42
NSKW INSTALLATION MANUAL
Check One
Start up/Check-out for new installation
T
Troubleshooting Problem:___________________________________
T
1. FLOW RATE IN L/s (SOURCE SIDE HEAT EXCHANGER)
Water In Pressure:
a.______
kPa
Water Out Pressure:
b.______
kPa
Pressure Drop = a - b
c.______
kPa
Convert Pressure Drop to Flow Rate
(refer to
Pressure Drop
table)
d.______
L/s
2. TEMPERATURE RISE OR DROP ACROSS SOURCE SIDE HEAT EXCHANGER
COOLING
HEATING
Water In Temperature:
e.______
°C
e.______
°C
Water Out Temperature:
f. ______
°C
f. ______
°C
Temperature Difference:
g.______
°C
g.______
°C
3. TEMPERATURE RISE OR DROP ACROSS LOAD SIDE HEAT EXCHANGER
COOLING
HEATING
Water In Temperature:
h.______
°C
h.______
°C
Water Out Temperature:
i. ______
°C
i. ______
°C
Temperature Difference:
j. ______
°C
j. ______
°C
4. HEAT OF REJECTION (HR) / HEAT OF EXTRACTION (HE) CALCULATION
HR or HE = Flow Rate x Temperature Difference x Brine Factor*
d. (above) x g. (above) x 4.1 for Methanol or Environol, 4.2 for water*
Heat of Extraction (Heating Mode) =
kW/hr
Heat of Rejection (Cooling Mode) =
kW/hr
Compare results to Capacity Data Tables
Note: Steps 5 through 8 need only be completed if a problem is suspected
5. WATTS
COOLING
COOLING
HEATING
HYDRONIC
Volts:
m._____
VOLTS
m.______
VOLTS
m. ______
VOLTS
Total Amps (Comp. + Fan):
n. _____
AMPS
n. ______
AMPS
n. ______
AMPS
Watts = m. x n. x 0.85
o. _____
WATTS
o. ______
WATTS
o. ______
WATTS
6. CAPACITY
Cooling Capacity = HR. - o.
p . _____
kW/hr
Heating Capacity= HE. + o.
p . _____
kW/hr
7. EFFICIENCY
Cooling EER = p. / o.
q . _____
COP
Heating COP = p. / o.
q . _____
COP
8. SUPERHEAT (S.H.) / SUBCOOLING (S.C.)
COOLING
HEATING
HYDRONIC
Suction Pressure:
r. ______
kPa
r. ______
kPa
r. ______
kPa
Suction Saturation Temperature:
s. ______
°C
s. ______
°C
s. ______
°C
Suction Line Temperature:
t. ______
°C
t. ______
°C
t. ______
°C
Superheat = t. - s.
u. _____
°C
u. ______
°C
u. ______
°C
Head Pressure:
v. ______
kPa
v. ______
kPa
v. ______
kPa
High Pressure Saturation Temp.:
w. _____
°C
w. _____
°C
w. _____
°C
Liquid Line Temperature*:
x. ______
°C
x. ______
°C
x. ______
°C
Subcooling = w. - x.
y. ______
°C
y. ______
°C
y. ______
°C
* Note: Liquid line is between the source heat exchanger and the expansion valve in the cooling mode;
between the load heat exchanger and the expansion valve in the heating mode.
Company Name: _________________________________
Technician Name: ________________________________
Model No: ______________________________________
Owner’s Name: __________________________________
Installation Address: ______________________________
Company Phone No: ______________________________
Date: __________________________________________
Serial No:_______________________________________
Open or Closed Loop: _____________________________
Installation Date: _________________________________
Startup and Troubleshooting Form