Understanding Bernoulli's Equation

00:13:43
https://www.youtube.com/watch?v=DW4rItB20h4

Ringkasan

TLDRVideon är en sponsrad presentation av Bernoullis ekvation och dess olika tillämpningar inom fysik och ingenjörsvetenskap. Bernoullis ekvation beskriver relationen mellan tryck, hastighet och höjd i en strömmande vätska och används för att analysera vätskeflöde, inklusive hur flygplan skapar lyft och hur vätska flödar genom rör. Videon diskuterar också olika mätinstrument som använder ekvationen, såsom Pitot-rör och Venturimätare. Begränsningar av ekvationen inkluderar antaganden om laminärt och stationärt flöde samt inkomprimerbarhet hos vätskan. Fördjupad information och fler exempel finns att se på streamingplattformen Nebula.

Takeaways

  • ✈️ Bernoullis ekvation hjälper till att förklara hur flygplan genererar lyft.
  • 📏 Venturimätare används för att mäta flödeshastighet via tryckförändringar.
  • 🧪 Bernoullis Princip visar att ökad hastighet leder till minskat tryck i flöde.
  • 🔍 Pitot-rör mäter flödets hastighet genom stagnationstryck.
  • ⚖️ Bernoullis ekvation är ett exempel på energikonservering i vätskeflöde.
  • 📉 Begränsningar i ekvationen anger krav på inkomprimerbarhet och laminar flöde.
  • 💡 Ekvationen har praktiska tillämpningar i olika ingenjörsdiscipliner.
  • 🌪️ Det dynamiska trycket representerar fluidens kinestiska energi per volymenehet.
  • 🌊 Den används för att förklara flöde genom rör med varierande diameter.
  • 🎓 Nebula erbjuder ytterligare resurser och exempel för vidare studier.

Garis waktu

  • 00:00:00 - 00:05:00

    Videon börjar med att beskriva Bernoullis ekvation och dess betydelse i fysik och ingenjörsvetenskap. Den uttrycker förhållandet mellan trycket, hastigheten och höjden på en flödande vätska. Bernoullis ekvation publicerades först av Daniel Bernoulli 1738 och är en grundläggande princip för energins bevarande i vätskeflöde. Den kan användas för att förklara fenomen som lyftkraften på flygplansvingar och vätskors utflödeshastighet från behållare. Ekvationen kan representeras i olika former och tillämpas längs en strömlinje, dock med vissa begränsningar som behandlas senare i videon, såsom att flödet måste vara laminärt och konstant över tid.

  • 00:05:00 - 00:13:43

    Bernoullis princip tillämpas i många områden, från att förklara hur flygplansvingar genererar lyftkraft till hur Bunsenbrännare fungerar och i flödesmätningsinstrument som Pitot-rör och Venturimätare. Principen framhäver att en ökning i vätskans hastighet innebär en minskning i trycket, vilket kan verka kontraintuitivt men förklaras av energibehovet. Mot slutet av videon diskuteras begränsningarna i tillämpningen av Bernoullis ekvation på grund av de antaganden som görs vid härledningen, såsom att flödet måste vara laminärt och icke-visköst. För mer djupgående exempel rekommenderas att titta på den längre versionen av videon på Nebula.

Peta Pikiran

Mind Map

Pertanyaan yang Sering Diajukan

  • Vad är Bernoullis ekvation?

    Bernoullis ekvation beskriver förhållandet mellan tryck, hastighet och höjd av ett flödande vätska.

  • Vem publicerade Bernoullis ekvation?

    Den publicerades av den schweiziske fysikern Daniel Bernoulli år 1738.

  • Vilka är de tre huvudtermerna i Bernoullis ekvation?

    De tre huvudtermerna är statiskt tryck, dynamiskt tryck och hydrostatiskt tryck.

  • Vad är Bernoullis Princip?

    Bernoullis Princip säger att för horisontellt flöde måste en ökning i vätskehastighet åtföljas av en minskning i tryck.

  • Hur används Bernoullis ekvation för att mäta flöde?

    Flödesmätningsenheter som Pitot-rör och Venturimätare använder Bernoullis ekvation för att bestämma flödets hastighet.

  • Vilka begränsningar har Bernoullis ekvation?

    Ekvationen förutsätter laminärt flöde, att flödet är stationärt och att vätskan är inkomprimerbar.

  • Hur relaterar Bernoullis ekvation till flygplanslyft?

    Kraftigare flöde ovanför en flygplanvinge skapar lägre tryck, vilket bidrar till att generera lyft.

  • Vad innebär 'stagnationstryck' i ett Pitot-rör?

    Stagnationstryck är trycket där vätskans hastighet minskar till noll vid rörets ände.

  • Vad är Venturi-mätarens syfte?

    Venturi-mätaren används för att bestämma flödeshastighet genom att mäta tryckfallet över en sammanströmningsavsnitt i ett rör.

  • Vilken roll spelar viskositet i Bernoullis ekvation?

    Bernoullis ekvation antar friktionsfritt flöde, och viskositetskrafter ignoreras eftersom de skulle dissipera vätskans inre energi.

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  • 00:00:00
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    and get access to Nebula for free, when you  sign up using the link in the description.
  • 00:00:11
    Bernoulli's equation is a simple but incredibly  important equation in physics and engineering
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    that can help us understand a lot about the flow  of fluids in the world around us. It essentially
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    describes the relationship between the pressure,  velocity and elevation of a flowing fluid.
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    It has countless applications. We can use  it to explain how planes generate lift,
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    or to calculate how fast liquid will  drain from a container, for example.
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    We'll explore these applications and a  few more later on, but let's start by
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    reviewing the equation itself. It was first published by the Swiss
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    physicist Daniel Bernoulli in  1738, and it looks like this.
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    The equation states that the sum of these three  terms remains constant along a streamline.
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    Each of the terms is a pressure. The first term is the static pressure,
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    which is just the pressure P of the fluid. Then we have the dynamic pressure
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    which is a function of the fluid density  Rho and velocity V, and represents the
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    fluid kinetic energy per unit volume. And the last term is the hydrostatic pressure,
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    which is the pressure exerted by the fluid due  to gravity. G is gravitational acceleration
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    and H is the elevation of the fluid, which is  just its height above a reference level.
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    This is the pressure form of the equation,  but it can also be presented in the head form,
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    and the energy form. We can think of Bernoulli's
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    equation as a statement of the conservation  of energy. It says that along a streamline
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    the sum of the pressure energy, kinetic energy  and potential energy remains constant. This is
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    really valuable information that can help us  analyse a whole range of fluid flow problems.
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    The equation does have a few limitations,  which I'll cover later on in the video,
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    but for now the important thing to note is  that it can only be applied along a streamline.
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    We can define a streamline in steady flow as the  path traced by a single particle within the fluid.
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    Or more technically as a curve that at all points  is tangent to the particle velocity vector.
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    Let's look at an example where  we apply Bernoulli's equation
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    to flow through a pipe which has a change in  diameter. We want to use the equation to see
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    how the pressure changes as the flow passes  from the larger to the smaller diameter.
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    Bernoulli's equation is usually used to  compare the flow at two different locations,
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    so we can rewrite it like this, with points  1 and 2 both being on the same streamline.
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    There’s no significant change in  elevation between Points 1 and 2,
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    so the potential energy terms cancel each  other out. And if we put all of the static
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    pressure terms on one side we get this  equation for the change in pressure.
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    If we assume that the fluid is incompressible,  the mass flow rate at points 1 and 2
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    must be equal. This gives us what’s called the  continuity equation, which is just a statement
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    of the conservation of mass. Mass flow rate  is equal to the product of the fluid density,
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    the pipe cross-sectional  area and the fluid velocity.
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    So we can re-arrange the continuity equation to  obtain an equation for the velocity at point 2.
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    The cross-sectional area A2 is smaller than  A1, which means that the velocity of the
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    flow increases as it passes into the smaller  diameter pipe. This is quite intuitive.
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    By substituting this equation for V2 into  Bernoulli's equation, we can see that since the
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    velocity increases between Points 1 and 2, the  pressure between both points must decrease.
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    This concept, that for horizontal flow an  increase in fluid velocity must be accompanied
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    by a decrease in pressure, is one way of  formulating what we call Bernoulli's Principle.
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    It can seem counter-intuitive,  because people often expect an
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    increase in velocity to result in a  corresponding increase in pressure.
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    But it makes sense if we think about the  conservation of energy. The energy required
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    to increase the fluid velocity comes at the  expense of the static pressure energy.
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    Bernoulli’s Principle shows up  in a lot of different places.
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    We can use it to help explain how plane  wings generate lift. Fluid flowing over
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    an airfoil travels faster  than fluid flowing below it.
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    According to Bernoulli's Principle this creates  an area of low pressure above the airfoil and
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    an area of high pressure below it, and it’s  this pressure difference that generates lift.
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    I'll cover lift and drag forces in  more detail in a separate video.
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    Bernoulli's Principle also explains  how Bunsen burners work.
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    When the gas valve is opened, gas flows into the  barrel at high velocity. Following Bernoulli’s
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    Principle, this high velocity creates an area  of low pressure in the barrel, which draws
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    air in through the air regulator, allowing  for more complete combustion of the gas.
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    Several different flow measurement  devices rely on Bernoulli’s equation
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    to determine the velocity of a flowing fluid. The Pitot-static tube is one such device.
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    It’s often used in aircraft to measure  airspeed. Here’s how it works.
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    If we place a tube into a flowing fluid,  like this, and we attach a pressure meter
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    to the end of it, the meter will measure  the pressure at the end of the tube.
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    At this point the fluid velocity is reduced  to zero, so it’s called the stagnation point,
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    and the pressure measured by the meter  is called the stagnation pressure.
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    We can apply Bernoulli’s equation between  an upstream point and the stagnation point,
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    and show that the stagnation pressure is  equal to the sum of the static pressure
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    and the dynamic pressure terms. All of the  kinetic energy is essentially being converted
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    into pressure energy at the stagnation point. If we add an outer tube which is sealed at the end
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    but has holes further downstream, the outer tube  will measure the static pressure of the fluid,
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    instead of the stagnation pressure. These two pressure measurements give
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    us all of the information we need to  determine the velocity of the flow.
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    Another flow measurement device  that uses Bernoulli’s equation
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    is the Venturi meter, which is an instrument  used to determine the flowrate through a pipe.
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    It works by measuring the pressure drop  across a converging section of the pipe.
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    Say we want to determine the flow rate Q,  which is the velocity multiplied by the
  • 00:07:46
    pipe cross-sectional area at Point 1. We can  easily rearrange the pressure drop equation
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    we derived earlier when we looked at a change  in diameter, to get this equation for flowrate.
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    All we need to know is the  dimensions of the Venturi meter,
  • 00:08:05
    the fluid density and the pressures P1 and P2,  and that allows us to calculate the flowrate.
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    The Venturi meter has no moving parts  and is a very simple and reliable way
  • 00:08:17
    of measuring the flowrate through a pipe.  The diverging section is longer than the
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    converging section to reduce the likelihood of  flow separation and keep energy losses low.
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    Let's look at one more example where  we can apply Bernoulli's equation.
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    Say we have a beer keg, and we want to  calculate how fast will drain when we
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    first open the tap at the bottom.  All we need to do is define our two
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    points along a streamline and  apply Bernoulli's equation.
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    It’s a gravity-fed keg with a vent at the top,  meaning that it’s not pressurised. The pressure
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    at both points will be atmospheric, and so the  static pressure terms cancel each other out.
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    We can also assume that the keg  is large enough that the fluid
  • 00:09:07
    velocity at Point 1 is close to zero. If we rearrange Bernoulli’s equation,
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    and define the height between  the beer level and the tap as H,
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    we get this equation for the  beer velocity out of the tap.
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    Those were a few examples of cases where we  can apply Bernoulli's equation to get some
  • 00:09:30
    valuable information or to solve a problem. But to use it correctly, it’s important to have an
  • 00:09:36
    understanding of the limitations of the equation,  which arise because of how it’s derived.
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    There are several different ways  Bernoulli’s equation can be derived.
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    It can be derived based on conservation of  energy, by considering that the work done
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    on the fluid increases its kinetic energy. Or it can be derived by applying Newton's second
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    law, which involves determining the forces acting  on a fluid particle and applying F equals M*A.
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    Although I won't cover either derivation  here, they do both make some assumptions
  • 00:10:10
    that we need to be aware of, since they  limit how we can apply the equation.
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    Firstly the derivation of Bernoulli’s equation
  • 00:10:18
    assumes that flow is laminar and that it is  steady, meaning that it doesn't vary with time.
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    Next, it assumes that the flow is inviscid,  meaning that shear forces due to fluid
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    viscosity are negligible. This assumption  is needed because viscosity would result
  • 00:10:37
    in a dissipation of some of the fluid’s internal  energy, and so the idea that energy is conserved
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    along a streamline would no longer apply. And finally the derivation of Bernoulli's
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    equation assumes that the fluid behaves as if it’s  incompressible. This is usually valid for liquids,
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    but might not be for gases at high velocities. All three of these assumptions need to be valid if
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    you want to apply Bernoulli's equation. Adapted versions of the equation which can
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    be applied to unsteady and compressible flows do  exist, although they’re a bit more complicated.
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    Being able to recognise when Bernoulli’s  Principle is at play, or when Bernoulli’s
  • 00:11:25
    equation can be applied to solve a problem,  is a powerful tool in any engineer's arsenal.
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    If you'd like to see a few more real world  examples of Bernoulli’s principle in action,
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Tags
  • Bernoullis ekvation
  • flödesmätning
  • vätskeflöde
  • ingenjörsvetenskap
  • tryck
  • hastighet
  • Pitot-rör
  • Venturimätare
  • lyft
  • viskositet