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Introduction to Stability

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1 Introduction to Stability
Lesson-1 Introduction to Stability CL M G B K BM KM DISPLACEMENT T O N S W E I G H B

2 CLASS TOPICS Definitions Stability Reference Points Stability Triangle
Conditions of Stability Stability Curve Ship’s Hull Markings Draft Diagram and Cross Curves Model

3 Definitions : Stability Initial Stability Overall Stability
Dynamic Stability

4 STABILITY - THE TENDENCY OF A SHIP TO ROTATE ONE WAY OR THE OTHER (TO RIGHT ITSELF OR OVERTURN)
INITIAL STABILITY - THE STABILITY OF A SHIP IN THE RANGE FROM 0° TO 7°/10° OVERALL STABILITY - A GENERAL MEASURE OF A SHIP'S ABILITY TO RESIST CAPSIZING IN A GIVEN CONDITION OF LOADING DYNAMIC STABILITY - THE WORK DONE IN HEELING A SHIP TO A GIVEN ANGLE OF HEEL

5 LAWS OF BUOYANCY • A FLOATING OBJECT HAS THE PROPERTY OF BUOYANCY
• A FLOATING BODY DISPLACES A VOLUME OF WATER EQUAL IN WEIGHT TO THE WEIGHT OF THE BODY.

6 LAWS OF BUOYANCY • A FLOATING OBJECT HAS THE PROPERTY OF BUOYANCY
• A FLOATING BODY DISPLACES A VOLUME OF WATER EQUAL IN WEIGHT TO THE WEIGHT OF THE BODY. • A BODY IMMERSED (OR FLOATING) IN WATER WILL BE BUOYED UP BY A FORCE EQUAL TO THE WEIGHT OF THE WATER DISPLACED.

7 DISPLACEMENT THE WEIGHT OF THE VOLUME OF WATER THAT THE SHIP'S HULL IS DISPLACING UNITS OF WEIGHT LONG TON = 2240 LBS = KG SHORT TON = 2000 LBS = KG METRIC TON = LBS = 1000 KG

8 DISPLACEMENT DISPLACEMENT 00 G

9 DISPLACEMENT DISPLACEMENT 04 G B

10 DISPLACEMENT DISPLACEMENT 09 G B

11 DISPLACEMENT G B DISPLACEMENT 16

12 DISPLACEMENT G B DISPLACEMENT 20

13 FORCE: A PUSH OR A PULL. IT TENDS TO PRODUCE MOTION OR A CHANGE IN MOTION.
UNITS: TONS, POUNDS, ETC. PARALLEL FORCES MAY BE COMBINED INTO ONE FORCE EQUAL TO THE SUM OF ALL FORCES ACTING IN THE SAME DIRECTION AND SO LOCATED TO PRODUCE THE SAME EFFECT. 5T 5T 15T 5T

14 d F a MOMENT = F x d WEIGHT : GRAVITATIONAL FORCE.
DIRECTION TOWARD CENTER OF EARTH UNITS : TONS, POUNDS, etc MOMENT: THE TENDENCY OF A FORCE TO PRODUCE ROTATION ABOUT AN AXIS a d F MOMENT = F x d

15 VOLUME = NUMBER OF CUBIC UNITS IN AN OBJECT
UNITS: CUBIC FEET CUBIC INCHES CUBIC METRES 20 M 30 M 6 M V = L x B x D V = 30 M x 20 M x 6 M V = 3600 M3

16 SPECIFIC VOLUME = VOLUME PER UNIT WEIGHT
UNITS: METRE CUBIC PER TON SW = M3/TON FW = M3/TON WT = VOLUME SP.VOL WT = 3600 M3 / M3/T 20 M 30 M 6 M V = 3600 M3 WT = 3600 M3 X T/M3 WT = 3698,99 TONS

17 CLASS TOPICS 1. Definitions 2. Stability Reference Points 3. Stability Triangle 4. Conditions of Stability 5. Stability Curve 6. Ship’s Hull Markings 7. Draft Diagram and Cross Curves 8. Model

18 2. Stability Reference Points
Metacentre Gravity Buoyancy Keel

19 STABILITY REFERENCE POINTS
M etacenter G ravity B uoyancy K eel CL

20 STABILITY REFERENCE POINTS
M other G oose B eats K ids CL

21 THE CENTER OF BUOYANCY

22 THE CENTER OF BUOYANCY B WATERLINE RESERVE BUOYANCY B B1

23 RESERVE BUOYANCY, FREEBOARD, DRAFT AND DEPTH OF HULL
WATERLINE B RESERVE BUOYANCY FREEBOARD DEPTH DRAFT

24 CENTER OF BUOYANCY WL B WL B WL B WL B WL B

25 CENTER OF BUOYANCY B B B B B

26 THE CENTER OF GRAVITY

27 CENTER OF GRAVITY POINT AT WHICH ALL WEIGHTS COULD BE CONCENTRATED.
CENTER OF GRAVITY OF A SYSTEM OF WEIGHTS IS FOUND BY TAKING MOMENTS ABOUT AN ASSUMED CENTER OF GRAVITY, MOMENTS ARE SUMMED AND DIVIDED BY THE TOTAL WEIGHT OF THE SYSTEM.

28 G G1 KGo KG1 THE CENTER OF GRAVITY G G1 KGo KG1

29 MOVEMENTS IN THE CENTER OF GRAVITY
G MOVES TOWARDS A WEIGHT ADDITION G MOVES AWAY FROM A WEIGHT REMOVAL G MOVES IN THE DIRECTION OF A WEIGHT SHIFT

30 MOVEMENTS IN THE CENTER OF GRAVITY
G MOVES TOWARDS A WEIGHT ADDITION G G1 KGo KG1

31 G KGo G1 KG1

32 MOVEMENTS IN THE CENTER OF GRAVITY
G MOVES AWAY FROM A WEIGHT REMOVAL G G1 KGo KG1

33 G1 KG1 KGo G G G G G G G

34 MOVEMENTS IN THE CENTER OF GRAVITY
G MOVES IN THE DIRECTION OF A WEIGHT SHIFT G G

35 G G2

36 THE METACENTER

37 METACENTER M B B1 B2 THE METACENTER CL B B20 B45 M M20 M45 M70 B70

38 METACENTER B B B B B B B B B

39 METACENTER M B SHIFTS

40 MOVEMENTS OF THE METACENTER
THE METACENTER WILL CHANGE POSITIONS IN THE VERTICAL PLANE WHEN THE SHIP'S DISPLACEMENT CHANGES THE METACENTER MOVES LAW THESE TWO RULES: 1. WHEN B MOVES UP M MOVES DOWN. 2. WHEN B MOVES DOWN M MOVES UP.

41 G M B G M B G M B G M B M G B M G B M1 B1 M1 B1 M1 B1 M1 B1
MOVEMENT OF THE METACENTRE G M B M1 B1 G M B M1 B1 G M B M1 B1 G M B M1 B1 M G B M G B

42 MOVEMENT OF THE METACENTRE 0o-7/10o M B CL

43 MOVEMENT OF THE METACENTRE M20 M B B20 CL

44 MOVEMENT OF THE METACENTRE M20 M45 M B B20 B45 CL

45 MOVEMENT OF THE METACENTRE M20 M45 M M70 B B20 B70 CL B45

46 MOVEMENT OF THE METACENTRE M45 M20 M70 B CL M M90 B20 B90 B45 B70

47 MOVEMENTS OF THE METACENTER
THE METACENTER WILL CHANGE POSITIONS IN THE VERTICAL PLANE WHEN THE SHIP'S DISPLACEMENT CHANGES THE METACENTER MOVES LAW THESE TWO RULES: 1. WHEN B MOVES UP M MOVES DOWN. 2. WHEN B MOVES DOWN M MOVES UP.

48 MOVEMENT OF THE METACENTRE
G B M M1 B1 G WHEN B MOVES UP M MOVES DOWN.

49 LINEAR MEASUREMENTS IN STABILITY
CL K M G B GM BM KM KG KB

50 CLASS TOPICS 1. Definitions 2. Stability Reference Points 3. Stability Triangle 4. Conditions of Stability 5. Stability Curve 6. Ship’s Hull Markings 7. Draft Diagram and Cross Curves 8. Model

51 3. Stability Triangle M G Z

52 THE STABILITY TRIANGLE
M G Z CL K B G M CL K B G M

53 THE STABILITY TRIANGLE
CL M G B K B1 CL K B G M B1 CL M G B K B1 M CL G B K B1 M G Z B K CL

54 Sin q = opp / hyp Where : opposite = GZ hypotenuse = GM
Sin q = GZ / GM GZ = GM x Sin q Growth of GZ a GM

55 G1 M G B K CL

56 Growth of GZ α GM AS GM DECREASES RIGHTING ARM ALSO DECREASES M G1 Z1

57 INITIAL STABILITY G B M 0 - 7° CL

58 OVERALL STABILITY M Z G B B1 CL RM = GZ x Wf

59 CLASS TOPICS 1. Definitions 2. Stability Reference Points 3. Stability Triangle 4. Conditions of Stability 5. Stability Curve 6. Ship’s Hull Markings 7. Draft Diagram and Cross Curves 8. Model

60 THE THREE CONDITIONS OF STABILITY
M THE THREE CONDITIONS OF STABILITY G Z B1 POSITIVE G M B B1 NEUTRAL G M B B1 NEGATIVE

61 POSITIVE STABILITY M G B K CL

62 POSITIVE STABILITY M Z G B B1 K CL

63 NEUTRAL STABILITY G M B K CL

64 NEUTRAL STABILITY G M B B1 K CL

65 NEGATIVE STABILITY G M B K CL

66 NEGATIVE STABILITY G M B B1 K CL

67 CLASS TOPICS 1. Definitions 2. Stability Reference Points 3. Stability Triangle 4. Conditions of Stability 5. Stability Curve 6. Ship’s Hull Markings 7. Draft Diagram and Cross Curves 8. Model

68 RIGHTING ARM CURVE RIGHTING ARMS (FT) 10 20 30 40 50 60 70 80 90
10 20 30 40 50 60 70 80 90 ANGLE OF HEEL (DEGREES) WL 60° G B Z WL 40° G B Z WL 20° G B Z GZ = 1.4 FT GZ = 2.0 FT GZ = 1 FT

69 ANGLE OF MAXIMUM RIGHTING ARM
MAXIMUM RANGE OF STABILITY RIGHTING ARMS (FT) DANGER ANGLE 10 20 30 40 50 60 70 80 90 ANGLE OF HEEL (DEGREES) WL WL WL 60° 40° 20° G Z G Z G Z B B B GZ = 1.4 FT GZ = 2.0 FT GZ = 1 FT

70 CLASS TOPICS 1. Definitions 2. Stability Reference Points 3. Stability Triangle 4. Conditions of Stability 5. Stability Curve 6. Ship’s Hull Markings 7. Draft Diagram and Cross Curves 8. Model

71 LONGITUDINAL CROSS SECTION
CALCULATIVE LIMITING NAVIGATIONAL MP AP FP DWL BL PROJ LBP

72 CLASS TOPICS 1. Definitions 2. Stability Reference Points 3. Stability Triangle 4. Conditions of Stability 5. Stability Curve 6. Ship’s Hull Markings 7. Draft Diagram and Cross Curves 8. Model

73 DRAFT DIAGRAM AND FUNCTIONS OF FORM
17 16 15 14 13 12 11 800 4000 3500 3000 2550 750 700 650 600 550 AFTER DRAFT MARKS (FT) MOMENT TO ALTER TRIM ONE INCH (FOOT-TONS) DISPLACEMENT (TONS) 22.2 22.3 22.4 22.5 22.6 22.7 22.8 TRANSERSE METACENTER ABOVE BOTTOM OF KEEL (FT) 28 29 30 31 32 33 5 4 3 2 1 TONS PER INCH (TONS/IN) LONGITUDINAL CENTER OF BUOYANCY (FEET) FORWARD DRAFT MARKS (FT) CURVE OF CENTER OF FLOTATION 20 10 Length Between Draft Marks 397' 0" TPI KM Wo LCB MT1" LCF DRAFT FWD = 14 FT 6 IN DRAFT AFT = 16 FT 3 IN KM = TPI = LCB = LCF = MT1" = 22.28 FT 32.7 TONS/IN Wo = 3850 TONS 3.5 FT AFT 778 FT-TONS/IN 24 FT AFT

74 FFG 7 10o = 15o = 20o = 30o = 40o = 45o = 50o = 55o = 60o = .55 FT
CROSS CURVES OF STABILITY CENTER OF GRAVITY ASSUMED 19.0 FT ABOVE THE BASELINE DISPLACEMENT (TONS) RIGHTING ARMS (FT) 3000 3500 4000 4500 40 30 20 15 10 60 55 45 50 3.0 2.5 2.0 1.5 1.0 0.5 10o = 15o = 20o = 30o = 40o = 45o = 50o = 55o = 60o = .55 FT .85 FT 1.1 FT 1.73 FT 2.35 FT 2.55 FT 2.6 FT 2.5 FT 2.3 FT

75 RIGHTING ARMS (FT) STATICAL STABILITY CURVE PLOTTING SHEET
10o = 15o = 20o = 30o = 40o = 45o = 50o = 55o = 60o = .55 FT .85 FT 5 1.1 FT 1.73 FT 2.35 FT 4 2.55 FT 2.6 FT 2.5 FT 3 2.3 FT X X X X X RIGHTING ARMS (FT) 2 X X 1 X X X 10 20 30 40 50 57.3 60 70 80 90 ANGLE OF INCLINATION - DEGREES

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