Worksheets - sample selection # 2, Preliminary data given, Location at reno, nevada, 95 – Bally Refrigerated Boxes BVC Generation C – Direct Drive Air-Cooled – Vertical Air User Manual

JOB REF:

WORKSHEETS - SAMPLE SELECTION # 2

Preliminary Data Given:

1. Location at Reno, Nevada, 95

o

F design ambient and 4,000 feet elevation.

2. Multiple circuits required with evaporating temperatures, condensing temperatures, compressor capacities and
refrigerant types as listed below.

Use WORKSHEET-MULTIPLE CIRCUITS (P. 27) to complete selection of condenser.

1. SYSTEM DATA REQUIREMENTS

CONDENSER DESIGN AMBIENT TEMP =

(AT )

o

F

ALTITUDE =

SEA LEVEL

or

FEET

FACTOR =

(See P. 2)

CIRCUIT INFORMATION

CIRC # 1

CIRC # 2

CIRC # 3

CIRC # 4

OPEN
HERMETIC

EVAP. TEMP

o

F =

CONDENSING TEMP =
COMPR CAP. (MBH) =
REFRIGERANT =
TD =
(Cond Temp - Amb.)

2. THR (Total Heat of Rejection) CALCULATION

COMPR CAPACITY (MBH)

X HRf

X ALTf

X REFf

= THR (MBH)

/ TD

= CL

CIRC # 1

X

X

X

=

/

=

CIRC # 2

X

X

X

=

/

=

CIRC # 3

X

X

X

=

/

=

CIRC # 4

X

X

X

=

/

=

TOTAL THR Capacity (MBH / 1

o

F TD) =

3. CONDENSER SELECTION

Refer to the R22 CAPACITY selection (P. 2) and select a condenser at the 1

o

F TD that will closely match the above Total THR Capacity

(MBH/ 1

o

F TD).

COND. MODEL #

For the model selected, refer to P. 2 and enter...
Max no. of Feeds

=

(A)

MBH @ 1

o

F TD per feed =

(B)

calculate the number of feeds required for each circuit.
CL (MBH / 1

o

F TD)

/ (B) value

= NF number of feeds required (round off to nearest whole #)

CIRC # 1

/

=

CIRC # 2

/

=

CIRC # 3

/

=

CIRC # 4

/

=

Total number of feeds required NF =
(must not exceed value (A))
If number of feeds required exceeds number of feeds available then select the next larger size
condenser model that can handle the number and repeat above process.

4. ACTUAL CONDENSING TEMP (per circuit) CALCULATION

First calculate the ATD (Actual TD) as follows:

{THR (from sec. 2) / NF value} / value (B) = ATD (Actual Temperature Difference)

CIRC # 1

{

/

}

/

=

CIRC # 2

{

/

}

/

=

CIRC # 3

{

/

}

/

=

CIRC # 4

{

/

}

/

=

To find the Actual Condensing Temperature (ACT) just add the Actual Temperature Difference (ATD) to the design ambient (AT)

ATD

+

AT

=

ACT

CIRC # 1

+

=

o

F

CIRC # 2

+

=

o

F

CIRC # 3

+

=

o

F

CIRC # 4

+

=

o

F

- 29 -

95

TC2000

4,000

1.14

13

25

4.6

31.5

-10

105

4.6

404A

10

-20

105

31.5

404A

10

+20

110

13

22

15

1.33

1.38

1.48

1.55

1.14

1.14

1.14

1.14

1

1

1.03

1.03

19.71

39.33

7.99

57.33

15

15

10

10

1.314

2.622

.799

5.733

10.468

BVC1A12022

24

.447

1.314

2.622

.799

5.733

.447

.447

.447

.447

(2.93) 3

(5.86) 6

(1.78) 2

(12.82) 13

24

19.71

39.33

7.99

57.33

3

6

2

13

.447

.447

.447

.447

14.7

14.7

8.9

9.9

14.7

14.7

8.9

9.9

95

95

95

95

109.7

109.7

103.9

104.9

+10

110

25

22

15