooling Load Components
roof
lights
equipment
floor
exterior
wall
glass solar
glass
conduction
infiltration
people
partition
wall
roof
lights
equipment
floor
exterior
wall
glass solar
glass
conduction
infiltration
people
partition
wall
COOLING LOADS
CATEGORY
External Loads (Due external Factors)
Internal Loads
Infiltration and Ventilation Loads
CATEGORY
External Loads (Due external Factors)
Internal Loads
Infiltration and Ventilation Loads
EXTERNAL LOADS:
Combined Effect of Outdoor Air Temperature and the
Solar Radiation that causes Heat Flow through Roof
and External Walls.
Temperature of Adjoining Spaces that Causes Heat
Conduction into Conditioned Space thru Interior
Partitions, Ceilings, Floors & Windows.
Solar Heat Gain by Direct or Indirect Solar Radiation
Thru Windows or other Fenestration Materials.
Combined Effect of Outdoor Air Temperature and the
Solar Radiation that causes Heat Flow through Roof
and External Walls.
Temperature of Adjoining Spaces that Causes Heat
Conduction into Conditioned Space thru Interior
Partitions, Ceilings, Floors & Windows.
Solar Heat Gain by Direct or Indirect Solar Radiation
Thru Windows or other Fenestration Materials.
INTERNAL LOADS
Lights
People
Internal Equipment ( such as, Electrical,
Gas Or Steam appliances, Electrical
machines and other miscellaneous
source of heat & steam.
Lights
People
Internal Equipment ( such as, Electrical,
Gas Or Steam appliances, Electrical
machines and other miscellaneous
source of heat & steam.
Infiltration and Ventilation
Ventilation Is Supplied to Meet the
Required Air Purity and Odor Standards.
Infiltration Arises From Controlled or
Uncontrolled Leakage Around Doors and
Windows or Through Walls.
Ventilation Is Supplied to Meet the
Required Air Purity and Odor Standards.
Infiltration Arises From Controlled or
Uncontrolled Leakage Around Doors and
Windows or Through Walls.
AIR CONDITIONING
COOLING LOAD
CALCULATION
PROCEDURES
COOLING LOAD
CALCULATION
PROCEDURES
STEPS INVOLVE IN A/C LOAD
CALCULATION:
DATA GATHERING
SELECTION OF INDOOR & OUTDOOR DESIGN
CONDITIONS.
CALCULATION OF HEAT TRANSFER COFFICIENTS
CALCULATION OF SPACE COOLING LOAD
PSYCHROMETRIC ANALYSIS
CALCULATION:
DATA GATHERING
SELECTION OF INDOOR & OUTDOOR DESIGN
CONDITIONS.
CALCULATION OF HEAT TRANSFER COFFICIENTS
CALCULATION OF SPACE COOLING LOAD
PSYCHROMETRIC ANALYSIS
DATA GATHERING
Orientation and Dimension of Building
Components.
Construction Materials for Roof, Walls, Ceiling,
Interior Partitions, Floors and Fenestration.
Size and Use of Space To Be Conditioned.
Surrounding Conditions Outdoors and in
Adjoining Spaces,
Orientation and Dimension of Building
Components.
Construction Materials for Roof, Walls, Ceiling,
Interior Partitions, Floors and Fenestration.
Size and Use of Space To Be Conditioned.
Surrounding Conditions Outdoors and in
Adjoining Spaces,
DESIGN CONDITION
Outdoor Design Condition
Indoor Design Condition
Latitude
Design Month & Design Hour
Daily Range
Outdoor Design Condition
Indoor Design Condition
Latitude
Design Month & Design Hour
Daily Range
External Cooling Load
Conduction : For Roof, Walls and Glass.
q = U x A x CLTD
Solar : Glass
q = A x SC x SHGF x CLF
Conduction : For Roof, Walls and Glass.
q = U x A x CLTD
Solar : Glass
q = A x SC x SHGF x CLF
U -VALUE
4.2.3 CMU Wall
ELEMENT CONSTRUCTION RESISTANCE, ft
2
-hr-
F/Btu
1 Outside Surface (15 mph wind) 0.17
2 Cement Plaster, 19mm 0.15
3 CMU, 200mm 1.11
4 Non-Reflective Air Space 0.91
5 Batt Insulation, 50mm 7.08
6 Gypsum Board, 15mm 0.534
7 Inside Surface (still air) 0.68
TOTAL 10.634
U-Value = 1 / 10.634 = 0.094 Btu/ ft
2
-hr-F
4.2.3 CMU Wall
ELEMENT CONSTRUCTION RESISTANCE, ft
2
-hr-
F/Btu
1 Outside Surface (15 mph wind) 0.17
2 Cement Plaster, 19mm 0.15
3 CMU, 200mm 1.11
4 Non-Reflective Air Space 0.91
5 Batt Insulation, 50mm 7.08
6 Gypsum Board, 15mm 0.534
7 Inside Surface (still air) 0.68
TOTAL 10.634
U-Value = 1 / 10.634 = 0.094 Btu/ ft
2
-hr-F
CLTD-COOLING LOAD TEMPERATURE DIFFERENCE FOR
ROOF, WALLS & GLASS
A: FOR ROOF
CLTDcorr.= (CLTD+LM) x K + (78-Tr) x (Toa -85) x f
WHERE:
CLTD = Cooling Load Temp. Diff., refer to ASHRAE GRP=158 Table 3.8.
LM= CLTD correction for Latitude-Month Correction, Table 3.12.
K= Color Adjustment Factor
Tr= Inside Room temperature
Toa= Average Outside Temperature.
F= Adjustment Factor.
ROOF, WALLS & GLASS
A: FOR ROOF
CLTDcorr.= (CLTD+LM) x K + (78-Tr) x (Toa -85) x f
WHERE:
CLTD = Cooling Load Temp. Diff., refer to ASHRAE GRP=158 Table 3.8.
LM= CLTD correction for Latitude-Month Correction, Table 3.12.
K= Color Adjustment Factor
Tr= Inside Room temperature
Toa= Average Outside Temperature.
F= Adjustment Factor.
B: FOR WALLS:
CLTDcorr.= (CLTD+LM) x K + (78-Tr) x (Toa -85)
WHERE:CLTD = Cooling Load Temp. Diff., refer to ASHRAE GRP=158
Table 3.10.
LM=
CLTD correction for Latitude-Month Correction, Table 3.12.
K= Color Adjustment Factor
Tr= Inside Room temperature
Toa= Average Outside Temperature.
CLTDcorr.= (CLTD+LM) x K + (78-Tr) x (Toa -85)
WHERE:CLTD = Cooling Load Temp. Diff., refer to ASHRAE GRP=158
Table 3.10.
LM=
CLTD correction for Latitude-Month Correction, Table 3.12.
K= Color Adjustment Factor
Tr= Inside Room temperature
Toa= Average Outside Temperature.
GLASS SOLAR LOAD
q = A x SC x SHGF x CLF
WHERE
:
A = NET GLASS AREA
SC = SHADING COEFFICIENT
SHGF = MAX. SOLAR HEAT GAIN FACTOR
CLF = COOLING LOAD FACTOR
q = A x SC x SHGF x CLF
WHERE
:
A = NET GLASS AREA
SC = SHADING COEFFICIENT
SHGF = MAX. SOLAR HEAT GAIN FACTOR
CLF = COOLING LOAD FACTOR
INTERNAL LOAD
1. PEOPLE
q = ( qs per person x no. of person ) +
( ql per person x no. of people )
where :
q= Total Heat Gain from People, Btu/hr)
qs= Sensible heat gain per person, BTU/Hr.
ql= Latent Heat Gain per person, BTU/hr.
1. PEOPLE
q = ( qs per person x no. of person ) +
( ql per person x no. of people )
where :
q= Total Heat Gain from People, Btu/hr)
qs= Sensible heat gain per person, BTU/Hr.
ql= Latent Heat Gain per person, BTU/hr.
TABLE 3 OF ASHRAE 1997 FUNDAMENTALS
RATE OF HEAT GAIN FOR OCCUPANT
DEGREE OF
ACTIVITY
TYPE OF
SPACE
SENSIBLE HEAT,
Btu/h
LATENT HEAT,
Btu/h
Seated at rest Theater 245 105
Seated, very light work Offices 245 155
Moderately active work Offices 250 200
Walking, standing Offices 250 250
Sedentary work Dining Areas 275 275
Light bench work Shops 275 475
Light machine work Shops 375 625
Heavy work Shops 580 870
Athletics Gymnasium 710 1090
Note: Tabulated values above are based on room temp. at 75F DB. For 80F DB room temp., the total heat remains
t He same, but the sensible heat values should be decreased by 20%, and the latent heat values increased accordingly.
RATE OF HEAT GAIN FOR OCCUPANT
DEGREE OF
ACTIVITY
TYPE OF
SPACE
SENSIBLE HEAT,
Btu/h
LATENT HEAT,
Btu/h
Seated at rest Theater 245 105
Seated, very light work Offices 245 155
Moderately active work Offices 250 200
Walking, standing Offices 250 250
Sedentary work Dining Areas 275 275
Light bench work Shops 275 475
Light machine work Shops 375 625
Heavy work Shops 580 870
Athletics Gymnasium 710 1090
Note: Tabulated values above are based on room temp. at 75F DB. For 80F DB room temp., the total heat remains
t He same, but the sensible heat values should be decreased by 20%, and the latent heat values increased accordingly.
2.0 LIGHTING :
QS = 3.41 X W X BF
WHERE:
QS -SENSIBLE COOLING LOAD, BTU/HR.
W -TOTAL LAMP WATTAGE, WATTS.
BF -BALLAST FACTOR.
QS = 3.41 X W X BF
WHERE:
QS -SENSIBLE COOLING LOAD, BTU/HR.
W -TOTAL LAMP WATTAGE, WATTS.
BF -BALLAST FACTOR.
Average Values of Ballast Factor for
Flourescent Lights
LAMP WATTAGE NO. OF LAMP /FIXTURE BALLAST FACTOR
35 - 40 1 1.30
35 - 40 2 1.20
60 - 75 1 1.30
60 - 75 2 1.20
110 1 1.25
110 2 1.07
160 1 1.15
160 2 1.08
185 - 215 1 1.08
215 2 1.06
Note: For incandescent lighting where ballast is not required, no factor should be added. Unoccupied diversity
factor shall be used only when fraction of lights are switched on during the unoccupied equipment operation
period.
Flourescent Lights
LAMP WATTAGE NO. OF LAMP /FIXTURE BALLAST FACTOR
35 - 40 1 1.30
35 - 40 2 1.20
60 - 75 1 1.30
60 - 75 2 1.20
110 1 1.25
110 2 1.07
160 1 1.15
160 2 1.08
185 - 215 1 1.08
215 2 1.06
Note: For incandescent lighting where ballast is not required, no factor should be added. Unoccupied diversity
factor shall be used only when fraction of lights are switched on during the unoccupied equipment operation
period.
EQUIPMENT LOAD
POWER EQUIPMENT
OFFICE EQUIPMENT
RESTAURANT EQUIPMENT
HOSPITAL & LABORATORY EQUIPMENT
POWER EQUIPMENT
OFFICE EQUIPMENT
RESTAURANT EQUIPMENT
HOSPITAL & LABORATORY EQUIPMENT
POWER EQUIPMENT
QS = ( A OR B OR C ) X NO. OF MOTORS
.
R e fe rrin g to A S H R A E 1 99 7 F u n d a m e n ta ls T a b le 4 - H e a t G a in fro m T yp ic a l E le ctric M o to rs
a re a s fo llo w s:
M O T O R N A M E -
P L A T E O R R A T E D
H P
M O T O R
T Y P E
(A) M O T O R IN ,
D R IV E N E Q U IP .
IN , B tu /h r
(B) M O T O R O U T ,
D R IV E N E Q U IP .
IN , B tu /h r
(C) M O T O R IN , D R IV E N
E Q U IP . O U T , B tu /h r
0 .0 5 S h a d e d P o le 3 6 0 1 3 0 2 4 0
0 .0 8 S h a d e d P o le 5 8 0 2 0 0 3 8 0
S h a d e d P o le 9 0 0 3 2 0 5 9 0
0 .1 6 S h a d e d P o le 1 1 6 0 4 0 0 7 6 0
0 .2 5 S p lit P h a s e 1 1 8 0 6 4 0 5 4 0
0 .3 3 S p lit P h a s e 1 5 0 0 8 4 0 6 6 0
0 .5 0 S p lit P h a s e 2 1 2 0 1 2 7 0 8 5 0
0 .7 5 3 -P h a s e 2 6 5 0 1 9 0 0 7 4 0
1 3 -P h a s e 3 3 9 0 2 5 5 0 8 5 0
1 .5 3 -P h a s e 4 9 6 0 3 8 2 0 1 1 4 0
2 3 -P h a s e 6 4 4 0 5 0 9 0 1 3 5 0
3 3 -P h a s e 9 4 3 0 7 6 4 0 1 7 9 0
5 3 -P h a s e 1 5 5 0 0 1 2 7 0 0 2 7 9 0
7 .5 3 -P h a s e 2 2 7 0 0 1 9 1 0 0 3 6 4 0
1 0 3 - P h a s e 2 9 9 0 0 2 4 5 0 0 4 4 9 0
1 5 3 - P h a s e 4 4 4 0 0 3 8 2 0 0 6 2 1 0
2 0 3 - P h a s e 5 8 5 0 0 5 0 9 0 0 7 6 1 0
2 5 3 - P h a s e 7 2 3 0 0 6 3 6 0 0 8 6 8 0
3 0 3 - P h a s e 8 5 7 0 0 7 6 3 0 0 9 4 4 0
4 0 3 - P h a s e 1 1 4 0 0 0 1 0 2 0 0 0 1 2 6 0 0
5 0 3 - P h a s e 1 4 3 0 0 0 1 2 7 0 0 0 1 5 7 0 0
QS = ( A OR B OR C ) X NO. OF MOTORS
.
R e fe rrin g to A S H R A E 1 99 7 F u n d a m e n ta ls T a b le 4 - H e a t G a in fro m T yp ic a l E le ctric M o to rs
a re a s fo llo w s:
M O T O R N A M E -
P L A T E O R R A T E D
H P
M O T O R
T Y P E
(A) M O T O R IN ,
D R IV E N E Q U IP .
IN , B tu /h r
(B) M O T O R O U T ,
D R IV E N E Q U IP .
IN , B tu /h r
(C) M O T O R IN , D R IV E N
E Q U IP . O U T , B tu /h r
0 .0 5 S h a d e d P o le 3 6 0 1 3 0 2 4 0
0 .0 8 S h a d e d P o le 5 8 0 2 0 0 3 8 0
S h a d e d P o le 9 0 0 3 2 0 5 9 0
0 .1 6 S h a d e d P o le 1 1 6 0 4 0 0 7 6 0
0 .2 5 S p lit P h a s e 1 1 8 0 6 4 0 5 4 0
0 .3 3 S p lit P h a s e 1 5 0 0 8 4 0 6 6 0
0 .5 0 S p lit P h a s e 2 1 2 0 1 2 7 0 8 5 0
0 .7 5 3 -P h a s e 2 6 5 0 1 9 0 0 7 4 0
1 3 -P h a s e 3 3 9 0 2 5 5 0 8 5 0
1 .5 3 -P h a s e 4 9 6 0 3 8 2 0 1 1 4 0
2 3 -P h a s e 6 4 4 0 5 0 9 0 1 3 5 0
3 3 -P h a s e 9 4 3 0 7 6 4 0 1 7 9 0
5 3 -P h a s e 1 5 5 0 0 1 2 7 0 0 2 7 9 0
7 .5 3 -P h a s e 2 2 7 0 0 1 9 1 0 0 3 6 4 0
1 0 3 - P h a s e 2 9 9 0 0 2 4 5 0 0 4 4 9 0
1 5 3 - P h a s e 4 4 4 0 0 3 8 2 0 0 6 2 1 0
2 0 3 - P h a s e 5 8 5 0 0 5 0 9 0 0 7 6 1 0
2 5 3 - P h a s e 7 2 3 0 0 6 3 6 0 0 8 6 8 0
3 0 3 - P h a s e 8 5 7 0 0 7 6 3 0 0 9 4 4 0
4 0 3 - P h a s e 1 1 4 0 0 0 1 0 2 0 0 0 1 2 6 0 0
5 0 3 - P h a s e 1 4 3 0 0 0 1 2 7 0 0 0 1 5 7 0 0
OFFICE EQUIPMENT
QS = (A) X NO. OF EQUIPMENT
Recommended Rate of Heat Gain from Selected Office Equipment are listed below:
APPLIANCES SIZE
(A) RATE OF HEAT GAIN, Btu/h
(Sensible)
Personal Computer 16 - 640 Kbytes 300 - 1800
Plotter - 214
Laser Printer 8 pages/min. 1025
Letter Quality Printer 30 - 45 char/min 1000
Blue Printer - 3930 - 42700
Printer Terminal - 270 - 600
Copier, large 30 - 67 copies/min. 5800 - 22500
Copier, small 6 - 30 copies/min. 1570 - 5800
Microfilm Reader/Printer - 3920
Electric Typewriter - 230
Coffee Maker 10 cups 3580 sens; 1540 latent
Microwave Oven 28 L 1360
Paper Shredder - 680 - 8250
Water Cooler 30 L/h 5970
Note: Other office equipment not listed above, heat gain should then be referred to Table 9A of ASHRAE 1997
Fundamentals, Chapter 28 and/or manufacturers manual.
QS = (A) X NO. OF EQUIPMENT
Recommended Rate of Heat Gain from Selected Office Equipment are listed below:
APPLIANCES SIZE
(A) RATE OF HEAT GAIN, Btu/h
(Sensible)
Personal Computer 16 - 640 Kbytes 300 - 1800
Plotter - 214
Laser Printer 8 pages/min. 1025
Letter Quality Printer 30 - 45 char/min 1000
Blue Printer - 3930 - 42700
Printer Terminal - 270 - 600
Copier, large 30 - 67 copies/min. 5800 - 22500
Copier, small 6 - 30 copies/min. 1570 - 5800
Microfilm Reader/Printer - 3920
Electric Typewriter - 230
Coffee Maker 10 cups 3580 sens; 1540 latent
Microwave Oven 28 L 1360
Paper Shredder - 680 - 8250
Water Cooler 30 L/h 5970
Note: Other office equipment not listed above, heat gain should then be referred to Table 9A of ASHRAE 1997
Fundamentals, Chapter 28 and/or manufacturers manual.
RESTAURANT EQUIPMENT
QE = ( QS + QL ) X NO. OF EQUIPMENT
3 .5 .1R e c o m m e n d e d R a te o f H e a t G a in fro m R e s ta u r a n t E q u ip m e n t ( w ith o u t h o o d ) L o c a te d in
C o n d itio n e d A re a s a re lis te d b e lo w :
R A T E O F H E A T G A I N , B t u / h
A P P L IA N C E S S I Z E S E N S I B L E L A T E N T
B le n d e r , p e r q u a r t o f c a p a c i t y 1 - 4 q t . 1 8 0 9 5
C o f f e e B r e w e r 1 2 c u p s /2 b r n r s 3 7 5 0 1 9 1 0
I c e M a k e r , la r g e 2 2 0 lb / d a y 9 3 2 0 -
I c e M a k e r , s m a l l 1 1 0 lb / d a y 6 4 1 0 -
R e f r i g e r a t o r , la r g e 2 5 - 7 4 f t
3
6 6 5 -
R e f r i g e r a t o r , s m a ll 6 - 2 5 f t
3
3 0 0 -
T o a s te r , la r g e p o p - u p 1 0 s lic e s 9 5 9 0 8 5 0 0
T o a s te r , s m a ll p o p - u p 4 s lic e s 4 4 7 0 3 9 6 0
H o t P la t e 2 b u r n e r s 1 1 7 0 0 3 4 7 0
3 .5 .2 R e c o m m e n d e d R a te o f H e a t G a in fro m R e s ta u r a n t E q u ip m e n t ( e x h a u s t h o o d
r e q u ir e d ) L o c a te d in A ir - C o n d itio n e d A re a s a re lis te d b e lo w :
R A T E O F H E A T G A I N , B t u / h
A P P L IA N C E S
S I Z E S E N S I B L E L A T E N T
F r y e r , d e e p f a t 3 5 - 5 0 lb . o il 1 2 0 0 -
F r y e r , p r e s s u r iz e d 1 3 - 3 3 lb . 5 9 -
G r i d d le /g r ill 2 . 5 - 4 . 5 f t
2
4 0 0 -
H o t P la t e 2 b u r n e r s 3 4 1 0 -
R a n g e 2 - 1 0 b u r n e r s 6 5 9 0 -
N o t e : F o r a d d it io n a l o f f ic e e q u i p m e n t n o t li s t e d a b o v e , h e a t g a in s h o u ld t h e n b e r e f e r r e d t o T a b le 8 o f
A S H R A E 1 9 9 7 F u n d a m e n t a ls , C h a p t e r 2 8 a n d / o r m a n u f a c t u r e r s m a n u a l .
QE = ( QS + QL ) X NO. OF EQUIPMENT
3 .5 .1R e c o m m e n d e d R a te o f H e a t G a in fro m R e s ta u r a n t E q u ip m e n t ( w ith o u t h o o d ) L o c a te d in
C o n d itio n e d A re a s a re lis te d b e lo w :
R A T E O F H E A T G A I N , B t u / h
A P P L IA N C E S S I Z E S E N S I B L E L A T E N T
B le n d e r , p e r q u a r t o f c a p a c i t y 1 - 4 q t . 1 8 0 9 5
C o f f e e B r e w e r 1 2 c u p s /2 b r n r s 3 7 5 0 1 9 1 0
I c e M a k e r , la r g e 2 2 0 lb / d a y 9 3 2 0 -
I c e M a k e r , s m a l l 1 1 0 lb / d a y 6 4 1 0 -
R e f r i g e r a t o r , la r g e 2 5 - 7 4 f t
3
6 6 5 -
R e f r i g e r a t o r , s m a ll 6 - 2 5 f t
3
3 0 0 -
T o a s te r , la r g e p o p - u p 1 0 s lic e s 9 5 9 0 8 5 0 0
T o a s te r , s m a ll p o p - u p 4 s lic e s 4 4 7 0 3 9 6 0
H o t P la t e 2 b u r n e r s 1 1 7 0 0 3 4 7 0
3 .5 .2 R e c o m m e n d e d R a te o f H e a t G a in fro m R e s ta u r a n t E q u ip m e n t ( e x h a u s t h o o d
r e q u ir e d ) L o c a te d in A ir - C o n d itio n e d A re a s a re lis te d b e lo w :
R A T E O F H E A T G A I N , B t u / h
A P P L IA N C E S
S I Z E S E N S I B L E L A T E N T
F r y e r , d e e p f a t 3 5 - 5 0 lb . o il 1 2 0 0 -
F r y e r , p r e s s u r iz e d 1 3 - 3 3 lb . 5 9 -
G r i d d le /g r ill 2 . 5 - 4 . 5 f t
2
4 0 0 -
H o t P la t e 2 b u r n e r s 3 4 1 0 -
R a n g e 2 - 1 0 b u r n e r s 6 5 9 0 -
N o t e : F o r a d d it io n a l o f f ic e e q u i p m e n t n o t li s t e d a b o v e , h e a t g a in s h o u ld t h e n b e r e f e r r e d t o T a b le 8 o f
A S H R A E 1 9 9 7 F u n d a m e n t a ls , C h a p t e r 2 8 a n d / o r m a n u f a c t u r e r s m a n u a l .
VENTILATION LOAD
VENTILATION STANDARD IS AVAILABLE IN
THE FOLLOWING STANDARD:
1. TABLE 5.3 ASHRAE GRP 158
2. ASHRAE 62.1, Table 6.1
VENTILATION STANDARD IS AVAILABLE IN
THE FOLLOWING STANDARD:
1. TABLE 5.3 ASHRAE GRP 158
2. ASHRAE 62.1, Table 6.1
VENTILATION LOADS
qs = 1.1 x CFMoa x ( toa -tm )
where :
CFM oa = outdoor air
toa= Outdoor Dry Bulb Temp.
tm= room dry bulb temp.
qs = 1.1 x CFMoa x ( toa -tm )
where :
CFM oa = outdoor air
toa= Outdoor Dry Bulb Temp.
tm= room dry bulb temp.
VENTILATION LOAD
LATENT LOAD:
ql = 0.7 x CFM oa x ( Woa -Wrm)
Where:
( Woa-Wrm) = Humidity Ratio Difference
between Outdoor Air and indoor air. Use
Psychrometric Chart.
LATENT LOAD:
ql = 0.7 x CFM oa x ( Woa -Wrm)
Where:
( Woa-Wrm) = Humidity Ratio Difference
between Outdoor Air and indoor air. Use
Psychrometric Chart.
COOLING LOAD
SUMMARY
SUMMARY
Summary
Sensible
Load
latent
load
Conduction through roof, walls,
windows, and skylights
Solar radiation through windows, skylights
Conduction through ceiling, interior
partition walls, and floor
People
Lights
Equipment/ Appliances
Infiltration
Ventilation
System Heat Gains
space
load
coil
load
cooling load components
Sensible
Load
latent
load
Conduction through roof, walls,
windows, and skylights
Solar radiation through windows, skylights
Conduction through ceiling, interior
partition walls, and floor
People
Lights
Equipment/ Appliances
Infiltration
Ventilation
System Heat Gains
space
load
coil
load
cooling load components
THANK YOU VERY
MUCH FOR YOUR
ATTENTION
LET’S PROCEED TO
ACTUAL
CALCULATION
MUCH FOR YOUR
ATTENTION
LET’S PROCEED TO
ACTUAL
CALCULATION
Design Consideration:
Location: Doha, Qatar
Latitude: 25.25 N, 51.57 E
Outdoor Design Condition:
115 degF (46 deg. C), 79 degF (26 degC).
Daily Range: 32 degF.
Design Month & Peak Time: August / 4:00PM
Location: Doha, Qatar
Latitude: 25.25 N, 51.57 E
Outdoor Design Condition:
115 degF (46 deg. C), 79 degF (26 degC).
Daily Range: 32 degF.
Design Month & Peak Time: August / 4:00PM
SAMPLE VILLA:
COOLING & HEATING LOAD
ESTIMATE SHEET
ESTIMATE SHEET
Tags
Categories
TechnologyDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 121
- Slides 48
- Age 510 days
Related Slideshows
11
8-top-ai-courses-for-customer-support-representatives-in-2025.pptx
JeroenErne2
60 views
10
7-essential-ai-courses-for-call-center-supervisors-in-2025.pptx
JeroenErne2
56 views
13
25-essential-ai-courses-for-user-support-specialists-in-2025.pptx
JeroenErne2
43 views
11
8-essential-ai-courses-for-insurance-customer-service-representatives-in-2025.pptx
JeroenErne2
42 views
21
Know for Certain
DaveSinNM
26 views
17
PPT OPD LES 3ertt4t4tqqqe23e3e3rq2qq232.pptx
novasedanayoga46
30 views