Excel Sheets and Forms—Summary

A P P E N D I X

VII

Excel Sheets and Forms—Summary No.

File Name

Description

Folder Name: Nursery 1

PL Acclimation Data Recording Form

For data recording during acclimation to nursery tanks: PL samples, mortalities, water volume, and water quality. Page # 401

2

PL Evaluation Data Recording Form

For PL microscopic physical evaluation following receipt from the hatchery and during early nursery stages. Page # 402

3

Nursery WQ, Feed, & More_Form

For recording daily water quality, equipment operation, feed rations, and other inputs. Page # 403

4

Nursery Group Sampling_Form & Calc

For weekly shrimp growth sampling, with calculations for average weight and growth (g/day and g/week) given in a separate spreadsheet. Page # 404

5

Nursery Ration Growth FCR Survival

For input of Excel Sheet #4 data and calculating average weight, growth, biomass, FCR, and rations. A separate spreadsheet with example data from 2014 is included.

6

Nursery WQ Feed Growth FCR Electronic Data Recording Form Example & Cal

For collating data for individual nursery tanks over a full nursery cycle (from Sheet # 3 and # 4)—water quality, equipment operation, feed rations, shrimp weight, and other inputs. Includes columns to calculate FCR and growth. A separate spreadsheet with example data from 2012 is included. Page # 405

7

Nursery Individual wt. Frequency distribution & Feed Calc_Examples

Example spreadsheets (2014 nursery trials) for calculating shrimp size distribution and allocating feed type and size to individual nursery tanks.

8

Shrimp PL Age and Length

For estimating L. vannamei PL weight at given total lengths and PL size at given ages. Covers PL5–30. Page # 406

9

Nursery Sampling Before Transfer_Form

For recording weight and size distribution prior to nursery tank harvest. The collected data can be added to a separate spreadsheet which includes formulae for calculating average weight and size variation. Page # 407 Continued

399

400

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

No.

File Name

Description

10

Juvenile Transfer Form & Calc

For recording weight of harvested shrimp during transfer to grow—out tanks. The collected data can be added to a separate spreadsheet which includes formulae for calculating total harvest weight, yield, shrimp number, survival, average weight, and size variation. Page # 408

Folder Name: Grow—out 11

Grow—out WQ Operation Feed Vibrio Inputs Data Recording Form

For recording daily water quality, equipment operation, feed rations, and other inputs. Page # 409

12

Grow—out Group Sampling_Form & Calc

For weekly shrimp growth sampling, with calculations for average weight and growth (g/d and g/wk) given in a separate spreadsheet. Page # 410

13

Grow—out 40 & 100 m3 RWs Growth. FCR. Ration Calc_Examples

Example spreadsheets (2012 & 2013 Grow—out trials) for calculating shrimp average weight, growth, biomass, FCR, and rations.

14

Grow—out Ration Growth FCR Survival

For input of Sheet # 12 data and calculating average weight, growth, biomass, FCR, and rations. A separate spreadsheet with example data from 2014 is included.

Folder Name: General 15

Calc & Example FCRs 100 m3 RW

For recording feed offered and shrimp growth, and calculating FCR, biomass, average weight, and growth. A separate spreadsheet with example data from 2012 is included. Page # 411

16

Group Weight Sampling_Form & Calc

For recording group weight of harvested shrimp from nursery or grow—out tanks. The collected data can be added to a separate spreadsheet which includes formulae for calculating total harvest weight, shrimp number, average weight, and size variation. Page # 412

17

Individual Weight Sampling_Form & Calc

For recording individual weight of 100 sampled shrimp from nursery or grow—out harvest. Data can be added to a separate spreadsheet that includes formulae for calculating average weight and size variation. Page # 413

18

Organic Carbon Supplementation_Examples & Calc

Examples on how to calculate organic carbon requirements for feed with different crude protein and different organic C sources and user input to calculate molasses/white sugar requirements. Page # 414

Folder Name: Water Quality 19

Vibrio & Alkalinity Form_Examples & Calc

For recording and calculating Vibrio plate counts and alkalinity (standard titration method). Examples are given for each. Page # 415

20

TSS Form_Example & Calc

For recording and calculating TSS (standard titration method). Examples are given. Page # 416

21

pH Calc

Spreadsheet showing the calculation of [H+] from known pH and how to calculate an average pH from multiple pH values

22

Changes in WQ during Grow—out_2012 40 m3 RW System_Example

Example spreadsheets for weekly water quality data from the 2012 grow—out trial. Includes data and graphs of TAN, NO2,—N NO3—N, PO4, TSS, VSS, alkalinity, turbidity, cBOD5, and COD changes over time.

Salinity TDS Conductivity_Conversions Table

Conversion table Conductivity to salinity. Page # 417

400

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Postlarvae Acclimation Data Recording Form P L Sourc e :

D a te :

Bag #:

B ag Vol. (L):

Sample Vol. (mL):

P L/Sample :

Live P L/ Sample :

De ad P L/Sample :

Total P L/B ag:

TAN (mg/L):

Time

Temp.

Excel Sheet # 1_PL Acclimation Form

DO

pH

Salinity

Vol. Added (L)

401

402

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Postlarvae Microscopic Evaluation , after Davis et al. (2004) and Villalon (1991). Date :

Hatche ry:

PL Age (d):

Ge ne tic Line :

Sample Siz e :

Population CV:

Av. Wt. (mg): Indicator Mucus & debris on setae:

Fouling: (sessile ciliates, filamentous bacteria, benthic algae, fungi etc.), especially on gills:

Broken walking legs (periopods) or antennae:

Lesions on walking legs/swimming legs (pleopods) and antennae along with/without chitinoclastic bacterial infection: Evidence of brown spots on the body such as chitinoclastic bacteria:

Deformities in eye stalks, rostrum, first and second antennae, tail segments, and walking leg:

Opaqueness of tail segments and swimming legs:

Body pigmentation and hepatopancreas color:

Gut fullness, hepatopancreas lipid content and deformities:

Gill Development:

Other:

Excel Sheet # 2_PL Evaluation Form

Comme nts

Score

Nursery Production - L. vannamei PL Source _________

Date:____/___ DOC:_______ Day: M, T, W, T, F, S, S Tank ID

FW

SW

(m3)

(m3)

FF (h)

MCF (h)

ST (h)

TSS (mg/L)

SS (mL/L)

1.5 mm

2 mm

NH4-N

NO2-N (mg/L)

NO3-N

Sugar (g)

Bicarbo (kg)

PL/m3:_____

Turb (NTU)

Alka (mg/L)

Vibrio (CFU/mL) Yellow Green

Carbo (kg)

Probio (g)

O2 (L/min) (h)

DO am

pH pm

am

pm

Sal (ppt)

Dead (#)

1 2 3 4 5

7 8 9 Tank ID EZ Art

Belt Feeders (kg) <400µm 400-600µm 600-860µm

1 mm

1 2 3 4 5 6

Total Fed (kg)

REMARKS

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

6

7 8 9

Excel Sheet # 3_Nursery WQ, Feed, & More_Form

403

404

Nursery Production - Litopenaeus vannamei PL Source: Stocking Date:

DOC: Days from last Sampling : Current

TK ID

Group Wt. (g)

# Shrimp

1 2 3 4 5 6 7 8 Excel Sheet # 4_Nursery Group Sampling_Form

Tare (g)

7 Av. Wt. 7 Days

Av. Wt. (g)

(g/day)

(g/wk)

Earlier (g)

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Sampling Date :

Example for electronic nursery data entry templet used by Texas A&M-ARML for 40 m raceway Raceway Volume (m ):40 Tank ID: RW 1

PL Genetic Info:

Comments TSS (mg/L)

Alka (mg/L)

TAN (mg/L) NO3-N (mg/L) NO2-N (mg/L) O2 (lpm) Venturi (h) New SW (m3)

Volume (m3)

New FW (m3)

FF (h)

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

17 25

ST (h)

16 24

NaHCO3 (g)

15 23

CaCO3 (g)

14 22

Av. Weight (g)

13 21

Current Bio (g)

12 20

Bio Incr from Last

11 19

FCR From T1

10 18

Feed from Last (g)

9 17

Feed Types

8 16

FCR from Last

7 15

Total Feed (g)

6 14

Feed Type 2 (g)

5 13

pH

4 12

Feed Type 1 (g)

DO (%)

DO (mg/L)

3 11

3

Stocking Date:

Temperature (oC) SS (mL/L)

Time (PM)

pH

Turbidity (NTU) DO (mg/L)

Salinity (ppt)

DO (% Saturation)

Time (AM)

Temperature (oC)

Day of culture

PL Age (days)

9

Date (M/D/Y)

1

40,294 Cross: Fast-Growth/Taura-R# of shrimp:

PL Size (g): Stocking Density (PL/m ):

# of PLs stocked: 3

3

2 10

18 26

19 27

20 28

Excel Sheet # 6_Typical Nur WQ Feed_records

405

Min Ln (mm) Max Ln (mm) Mean Wt (g) 3 4 5 6 7

4 5 6 7 8

0.0010 0.0015

Insufficient branchial development and osmoregulatory capacity for salinity less than about 30 ppt.

30 25 20 15 10 5 0 5

10

15 20 PL age (days)

25

30

25

30

0.35 0.30

PL weight (g)

0.25 0.20 0.15 0.10 0.05 0.00 5

10

15

20

PL age (days)

Excel Sheet # 8_Shrimp PL Age and Length

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Acceptable range in PL development for osmoregulatory capacity (salinity reduction) and shipping in sealed bags (metabolic loading).

35

PL length (mm)

PL age 5 6 7 8 9

406

(Doug Ernst, NSC, 4/25/14)

Relationship of PL age and size

Data compiled from various sources, internal and external. Age and size relation shown below is an approximation and varies with PL culture conditions and growth rate. Given that it's easier to measure length than weight for PL stocking (PL8 - 12), this chart is used to estimate mean weight based on mean length.

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Nursery Tank Sampling Before Transfer Tank ID: Sample

Date: Total Wt. (g)

# Shrimp

Tare (g)

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 Excel Sheet # 9_Nursery Sampling Before Transfer_Form

Av. Wt. (g)

407

408

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Juvenile Transfer - Data Recording Sheet P L Sourc e :

M ove d to GO Tank: 3

Tank Vol. (m ): Nursery ID: Weight (kg)

Trans. Date: Cumulative Weight (kg)

Weight (kg)

1

26

2

27

3

28

4

29

5

30

6

31

7

32

8

33

9

34

10

35

11

36

12

37

13

38

14

39

15

40

16

41

17

42

18

43

19

44

20

45

21

46

22

47

23

48

24

49

25

50

Excel Sheet # 10_Juvenile Transfer Form & Calc

Cumulative Weight (kg)

Date:____/___

Grow-out - L. vannamei PL Source _________

DOC:_______

Stocking Juveniles/m3:_________

Day: M, T, W, T, F, S, S Tank ID

FW 3

SW

(m )

3 (m )

1 mm

1.5 mm

FF (h)

MCF (h)

TSS (mg/L)

SS (mL/L)

NH4-N

Total Fed Sugar (kg) (g)

Bicarbo (kg)

Carbo (kg)

ST (h)

NO2-N (mg/L)

NO3-N

Turb (NTU)

Alka (mg/L)

Vibrio (CFU/mL) Yellow Green

DO am

pH pm

am

pm

Sal (ppt)

Dead (#)

1 2 3

5 6 7 8

Tank ID

Belt Feeders (kg) 2 mm

2.4 mm

Probio (g)

O2 (L/min)

(h)

1 2 3 4 5

REMARKS

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

4

6 7 8 P. 535 GO WQ Operaon Feed

Excel Sheet # 11_Grow-out WQ Operation Feed Vibrio Inputs Data Recording Form

409

410

Grow-out Production - Litopenaeus vannamei PL Source:

DOC:

Stocking Date:

Days from Last Sampling:

TK

ID

Current Group Wt. (g)

# Shrimp

Tare (g)

1 2 3 4 5 6 7 8 Excel Sheet # 12_Grow-out Group Sampling_Form & Calc

7

Av. Wt. 7 Days Av. Wt. (g)

(g/day)

(g/wk)

Earlier (g)

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Sampling Date:

411

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY 3

Computing FCR in 100 m RW Total shrimp stocked in RW: Date

Total Total Doc Feed (g/day) Feed (g)

50,000 Stocking density (shrimp/m3): Inter FCR

Overall Feed FCR Last wt.

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 Excel Sheet # 15—Grow-out ration growth FCR survival

500

Biomass Av. wt. Biomass Increase (g) (g) (g)

412

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Group Weight - Nursery / Grow-out Harvest - Data Recording Sheet Transfer / Final Harvest

PL Source: Tot. Wt. (g)

# shrimp

Tare

Av. Wt.

Tot. Wt. (g)

1

21

2

22

3

23

4

24

5

25

6

26

7

27

8

28

9

29

10

30

11

31

12

32

13

33

14

34

15

35

16

36

17

37

18

38

19

39

20

40

Excel Sheet # 16—Group weight sampling_form & calc

Tank ID:

Date: # shrimp

Tare

Av. Wt.

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Individual Weight - Data Recording Sheet Tank ID:

Nur.

GO

Trans. Harvest Date:

1

26

51

76

2

27

52

77

3

28

53

78

4

29

54

79

5

30

55

80

6

31

56

81

7

32

57

82

8

33

58

83

9

34

59

84

10

35

60

85

11

36

61

86

12

37

62

87

13

38

63

88

14

39

64

89

15

40

65

90

16

41

66

91

17

42

67

92

18

43

68

93

19

44

69

94

20

45

70

95

21

46

71

96

22

47

72

97

23

48

73

98

24

49

74

99

25

50

75

100

Excel Sheet # 17—Individual weight sampling_form & calc

413

Specific Example 1. Assuming tank volume of: 100,000 L 2. Level of TAN in tank: 3 mg/L 3. Providing the heterotrophic bacteria all organic C requires to convert the TAN into bacteria biomass Calculation for molasses:

100,000 L (TK vol.)

3 (TAN conc.)

6 (required C)

Calculation of daily TAN production in no exchange production system Assumptions: F = Daily Ration: PC = Protein Concentration: Constant for TAN generation in no exchan Nitrogen in Protein:

1 kg 35% = 0.144 16%

0.35

1 kg 4 0% = 0.144 0.0576 kg

1.3 (molasses spec. wt.) Example 4: F PC C TAN/day =

0.40

Example 3: F 1 kg PC 4 5% = C 0.144 0.0648 kg TAN/day

0.45

24% (C in molasses) / 1,000 (conv. To g from m

1 kg 50% = 0.144 0.0720 kg

0.50

Example 5: F 1 kg PC 55% = C 0.144 0.0792 kg TAN/day

0.55

Steps to enhance development of nitrifying bacteria Assumptions: Tank volume: 40,000 L 1) 1/3 of the TAN generated from feed per day is taken by the heterotrophic bacteria 2) 2/3 of the TAN generated from feed per day is left for the nitrifying bacteria to process 3) Tank w as inoculated w ith at least 10% of its volume w ith nitrifying-rich water 4) Alkalinity, TAN, nitrite, nitrate and pH are monitored daily 5) Daily ration: 1 kg 6) Feed protein concentration: 55% 7) Amount of TAN generated: 0.0792 kg 1.98 mg/L (0.0792 × 1,000 × 1,000 / 40,000) 8) TAN concentration in 9) Amount of TAN left for the nitr 0.0523 kg (0.0792 × 0.66) Day 1 TAN 1.98 mg/L Alkalinity 140 mg/L (as CaCO3) pH 7.8 NO2 0.01 mg/L 0.001 mg/L NO3 Organic C supplementat 0.2981 kg [(0.0523 × 6 - (0.0523 × 6 × 0.05)] 5% reduction in organic C below the amount needed to convert all TAN into heterotrophic bacterial biomass to free-up TAN for the nitrifying bacteria

TAN (kg) = F (kg) × PC (decimal value) × 0.144 0.0504 1 × 35% × 0.144 Example 1: F PC C TAN/day

=

1 kg 30% = 0.144 0.0432 kg

0.30

Excel Sheet # 18_Organic Carbon Requirement Examples & Cal

Day 2 TAN 0.01 mg/L Alkalinity 128 mg/L (as CaCO3) pH 7.8 NO2 0.02 mg/L 0.001 mg/L NO3 Organic C supplementat 0.2824 kg (0.3138 - 0.0314) Alkalinity reduction along w ith slight increase in nitrite suggest nitrification activity 10% reduction in organic C supplementation along with increase in alkalinity to 140 mg/L are suggested to free-up TAN for the nitrifying bacteria

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Carbon Source Available C Required Organic Carbon Molasses* 24.0% 5,769.23 mL White sugar 42.1% 4,275.53 g Lactose 42.1% 4,275.53 g 40.0% 4,500.00 g Dextrose Glucose 40.0% 4,500.00 g Acetate 40.0% 4,500.00 g Glycerol 39.1% 4,603.58 L Cellulose 44.4% 4,054.05 g Starch 44.4% 4,054.05 g Cassava meal 43.4% 4,147.47 g Corn flour 43.4% 4,147.47 g Rice brane 43.4% 4,147.47 g Sorghum meal 43.4% 4,147.47 g Tapioca 43.4% 4,147.47 g Wheat flour 43.4% 4,147.47 g Wheat brane 43.4% 4,147.47 g * Assuming 24% W/W carbon concentration and specific weight of 1.3 g/ml

Example 2: F PC C TAN/day =

414

Amount of different organic carbon sources required to convert all TAN generated from feed into biomass of heterotrophic bacteria

415

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Vibrio Counts Date:

Time Inoculated: Time Counted: Sample size (µL):

Yellow

Green

Total

RACEWAY CFU/Plate

CFU/mL

CFU/Plate

CFU/mL

RW 1 RW 2 RW 3 RW 4 RW 5 RW 6 RW 7 RW 8 RW 9 RW 10

Alkalinity SULFURIC ACID USED (mL) Initial Reading

End Point Reading

Date:

Difference (mL)

RW1

0.00

RW2

0.00

RW3

0.00

RW4

0.00

RW5

0.00

RW6

0.00

B1

0.00

B2

0.00

Normality of H2SO4 Solution

Jun-14

0.019023462

*Calculated normality of H 2 SO 4 solution- should be close to 0.02

Excel Sheet # 19—Vibrio Alkalinity Forms & Calc.xls

Alkalinity (mg/L CaCO3)

CFU/Plate

CFU/mL

416

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

TSS Monitoring Form* DATE: RW Sample Empty (g) Dry (g) Empty (mg) Dry (mg) TSS (mg/L) Av. TSS (mg/L) Dry 2 (g) Dry 2 (mg) Control

RW1

RW2

RW3

RW4

RW5

RW6

RW7

RW8

RW9

RW10 * This form is based on Standard Method procedure (Eaton et al. 1995); To save time and siplify monitoring we recommend the use of Pre Weighed 7.7. cm filter papers Excel Sheet #20—TSS Form_Example & Calc

417

APPENDIX VII EXCEL SHEETS AND FORMS—SUMMARY

Conversion Table for Changing Conductivity into Salinity Conductivity*

Salinity

0°C

5°C

10°C

15°C

20°C

25°C

30°C

ppt

1.200

1.400

1.500

1.700

2.000

2.200

2.400

1

2.220

2.500

2.900

3.300

3.700

4.100

4.500

2

3.200

3.700

4.200

4.700

5.300

5.900

6.500

3

4.100

4.700

5.400

6.100

6.900

7.600

8.400

4

5.000

5.800

6.600

7.500

8.400

9.300

10.300

5

5.900

6.800

7.900

8.800

9.900

11.000

12.100

6

6.700 7.600

7.800 8.800

8.900 10.100

10.100 11.400

11.300 12.800

12.600 14.200

13.900 15.700

7 8

8.500

9.800

11.200

12.700

14.200

15.800

17.400

9

9.300

10.800

12.300

13.900

15.600

17.300

19.100

10

10.200

11.800

13.400

15.200

17.000

18.900

20.800

11

11.000

12.800

14.500

16.500

18.900

20.400

22.500

12

11.900 12.600

13.700 14.600

15.600 16.700

17.600 18.700

19.700 21.100

21.900 23.400

24.100 25.800

13 14

13.400

15.600

17.800

20.100

22.400

24.900

27.400

15

14.200

16.400

18.800

21.200

23.800

26.400

29.100

16

15.000

17.400

19.800

22.400

25.100

27.800

30.700

17

15.800

18.300

20.900

23.600

26.400

29.300

32.300

18

16.600

14.200

21.900

24.800

27.700

30.700

33.900

19

17.400

20.100

23.000

25.900

29.000

32.200

35.500

20

18.200

21.100

24.000

27.100

30.300

33.600

37.000

21

19.000

22.000

25.100

28.300

31.600

35.000

38.600

22

19.800

22.900

26.100

29.400

32.900

36.500

40.100

23

20.600

23.800

27.100

30.600

34.200

37.900

41.700

24

21.400

24.700

28.100

31.700

35.400

39.300

43.200

25

22.100

25.500

29.100

32.800

36.700

40.700

44.800

26

22.800

26.400

30.100

33.900

37.900

42.100

46.300

27

23.600

27.300

31.100

35.100

39.200

43.500

47.800

28

24.400

28.100

32.100

36.200

40.400

44.800

49.400

29

25.200

29.000

33.100

37.300

41.700

46.200

50.900

30

26.000

30.000

34.100

38.500

43.000

47.600

52.400

31

26.800

30.900

35.100

39.600

44.200

49.000

53.900

32

27.500

31.700

36.100

40.700

45.400

50.300

55.400

33

28.300

32.600

37.100

41.800

46.700

51.700

56.800

34

29.100

33.500

38.100

42.900

47.900

53.000

58.300

35

29.700

34.200

39.000

44.000

49.100

54.400

59.800

36

30.500

35.100

40.000

45.100

50.300

55.700

61.300

37

31.200

36.000

41.000

46.200

51.500

57.100

62.800

38

32.000 32.700

36.800 37.700

41.900 42.900

47.200 48.300

52.700 53.900

58.400 59.700

64.200 65.700

39 40

* Conductivity values are given in millisiemens/cm Data derived from the equation of P.K. Weyl, Limnology and Oceanography; 9,75 (1964).