ฝัง
- เผยแพร่เมื่อ 26 ม.ค. 2020
- This video describe the concept of Pitot tube. What it is? and How it helps to understand the concept of Stagnation and Dynamic Pressure? Also please suscribe for more fluid mechanics video. I will update more animated videos soon :)
![[UNCUT] ที่นี่ที่แรก ปู - หาญส์ พูดถึงมหากาพย์หนี้สิ้น I คนดังนั่งเคลียร์ I 10 ก.ค.67](http://i.ytimg.com/vi/KDNA9DZ0p4U/mqdefault.jpg)
When she said "Oh Look", I felt that
Felt what?
@@kwenheejo9008 Lmaooooooooooooooooooooooooooooo
@@kwenheejo9008 A little wired, is it?
@@user-ih2vt2pe9x yeah, still don't get it
Sorry to be so offtopic but does anyone know of a method to get back into an instagram account?
I stupidly forgot the login password. I would love any help you can offer me
I wish anyone loved me as much as she loved solving for the stagnation pressure XD
Yeh she do haha
"Look!!" 😲
"Now, solving the equation with those values we get... Oh... LOOK!"
Seriously, though, sweet illustration of pitot tube. Wish I had this for my Engineering Measurements class.
Thank you Falprofessional ^^ ..
@@NiLTime Lowe you
You are a lifesaver! Thank you so much for this video. Extremely helpful haha! Also when she said "Oh, look!" Ahahaha that was so cute xD
Thanks. The explanation was just perfect.
I was so confused about this topic, You've cleared everything up thank so much
Finally understood it. Thank you so much
this explanation is a masterpiece
Oh this is just perfect. Thanks for posting.
Wlc bro :)
I didn't understand exact concept while studying in book but now I got it .Thank you 🥺
Aww .. good to hear ^^
Wavoo.. What a great video.. Nice explanation.. Thank u
Thank you so much. Great explanation!
Keep up the excellent work. Look what you have done. Thanks
thank you so so so much! I really love it! Awesome intuitive presentation which will clear the concepts of thousands of students❤❤. We want more videos like these.
Really awesome concept thanks for uploading this video I wish this type of animation video if teachers teach like this in schools than it will be helpful for students and students imagination power will aslo be increased and this type of teachings can aslo helps students for further resarch in specific subject in future
ofcourse, I agree with you ^^
Excellent video
OMG ! You explain more clear than my teacher .
Very helpful and creepy video!
u made it soo simple to undetstand ,thanks on brhalf of the whole engineering community
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
.
..
Ek number
the great way of explaining...thank you
Welcome friend ^^
this is just what i was looking for, thank youu!
Good and Helpful Tutorial. Thank you.
Ooh look is great 😂😊😊😊
Damn good explanation ever! expecting more videos from you❤️
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
Awesome 👍 animation, explanation and whole presentation.
Great..love from Bangladesh ❤️
Wow your animation is osm
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
amazing explanation. thanks
Amazing it's clear my concept please more animation add for fluid mechanics it helps us
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
You are nailing it
Good explanation
excellent explanation
Wow what a wonderful explanation 🔥🔥🔥🔥
Thank you so much ^^
Thank you for this channel!
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
you saved my life
very nice explanation
Amazing, thank you
Nice video❤
Great
Thank you lady or mr whoever has created this video❤️
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
Finally understand what dynamic pressure is
it's very helpful. Thank you!
Wlc
Great way to explain an important principle.
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
.
Thank you, this is VERY helpful
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
Great 😍👍
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
Nice
Very good Explaination
Keep watching ^^
Good , thanks
Nice
Oh... Look... I subscribed
Madam..Thank you. I will use this video for my lecture.
ofcourse go ahead ^^
Awsome animation
Thanks ^^
Wonderful ❤️💜💙💚💛🧡
It's really more than my expectation
aww ... Thankyou ^^
thank you!
Perfect
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
Keep doing such work it is very helpful...
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
knsa mga taga cit diri? shawtout kang EC!
Thanks, very nice explanation
Glad it was helpful! ^^
very helpful video, thank you
Glad to hear ^^...
Nicely explained
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
I can not understand your language fully but your animation is sufficient for me to understand this function
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
really good
Thank you ^^
Excellent content and clear explanation for a video voiced by a bot!
Haha Thankyou ^^
Thank you itachi
Thank you
wlc dear ^^
Need more topics from you
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
2:04 ♥️ I felt that.. Oh look
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
fluid mechanics by itachi. my dream has come true. i had quick question, if say we have 6 pitot tubes in a large tube, can we use the velocity distribution on the pitot tubes, to calculate volumetric flow rate of the large tube? if so, how does one do this or how does one find a relationship between velocity going in the pitot tube to the pitot position distance. thanks once again itachi
If the Flow is in-compressible, steady, streamline (idle) then of course you can use Pitot tube to calculate velocity, using the derived equation. To get velocity, Just identify the pressure (use pressure gauge) at different point and use in the equn of pitot tube (to get velocity). Then you can use use Poiseuille's law to predict the volume flow rate of water through this large pipe. But in real life that's impossible, Turbulence is almost always a factor in larger pipes, as is friction caused by the interaction of the fluid with the pipe walls. So to calculate Volume flow rate and and average velocity, you need other parameter like Pipe Diameter, length, friction factor,pipe roughness etc.. Pipe are always designed, in accordance with the flow rate and pressure that it can handle.
@@NiLTime Thank you very much for your detailed answer. i have a follow up question. In the beginning of the video, you had connected 2 piezometer tubes. I am unsure on how the pressure in both the tubes are the same. Is it because of constant fluid velocity along the larger pipe? What if the velocity is different, would this differ the static pressures obtains in the two peizometer tubes? Also is there a video on your channel explaining the fundamentals of the peizometer tube? Thank you once again and i appreciate you taking the time to make such amazing videos^.^
PS- this is an edit. i found the piezometer head loss video on your channel. That explained my question above^. Thx. i am still a bit confused as to how would one find the total pressure at a peizometer tube, given the initial velocity at the inlet of the large pipe and the distance from the inlet the the pipe. Is there an equation that could do this or do we have to manually put a pitot tube directly below the peizometer in order to measure velocity and thus find the total pressure at that tap? I am considering a large pipe where there are 10 static taps with different heads and the flow is not steady that is two streams of unequal velocity are mixing together and since there is a pressure drop, will we have to keep a peizometer at each static tap in order to measure the velocity at that point or can we find velocity from the distance and initial velocities of the two streams.
@@emilymaze6616 In this video, Static pressure in both piezometer are same because the fluid is ideal and also have constant velocity. Increasing Velocity decreases static pressure and vice versa. If you consider friction then of course static pressure and dynamic pressure would decrease along the length of pipe.
For the next part, with piezometer you can only get static pressure, not total pressure. For total pressure use pitot tube. You can calculate local velocity at different point using combination of piezometer and a pitot tube. Pitot gives total pressure. Piezometer gives static pressure. subtract them to get velocity. You can also use "Pitot-Static" tube. It is more precise and donot require piezometer. Hope that helps and enjoy reading ^^ .
Thank u very much 🙏🙏
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
2:04 I lost it lmao
Intelligence girl... Thanks... 🇧🇩♥️
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
tq
mantop from dtp2b
انت بتجيب الأدوار دي منين روعة❤❤
It's good, but could have been much better if the concept of zero velocity at the entrance of pitot tube have been explained in detailed.
watch this then you will understand th-cam.com/video/CxqM_kkwgU4/w-d-xo.html :)
@@NiLTime thanx, I'll definitely see it
I have a question, in case tube measuring static pressure, the fluid level increase by its motion, using kinetic energy and come to stop, so why it not measure as total pressure?
When she said “V” when doing the calculations it was like when you say a nickname for someone with a name beginning with V
Mam if static pressure are same at both point then how water flow from 1to2 because i study water flow from high pressure to low pressure it my dout please solve
How do you calculate for the static pressure? ro*g*h?
One question, how about turn the pitot tube 180 deg? Tube pressure will become low, then P2=P(stag) - P(dyanmic)?
thanks ITACHI
Yo welcome :D ^^
What is 'datum' height at 1:54? And z1 and z2
Plz upload video on working of siphon tube!
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
🙂
Can we use the top of fluid level in pitot tube as a reference point instead of point 2
Good question
Please tell me what program did you use to do this animation video
Blender app .. XD
Static pressure from piezometer is calculated the( height of the piezometer till filled water)+ (hydrostatic pressure head)
Am I right?
uhm. sorry for the noob question, but what was the name of the first tube that measures static pressure? cant find it anywhere. im new to this btw
It's called "Piezometer". ^^
@@NiLTime thanks. ♥️
Is the piezometric tube similar to pressure gauge? Do both measure static pressure?
Why V2 = 0 ??
What happens to the formula if the medium IS compressible? Is there a negative multiplier?
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
.
when i see tough concepts: _AMATERASU_
That would burn everything haha ...
can someone explain why V2=0, fluid at point 2 is moving right? still cant understand the logic
bruh where u find that shit , thats so cool
what shit? 😂
why velocity at the entry of the tube V2 is equal to 0 ???
when water enter it's head .. it gets trapped and couldn't get out so they remains static... which means zero velocity. Please watch this video th-cam.com/video/CxqM_kkwgU4/w-d-xo.html
Itachi❤
This is great video but i dont understand somewhere which is V2 why is zero?
Hey consider watching this : th-cam.com/video/CxqM_kkwgU4/w-d-xo.html ^^
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
Pilots-- Dynamic Pressure= Impact Pressure-Static Pressure
How can the velocity at point 2 be zero, when it's clearly due to it's motion that it enters the pitot tube???
It enters due to its motion and stops suddenly at one point. Watch this video ://th-cam.com/video/CxqM_kkwgU4/w-d-xo.html :)
@@NiLTime thenks
th-cam.com/video/KZNMYV23sj4/w-d-xo.html
If the fluid stops, does it mean tube 2 will become similar as tube 1 ? Thank you
No. Tube 2 (pitot) will experience greater pressure than tube one. This greater pressure is dynamic pressure. Static pressure is similar on both tube.
@@NiLTime thank you but i dont quite understand… i understand what happen when the fluid is dynamic but i was trying to imagine what would happen if the fluid were static (i was asked that question in an exercice..) my thought were that if the dynamic pressure is experiencing in tube 2, in static condition tube 2 will experience drop pressure and the fluid level in the tube will drop too, but will it be the same level as tube 1 or there will be a différent level in both tube ? (I’m really sorry for my english, i hope what i’m saying is still understandable..)
@@emmadenisi1606 yeah. If fluid were static, both tube would have same pressure. In this case same static pressure. Watch this video. th-cam.com/video/2-jl2jObj4E/w-d-xo.html
Hi , why is the velocity at pt 1 = 0 ?
hey it's not point 1 ,its point 2. It's because the water velocity completely stops at point 2.