Physics of swimming Physics of swimming not all
- Slides: 40
Physics of swimming
Physics of swimming • • • not all fish swim not all swimmers are fast or efficient but - in order to swim fast, all fish have the same constraints due to physics - thus fast fish tend to look similar
Physics of swimming Properties of water as medium in which to move • density - 830 x greater than air • viscosity – 70 x greater than air
Physics of swimming Properties of water as medium in which to move • density - 830 x greater than air • viscosity – 70 x greater than air • lift – force exerted on object perpendicular to direction of flow (or movement) - proportional to the area over which the pressure difference acts
lift
Physics of swimming Properties of water as medium in which to move • density - 830 x greater than air • viscosity – 70 x greater than air • lift • drag – 830 x greater than in air - increases with speed of object or current - due to separation of flow from object into turbulent flow
Physics of swimming Properties of water as medium in which to move • density - 830 x greater than air • viscosity – 70 x greater than air • lift • drag – 830 x greater than in air - increases with speed of object or current - due to separation of flow from object into turbulent flow • boundary layer - laminar or turbulent
Physics of swimming Reynolds number (Re): ratio of inertial forces to viscous forces Re = LVr/m L = length of object V = velocity of object r = density of fluid m = viscosity of fluid
Physics of swimming Reynolds number (Re): ratio of inertial forces to viscous forces Re = LVr/m L = length of object V = velocity of object r = density of fluid m = viscosity of fluid flow changes to turbulent at Re ~ 2, 000 turbulent flow is a consequence of increasing speed increasing length (decreasing viscosity) (increasing density of liquid) boundary layer changes to turbulent as Re goes from 5 x 105 -5 x 106
Physics of swimming Reynolds number (Re): ratio of inertial forces to viscous forces Re = LVr/m L = length of object V = velocity of object r = density of fluid m = viscosity of fluid Examples of Re: animal whale tuna copepod sea urchin sperm speed 10 m/s 20 cm/s 0. 2 mm/s Re 300, 000 30, 000 300 0. 03
Physics of swimming for efficient swimming avoid separation of boundary layer from surface maximize laminar flow in boundary layer
Physics of swimming for efficient swimming avoid separation of boundary layer from surface maximize laminar flow in boundary layer minimize turbulent flow in wake
Physics of swimming solutions: streamline body (tapering): aspect ratio of about 0. 25 maximum thickness of body 1/3 from front (head) b a Aspect ratio = a/b
Physics of swimming solutions: streamline body (tapering): aspect ratio of about 0. 25 maximum thickness of body 1/3 from front (head) drag reduction - keep body rigid
Physics of swimming solutions: streamline body (tapering): aspect ratio of about 0. 25 maximum thickness of body 1/3 from front (head) drag reduction - keep body rigid slime layer to reduce frictional drag rough surface (cteni) keeps boundary layer attached? Australian Museum
Physics of swimming Swimming modes “kick and glide” active - sustained for hours or days burst - only for up to 30 secs large fishes have greater difference between burst and active than small fishes
Physics of swimming Swimming modes “kick and glide” active - sustained for hours or days burst - only for up to 30 secs large fishes have greater difference between burst and active than small fishes
Physics of swimming active swimming accomplished using red muscle along sides of fish - high myoglobin and mitochondrial enzymes burst swimming with white muscle - great contractile speeds, low endurance
BCF - body/caudal fin propulsion
anguilliform entire body undulates laterally flattened, elongated body inefficient Anguilliformes – moray eel Perciformes – snake mackerel, etc.
subcarangiform swim with posterior portion of body, less than one wavelength tend toward truncate, rounded, or emarginate tails head still yaws with motion of swimming aspect ratio of tail ~1. 5 -2 cods, basses, trout, many others Salmoniformes – rainbow trout
carangiform less that half to one third of body flexes generally narrow peduncle, flared and strongly forked or lunate tail high aspect ratio tail (square of span/surface area) ~3. 5 herrings, jacks, some scombrids Perciformes – jacks (Carangidae)
thunniform extremely stiff body, narrow peduncle, high aspect ratio tail (4 -10) large tendons to support muscular energy transmission to tail; stiffened tail tunas, marlins, sailfishes, some sharks Perciformes – tuna (Thunnidae)
ostraciiform only moves tail, rest of body rigid boxfishes, porcupine fish Tetraodontiformes – boxfish (Tetraodontidae)
MPF - median/paired fin propulsion
rajiiform undulate pectoral fins from front to back, with wing-like ‘flapping’ Rajiiformes – Rajidae (manta ray)
didontiform undulate pectorals for sculling and maneuvering Tetraodontiformes - pufferfish (Ostracidae)
labriform oscillate pectorals for sculling and maneuvering Perciformes – parrotfish (Labridae)
amiiform/gymnotiform use undulatory waves of dorsal (Amia) or anal (Gymnotids) fins also seahorses, with narrow-base dorsal Amiiformes - bowfin Gymnotiformes - knifefish
balistiform use simultaneous motion of dorsal and anal fins - triggerfish (used to some extent in eels, percids, flatfish) Tetraodontiformes – triggerfish (Balistidae)
tetraodontiform both dorsal and anal fins move together to each side Tetraodontiformes – ocean sunfish (mola)
NON-SWIMMING LOCOMOTION gliding above water - flying fishes add to take-off propulsion by using tail lobe in water like propeller may fly up to 400 m, as high up as 5 m may add pelvic fins as secondary gliding surfaces
Scorpaeniformes – flying gunard
Other forms of nonswimming locomotion: burrowing - eels, gobies, flatfish, rays wriggling - eels hitchhiking - remoras, lamprey push-and-hold - gobies using pelvic disk; lamprey using oral disk
Other forms of nonswimming locomotion: ‘walking’ or climbing on pectorals - walking catfish, mudskippers walking on bottom – sea robins using pectoral rays; batfish and relatives walk on modified pelvics Siluriformes – walking catfish Perciiformes (Gobiidae) - mudskipper Lophiiformes - batfish
Other forms of nonswimming locomotion: ‘walking’ or climbing on pectorals - walking catfish, mudskippers walking on bottom - searobins using pectoral rays; batfish and relatives walk on modified pelvics Aulopiformes - tripod fish
Other forms of nonswimming locomotion: leaping - mullets, tuna, sailfish - also salmonids moving upstream
Other forms of nonswimming locomotion: jet propulsion - by forcible ejection of water out of gills by operculum used as ‘assist’ to fast take-off by some percids, sculpins passive drift - larvae, sargassum fish frogfish
Sadlier unit 1 level d synonyms
Love is not all imagery
Opposite rays
Physics in swimming
Autoenglish fce
Modern physics vs classical physics
University physics with modern physics fifteenth edition
Physics investigation ideas
If you are not confused you're not paying attention
Informal-casual
Attention is not explanation
Not too narrow not too deep
If not p then q
Small just
Eyes that see and ears that hear
Pp sit
If you can't measure it you can't improve it
We will not be moved when everything around is shaking
Not a rustling leaf not a bird
You can not not communicate
Not everyone internalizes all of society's norms
Elt supervision
Not all enzymes are proteins
Rank size formula
Not of an age but for all time
All nonzero digits are significant.
Measurable characteristics that describe an object
All roads lead to damascus
For one does not fit all
That is not all technique
One size does not fit all
Not all qubits are created equal
Not all books belong
Both of the statues on the shelf is broken
One size does not fit all in education
Oatmeal glycemic index
Germany will either be a world power or will not be at all
All multimode modems are not created equal
Help ever hurt never
Interventi sociali rivolti all'infanzia e all'adolescenza
Above all power above all kings
