Hi lollol,
I don’t disagree with anything here, but it all has to be taken in context with some understanding of Bernoulli’s and frictional flow losses which I don’t see anyone mentioning.
Bernoulli’s is only an idealized equation which doesn’t account for frictional flow losses. If you apply Bernoulli’s to a system such as arteries where the blood is going around in a circular route, there would be no need for a heart to pump the blood – the blood would just continue flowing by itself. Needless to say, something’s wrong with an equation that predicts perpetual motion.
According to bernoullli, assuming ideal flow, if you increase the area of a tube... vessel in this case, pressure increases as well
Note that this assumes:
1. The static pressure (sometimes called stagnation pressure) and velocity (or flow rate) at some location is constant between the two cases being compared.
2. The flow then enters a section of the arteries where the cross sectional area increases. Bernoulli’s alone would predict an increase in static wall pressure for the larger cross section. (This is not entirely true - see assumption 3.)
3. No frictional losses (ie: permanent pressure loss as predicted for example by the Darcy-Weisbach equation).
In a real blood vessel, or any pipe, assumption 1 is questionable as it depends on the entire system. If a restriction in the system is changed, then because there are other real considerations that go beyond what Bernoulli predicts, the system flow rate and pressure at any point can vary between the two cases. This is true for a variety of reasons. Note that assumption 3 is simply not true regardless and this is one source of error. Also, the heart, like many pump designs, will have some kind of variation with flow depending on the pressure difference between the inlet of the heart (pump) and outlet. This is what Russ is talking about when he says that Bernoulli’s is not a before and after comparison.
The pressure between the inlet and outlet of the heart can be increased by real restrictions throughout the system of arteries and blood vessels. But note here that Bernoulli’s equation alone doesn’t account for any permanent pressure drop. Bernoulli’s alone would say that, if the flow area of the artery going into the heart is the same as the flow area of the artery coming out of the heart, the pressure at those two locations will be the same. Reality simply isn’t like that.
Restrictions in the blood vessels due to clogging of arteries for example, increases the overall resistance to flow. In the real case which isn’t predicted by Bernoulli’s, this restriction to flow means that if the heart is to maintain a constant flow, the pressure the heart must generate will be higher when there is more resistance to flow.
Bernoulli’s isn’t wrong, it just doesn’t account for permanent pressure losses in any fluid system. Sometimes, neglecting this pressure loss is acceptable and leads to fairly accurate results, such as flow through a converging/diverging nozzle. Other times, neglecting permanent pressure losses leads to a total misunderstanding of what is happening as in the case of flow through a network of pipes or arteries. If you want to correctly model nature, you also need to take into account any permanent pressure losses in such a system. These permanent losses aren't predicted by Bernoulli's.
