Electrical data, Application data (cont), Wshp sound control – Carrier AQUAZONE 50KQL-1PD User Manual

24

OCTAVE BAND SOUND PRESSURE LEVEL (Lp)

ASSOCIATED WITH NC CURVES

WSHP sound control

Analyzing the projected sound level in the conditioned
space caused by a WSHP unit is quite involved. The key is
to have good sound power ratings (Lw) in dB on the equip-
ment to determine the ductwork, ceiling and room sound
attenuation effect.

Console units

With console units, the fan and compressor are located
within the space, and only the casing design attenuates the
transmission of sound sources into the space. The designer
should carefully review the manufacturer’s acoustical data
when selecting console units and use lower fan speeds to
minimize space noise.

Operating limits

Environment
This equipment is designed for indoor installation ONLY.
Power supply
A voltage variation of ± 10% of nameplate utilization volt-
age is acceptable.

Starting conditions

The 50KQL unit will start and operate in an ambient tem-
perature of 50 F, with entering air temperature at 50 F,
with entering water temperature at 60 F, with both air and
water at the flow rates used in the ARI/ISO Standard
13256-1 rating test, for initial start-up in winter.
NOTE: These are not normal or continuous operating
conditions. Such a start-up should be used to bring the
building space up to occupancy temperature.

AIR LIMITS

WATER LIMITS

LEGEND

*Requires optional extended range insulation package when operating below the dew point.
NOTES:

1.

Minimum Air and Water conditions can only be used at ARI/ISO 13256-1 flow rates.

2.

The 50KQL units may have up two values at maximum or minimum with all other param-
eters at normal conditions.

Solenoid valves

In applications using variable flow pumping, solenoid
valves can be factory installed and operated from the con-
trol board in the Aquazone™ WSHP unit.

Freeze protection

Applications where systems are exposed to outdoor
temperatures below freezing (32 F) must be protected from
freezing. The most common method of protecting water
systems from freezing is adding glycol concentrations into
the water. Use design care when selecting both the type
and concentrations of glycol due to the following:
• Equipment and performance may suffer with high con-

centrations of glycol and other antifreeze solutions

• Loss of piping pressure may increase greatly, resulting

in higher pumping costs

• Higher mixture viscosity may cause excess corrosion

and wear on the entire system

• The water’s acidity may be greatly increased, promoting

corrosion

Glycol promotes galvanic corrosion in systems of dissimilar
metals. The result is corrosion of one metal by the other,
causing leaks.

Electrical data

LEGEND

NOISE

CRITERIA

CURVES

OCTAVE BAND SOUND PRESSURE LEVEL (Lp)

Frequency (Hz)

63

125

250

500

1000

2000

4000

8000

NC-15

49

36

26

17

17

14

12

11

NC-20

52

41

33

27

22

19

17

16

NC-25

54

45

38

31

27

24

22

21

NC-30

58

49

41

36

31

29

28

27

NC-35

61

53

45

40

36

34

33

32

NC-40

64

57

50

45

41

39

38

37

NC-45

67

61

54

49

46

44

43

42

NC-50

71

64

58

54

51

49

48

47

NC-55

74

68

63

58

56

54

53

52

NC-60

77

71

67

63

61

59

58

57

NC-65

80

75

71

68

66

64

63

62

50KQL

Cooling

Heating

Min. Ambient Air

50 F

50 F

Rated Ambient Air

80 F

66 F

Max. Ambient Air

100 F

86 F

Min. Entering Air

50 F

50 F

Rated Entering Air, db/wb

80/66 F

68 F

Max. Entering Air, db/wb

100/82 F

80 F

50KQL

Cooling

Heating

Min. Entering Water

30 F*

21 F*

Normal Entering Water

86 F

70 F

Max. Entering Water

110 F

90 F

db

—

Dry Bulb

wb —

Wet Bulb

50KQL

VOLTS-PHASE

(60 Hz)

VOLTAGE

COMPRESSOR

FAN MOTOR

FLA

TOTAL UNIT

FLA

MIN CIRCUIT

AMP

MAX FUSE/

HACR

Min

Max

RLA

LRA

07

115-1

104

127

7.1

46.5

0.50

7.6

9.3

15

208/230-1

187

253

3.7

19.0

0.33

4.0

5.0

15

265-1

239

291

2.8

16.0

0.35

3.1

3.8

15

09

115-1

104

127

9.0

46.5

1.30

10.3

12.5

20

208/230-1

187

253

4.7

23.0

0.50

5.2

6.3

15

265-1

239

291

3.8

16.0

0.50

4.3

5.3

15

12

115-1

104

127

10.6

63.0

1.30

11.9

14.6

25

208/230-1

187

253

6.1

29.0

0.50

6.6

8.1

15

265-1

239

291

4.8

21.6

0.50

5.3

6.5

15

15

208/230-1

187

253

7.0

33.2

1.10

8.1

9.8

15

265-1

239

291

5.4

29.0

1.00

6.4

7.8

15

19

208/230-1

187

253

7.7

38.0

1.10

8.8

10.7

15

265-1

239

291

5.8

29.0

1.00

6.8

8.2

15

FLA

— Full Load Amps

HACR — Heating, Air Conditioning and Refrigeration
LRA

— Locked Rotor Amps

RLA

— Rated Load Amps

Application data (cont)