HVAC and refrigeration systems consume a lot of electricity in Nepalese Industries. Therefore, improving the efficiency of these systems can lead to huge cost savings. This presentation was held in the context of energy auditor training in Nepal in 2012 that was supported GIZ/NEEP Programme.
2. INTRODUCTION
Refrigeration deals with the transfer of
heat from a low temperature level at the
heat source to a high temperature level at
the heat sink.
Air conditioning for comfort
Refrigeration for process
3. TON OF REFRIGERATION
1 ton of refrigeration
= 3024 kCal/hr heat rejected.
The cooling effect produced is quantified as
tons of refrigeration.
5. VAPOUR – ABSORPTION REFRIGERATION SYSTEM
EVAPORATOR
CONDENSOR GENERATOR
ABSORBER
STRONG
SOLUTION
WEAK
SOLUTION
COOLING
WATER IN
HOT WATER OUT
THROTTLING
VALVE
Regulating
Valve
Waste Heat/
Direct Fired
Heat load In
6. PERFORMANCE ASSESSMENT
The specific power consumption kW/TR is a useful indicator of the
performance of refrigeration system. By messing refrigeration duty
performed in TR and the Kilo Watt inputs measured, kW/TR is used
as a reference energy performance indicator.
The refrigeration TR is assessed as TR
= Q Cp (Ti – To) / 3024
Where TR is cooling TR duty
Q is mass flow rate of coolant in kg/hr
Cp is coolant specific heat in kCal /kg / 0C
Ti is inlet. Temperature of coolant to evaporator (chiller) in 0C.
To is outlet temperature of coolant from evaporator (chiller) in 0C.
8. EFFECT OF VARIATION IN EVAPORATOR TEMPERATURE
ON COMPRESSOR POWER CONSUMPTION
Evaporator
Temperature
(0
C)
Refrigeration
Capacity
(tons)
Specific
Power
Consumption
Increase in
kW/ton (%)
5.0 67.58 0.81 -
0.0 56.07 0.94 16.0
-5.0 45.98 1.08 33.0
-10.0 37.20 1.25 54.0
-20.0 23.12 1.67 106.0
A 10C raise in evaporator temperature can help to save
almost 3 % on power consumption.
9. EFFECT OF VARIATION IN CONDENSER TEMPERATURE
ON COMPRESSOR POWER CONSUMPTION
Condensing
Temperature
(0
C)
Refrigeration
Capacity
(tons)
Specific
Power
Consumption
Increase in
kW/TR
(%)
26.7 31.5 1.17 -
35.0 21.4 1.27 8.5
40.0 20.0 1.41 20.5
10. EFFECT OF POOR MAINTENANCE
ON COMPRESSOR POWER CONSUMPTION
Condition
Evap.
Temp
(0
C)
Cond.
Temp
(0
C)
Refrigeration
Capacity
(tons)
Specific
Power
Consumption
(kW/ton)
Increase
in
kW/Ton
(%)
Normal 7.2 40.5 17.0 0.69 -
Dirty
condenser
7.2 46.1 15.6 0.84 20.4
Dirty
evaporator
1.7 40.5 13.8 0.82 18.3
Dirty
condenser
and
evaporator
1.7 46.1 12.7 0.96 38.7
11. ENERGY SAVINGS OPPORTUNITIES
Cold Insulation
Process Heat Loads Minimisation
Flow optimization and Heat transfer area
increase to accept higher temperature
coolant
Avoiding wastages like heat gains, loss of
chilled water, idle flows
Frequent cleaning / de-scaling of all heat
exchangers
12. AT THE REFRIGERATION PLANT AREA
Ensure adequacy of chilled water and cooling water
flows, avoidance of bypass flows by valving off the idle
equipment.
Minimize part load operations by matching loads and
plant capacity on line, adopting variable speed drives
for varying process load.
Ensure efforts to continuously optimize condenser and
evaporator parameters for minimizing specific energy
consumption and maximizing capacity.
Adopt VAR system where economics permit as a non
CFC solution
13. SELECT THE RIGHT COOLING MEDIUM
Type of cooling Power Consumption
1. Cooling tower water 0.1 KW/TR
2. Chilled water System at 10oC 0.7 KW/TR
3. Brine System at -20oC 1.8 KW/TR
Order of preference
Cooling water ChilledWater Brine
14. ENERGY SAVINGS IN REFRIGERATION SYSTEMS
There are two broad ways by which energy
can be conserved
1.By decreasing the load
2.By optimising the refrigeration system
15. CALCULATING THE OPERATING LOAD OF A
CHILLER PLANT
Refrigeration
plant
Hot well
12OC
Cold well
8OC
Process
Chilled water flow – 100 m3/hr
Refrigeration TR - 100,000 kg/hr x 1 x 4
3000
- 133.33 TR
Efficiency-
Power drawn by compressor, kW
TR
m Cp
120
133.33
- = 0.9
DT
16. EFFICIENT OPERATION & MAINTENANCE
The suction temperature, pressure delivery pressure of
compressors should be kept at optimum level
Ensure all indicators are working properly
Keep record of oil consumption
Condensers
Remove scale and algae and adopt suitable water treatment
Give periodic purging of non-condensable gases
Lesser the water temperature more the COP
Routine defrosting of Cooling coils
Stop condenser water pump when compressor not working
5OC rise in condensing temperature increases 10 % power consumption
5OC rise in evaporating temperature increases 10 % power consumption
17. ENERGY SAVING MEASURES IN REFRIGERATION
Look for process modifications to reduce the cooling load
Use cooling water to remove the maximum heat before using chilled water
Provide VSD for condenser water pumps
to vary the cooling water flow to maintain 4oC difference across the condensers
Avoid primary pump operation
Normally two pumps are operation
(Chilled water supply pump from cold well and return water pump from hot well)
Modify to operate only return water pump
Provide VSD for efficient part load operation
Explore ‘Ice-bank’ system for Maximum demand reduction
Explore application of vapour absorption with cost economics
Replace old systems with modern energy efficient systems
18. COLD INSULATION
Thumb rules for cold Insulation
Chilled water pipe insulation (Provide 2 to 3 inch thickness)
Duct insulation (Provide 1 to 2 inch thickness)
Suction line refrigerant pipe insulation(Provide 2 to3 inch thickness)
Difference in
temperature between
ambient and surface
Heat ingress
kCal/m2/hr
Exposed area per
tonne of
refrigeration
5 35 86
10 73 41
15 113 27
20 154 19
Basis:
Ambient temperature - 35OC, emissivity – 0.8, still air conditions
Allowable heat ingress – 10 –15 Kcal/m2/hr
Editor's Notes
As mentioned earlier, we can see the difference in power consumption between various cooling mediums. The lower the temperature to be attained the higher is the power consumption.
Energy savings in refrigeration needs application of common sense. The first thing to look for is in the process. There may be a stream which is cooled from 50 O C to 25 O C. In this case the stream can first be cooled by cooling water upto say 30 O C and further cooling can be effected by chilled water. Chilled water is costlier than cooling water. There could also be process streams to be cooled and other stream requiring heating. In such cases proces to process heat exchange can reduce chilled water requirements as well as steam. Similarly in an air conditioning application, minimising/ eliminating unwanted loads can bring down energy consumption. Once load reduction options have been explored, we can move to refrigeration plant to try and optimise the system.