Talk:Dynamic pressure

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R = 1716 what?[edit]

I can't figure out any units in which R=1716. I get 25.54 mbar/(°R·lb/ft³), for what it's worth. —Ben FrantzDale 16:00, 31 January 2007 (UTC)[reply]

It's 1716 ft·lb_f/(slug·°R). I'll add it in. 164.107.197.169 06:47, 9 February 2007 (UTC)[reply]

Usefulness of section: Alternative forms[edit]

What is the purpose of the formulas given in the section alternative forms? What use do they have? -- Crowsnest (talk) 14:54, 7 November 2008 (UTC)[reply]

Being unreferenced, and of no significant use (as far as I can see), I removed the following alternative form from the article:

Alternatively, considering for example a spacecraft during launch and using the formula for the air density as a function of altitude (only valid below the tropopause), the dynamic pressure associated with the spacecraft can be expressed as:^{[citation needed]} $q\ =\ {\frac {v^{2}\cdot p_{0}}{2\cdot R\cdot \left(T_{0}+L\cdot h\right)}}\cdot \left({\frac {T_{0}}{T_{0}+L\cdot h}}\right)^{\frac {g\cdot M}{-R^{}\cdot L}}$ where (using SI units): $q$ = dynamic pressure in pascals $v$ = spacecraft's velocity in m/s $p_{0}$ = atmospheric pressure at sea level in pascals $M$ = molecular weight of dry air (28.9644 g/mol) $R^{}$ = universal gas constant (8.31432×10³ N·m/(kmol·K) ) $T_{0}$ = absolute air temperature at sea level in kelvin $L$ = atmospheric temperature lapse rate (−0.0065 K/m) $h$ = altitude above sea level in m $g$ = acceleration due to gravity at the Earth's surface in (9.80665 m/s²)

You may put it back if you can provide reliable references and think it useful. Crowsnest (talk) 11:44, 13 November 2008 (UTC)[reply]

Velocity Pressure and Flow[edit]

I looked up Velocity Pressure and was directed to this page on Dynamic Pressure. I find these formulas a little confusing. I was expecting to find the formula for determining air velocity from velocity pressure. The formula I expected to see was V = 1096.7 * sqrt(Pv / density). I'm further confused with the use of Q or q to represent Velocity Pressure since everywhere else that I've looked Q or q is used to represent flow. I also expected to see how Velocity Pressure is measured (Total Pressure - Static Pressure = Velocity Pressure).

I don't know enough to know if these are mistakes or if it's a matter of mixed nomenclatures. In the latter case, I would expect to see seperate pages for Velocity Pressure and Dynamic Pressure. Steveandaugie (talk) 19:30, 18 March 2009 (UTC)[reply]

Hi Steveandaugie. In fluid dynamics, and particularly aerodynamics, dynamic pressure is a very important concept. It is always abbreviated q but I concede that in hydrodynamics q is often used for volume flow rate.

In hydrodynamics, and in low-speed aerodynamics, q is always defined as

{\frac {1}{2}}\rho V^{2}

. You can safely use this formula to calculate air velocity when you know air density and dynamic pressure (or velocity pressure), providing the air velocity is no greater than about 30% of the speed of sound.

You are correct in writing:

dynamic pressure = q = total pressure - static pressure

(In high speed aerodynamics, when Mach number becomes significant, it becomes a little more complicated. In the USA and elsewhere, the term impact pressure is introduced. This is often abbreviated q_c.)

Different abbreviations are often encountered in different countries, different fields, and among different authors. We all learn to live with that and use our favourite character, Greek or otherwise! Dolphin51 (talk) 22:42, 18 March 2009 (UTC)[reply]

Unit balance[edit]

Care should be taken in balancing units. I believe ${\tfrac {1}{2}}\rho V^{2}$ mentioned in the top of the article should not this as to get the units to come out a 9.81m/s² would need to be muliplied on the right hand side. —Preceding unsigned comment added by 208.250.9.26 (talk) 17:38, 22 April 2009 (UTC)[reply]

Dynamic pressure has the units of pressure. If

{\tfrac {1}{2}}\rho V^{2}

is evaluated using density units of kg/m³ and speed units of m/s the result will be kg/m/s² or kg.m/s²/m² which is the same as N/m² or Pa. These are units of pressure.

If

{\tfrac {1}{2}}\rho V^{2}

is evaluated using density units of pounds (mass) per cubic foot and speed units of feet per second, it is necessary to multiply by g₀ of 32.17 ft/sec² in order to get a result in pounds (force) per square foot. That is because the lbm and lbf are not consistent units with respect to the formula

{\tfrac {1}{2}}\rho V^{2}

. Dolphin51 (talk) 23:29, 22 April 2009 (UTC)[reply]

Thank you! you are correct. —Preceding unsigned comment added by 208.250.9.26 (talk) 21:19, 23 April 2009 (UTC)[reply]

Dynamic pressure equal to difference between stagnation and static pressures[edit]

The statement (referenced) on the page, "[t]he dynamic pressure is equal to the difference between the stagnation pressure and the static pressure" is not, s.s., true. It is a good approximation (how accurate does one wish to be?) but density variation becomes larger than about 5% after about Mach 0.3. The statement should be modified to read something akin to, "the dynamic pressure approximates the difference between the stagnation pressure and static pressure" (lobbing in the usual assumptions - time invariant, inviscid, irrotational, flows with gravity neglected, etc). See discussion page under Impact pressure, and/or talk page under Dolphin51's talk page on impact pressure. (Weirpwoer (talk) 16:07, 25 November 2009 (UTC))[reply]

I think the statement can be made completely accurate by changing it to: in incompressible flows, dynamic pressure ${\tfrac {1}{2}}\rho v^{2}$ is equal to the difference between the stagnation pressure and the static pressure. In compressible flows, dynamic pressure ${\tfrac {1}{2}}\rho v^{2}$ is a good approximation of the difference between stagnation and static pressures at low speeds, and is usually acceptable up to about thirty percent of the speed of sound. Dolphin51 (talk) 21:54, 25 November 2009 (UTC)[reply]

I wouldn't go so far as saying "completely accurate" as there is really no such thing as an incompressible flow which begs the question as to whether the words "equal to" should be used at all. I see where you're coming from, but it should be pointed out that this relationship is a convention and does not have a physical basis. Perhaps saying "is considered to be equal to" would be a safer position (noting the conditions). (Weirpwoer (talk) 15:44, 26 November 2009 (UTC))[reply]

Saying

{\tfrac {1}{2}}\rho v^{2}

is equal to the difference between stagnation and static pressures is a statement of Bernoulli's equation. I am not aware of Bernoulli's equation ever being described as total pressure is considered to be equal to static pressure plus dynamic pressure.

Similarly, Bernoulli's equation is analogous to the Law of Conservation of Energy. This Law is always expressed in terms of energy remaining constant, or the energy before an event being equal to the energy after the event. The Law is not expressed in terms of considered to remain constant or considered to be equal.

I think the notion that liquids are compressible (or are not incompressible) is unnecessarily esoteric for Wikipedia articles on dynamic pressure, Bernoulli's principle, and others in this series. Bernoulli's principle still commands the greatest respect from scientists even though it relies on the idea that liquids are incompressible and inviscid. Dolphin51 (talk) 21:43, 26 November 2009 (UTC)[reply]

It is a statement of the Euler-Bernoulli equation inasmuch as density is held constant along a common streamline. This is easily shown by integrating Euler's equation with density held constant. The statement must be made with that condition expressed. Whilst I ought to have included at the end of the first sentence of my last reply above the words "where the fluid in question is a gas", it should be reasonably understood (given the use of the Mach number and the ratio of specific heats elsewhere in the text) that the Euler-Bernoulli equation finds widespread use in aerodynamics. Your remark regarding liquids is quite acceptable concerning the assumption that density is held constant. However, NACA 837 (Langley, 1949?) does not state that dynamic pressure equals the difference between total and static pressures - this definition is reserved for Impact pressure as previously discussed - and given the dissimilar domains for the application of dynamic pressure it seems a safer bet to stress the associated condition.

As for the amendment to the article, if you're content with the following then I would propose it be inserted under the section on 'Physical meaning': [Dynamic pressure:] In incompressible flow, dynamic pressure is the difference between total pressure and static pressure. (Footnote: Glover, D. R., Jr.. (1965). NASA Aerospace Dictionary. Cleveland: NASA GRC.)

I would further propose the removal of the remark on controversy (not limited to British authors, in my experience!) under "Compressible flow," renaming "Compressible flow" to "Alternative forms of the equation" and modifying the introductory sentence from "...sometimes called velocity pressure or impact pressure..." to "...sometimes called velocity pressure or kinetic pressure..." leaving the term "impact pressure" to be mentioned under the "See also" section. (If including the text you've proposed, mentioning "...thirty percent of the speed of sound..." it might be prudent to specify also "in a perfect gas.") (Weirpwoer (talk) 03:13, 28 November 2009 (UTC))[reply]

Compressible flow[edit]

Putting the dynamic pressure equation in terms of the Mach number, $\gamma$ and static pressure under a Compressible flow heading is misleading. Acknowledging that the equation for dynamic pressure has limited usefulness at higher subsonic Mach numbers, it might be more appropriate to retitle this section as something like 'alternative forms of the [dynamic pressure] equation' and addressing any confusion between dynamic and impact pressures separately. (Weirpwoer (talk) 15:37, 26 November 2009 (UTC))[reply]

I agree. As I promised here, I will think about this over the next couple of days, and suggest a suitable way to rectify the errors I introduced by assuming

{\tfrac {1}{2}}p_{s}\gamma M^{2}

is significant for all Mach numbers. Dolphin51 (talk) 21:55, 26 November 2009 (UTC)[reply]

Could mention relevance to aircraft operation and rocket design[edit]

eg SR71 operations had to limit air speed at low altitudes due to a max-Q limit on the airframe, and during every SpaceX rocket launch the point of Max-Q is announced (as when the rocket is under max structural stress and risk) - Max-Q for most launches seems to come just after Mach 1 - not clear if by max-Q they mean max-drag (taking variable coefficient of drag (peaking around Mach 1) into account). - Rod57 (talk) 17:00, 22 September 2018 (UTC)[reply]

There is a Max Q article, if that helps you at all. Kees08 (Talk) 17:47, 22 September 2018 (UTC)[reply]

The NASA public affairs officer who gave running commentary for the Apollo and Space Shuttle launches explicitly explained it was reference to dynamic pressure (sometimes colloquially referred to as aerodynamic pressure). I'm sure NASA historical reports also define the term. Since the aerodynamic forces drag and lift (also present during a space vehicle launch) are proportional to dynamic pressure, maximum drag also coincidentally would occur at or close to the same point.

By the way, I believe "max Q" is improper capitalization because the parameter variable is invariably rendered as q, not Q. It should be "max q" and that article should be moved. JustinTime55 (talk) 13:57, 24 September 2018 (UTC)[reply]

Définition ?[edit]

It is stated : "Dynamic pressure is the increase in a moving fluid's pressure over its static value due to motion."

Shouldn't we say decrease ?

$P_{v}=P_{s}-{\frac {1}{2}}\rho v^{2}<P_{s}$

RadXman (talk) 21:08, 10 May 2020 (UTC)[reply]

Thanks for notifying us of the problem. The present wording has been in place since 27 June 2018 but it doesn’t match the cited source. I will restore some wording that is consistent with the cited source. Dolphin (t) 02:12, 11 May 2020 (UTC)[reply]

Total pressure is equal to static pressure plus dynamic pressure. Therefore it is correct to say that total pressure is the static pressure increased by the value of the dynamic pressure.

I have changed the lead to more closely resemble the cited source. See my diff. Dolphin (t) 12:24, 11 May 2020 (UTC)[reply]

When it's compressible[edit]

Impact pressure says "Expressing the incompressible dynamic pressure as $\;{\tfrac {1}{2}}\gamma PM^{2}$ " (emphasis added).

The present article has the identical equation — albeit with the preferable lowercase p nomenclature for pressure — as a result under the heading "Compressible flow".

Is that consistent? (Because it doesn't seem so.)

—DIV (137.111.13.4 (talk) 07:46, 11 November 2020 (UTC))[reply]

Inaccurate references[edit]

1) The quote "the dynamic pressure is equal to half rho vee squared only in incompressible flow." attributed to Houghton and Carpenter is not to be found in the Butterworth-Heinemann 2017 edition, and neither is there a Section 2.3.1. Gpsanimator (talk) 00:11, 9 May 2023 (UTC)[reply]

The cited source is the ~~1997~~ 1993 edition of Houghton and Carpenter. It isn't surprising that the 2017 edition is different. What would be surprising is if the sentiment of this quotation is not to be found in ~~Houghton and Carpenter~~ the 2017 edition - the background is that some authors (chiefly British authors) define dynamic pressure to be the difference between total (or stagnation) pressure and static pressure; in incompressible flow that is half rho vee squared. In contrast, some authors (chiefly North American) define dynamic pressure to be half rho vee squared for all flows, and therefore having relevance only in incompressible flows; these authors define the difference between total pressure and static pressure (in compressible flows) to be impact pressure or ram pressure. I suggest you look through the 2017 edition and see which of these two definitions is used. Feel free to create a new in-line citation based on the 2017 edition. Dolphin (t) 13:25, 9 May 2023 (UTC)[reply]

Necessary Revision[edit]

In the Physical Meaning section, it is said that "At a stagnation point the dynamic pressure is equal to the difference between the stagnation pressure and the static pressure, so the dynamic pressure in a flow field can be measured at a stagnation point."

This is not true. This should be changed to: "For incompressible flow, the dynamic pressure is equal to the difference between the stagnation pressure and the static pressure, thus dynamic pressure can be used to measure the flow velocity. Because the flow has no velocity at a stagnation point, the dynamic pressure at a stagnation point is 0, and the static pressure is equal to the stagnation pressure."

See this website for reference: https://www.princeton.edu/~asmits/Bicycle_web/Bernoulli.html#:~:text=Since%20the%20velocity%20at%20the,occurs%20at%20the%20stagnation%20point. 2600:1700:2BB0:6AB0:81F9:19C:66E2:EF69 (talk) 18:36, 20 December 2023 (UTC)[reply]