ข้อมูลของบทความนี้จะเกี่ยวกับsyphon หากคุณต้องการเรียนรู้เกี่ยวกับsyphonมาถอดรหัสหัวข้อsyphonกับPopAsiaในโพสต์How a siphon (syphon) worksนี้.
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หุ้นที่เกี่ยวข้องกับหมวดหมู่syphon
คำอธิบายวิธีการทำงานของกาลักน้ำ (กาลักน้ำ) และสาเหตุที่ท่อไม่ว่างเปล่า สำหรับคำอธิบายทางเทคนิคว่าถังเก็บน้ำขับเคลื่อนการไหลของท่อที่ฐานถังได้อย่างไร โปรดดูที่:
รูปภาพที่เกี่ยวข้องกับหมวดหมู่ของsyphon
นอกจากการดูเนื้อหาของบทความนี้แล้ว How a siphon (syphon) works สามารถดูข้อมูลเพิ่มเติมได้ที่ด้านล่าง
คำหลักที่เกี่ยวข้องกับsyphon
#siphon #syphon #works.
siphon,syphon,empty,pipe empty,Hydraulics,Fluid dynamics,Water Engineering.
How a siphon (syphon) works.
syphon.
หวังว่าการแบ่งปันที่เราให้ไว้จะเป็นประโยชน์กับคุณ ขอบคุณมากสำหรับการดูเนื้อหาsyphonของเรา
Check out new content on this channel about the flume I built in my office:
https://youtu.be/sppaBqpIT-w
A good explanation but would disagree on a couple of points.
Firstly the vacuum wouldn't need to be perfect. If you connected a transparent vacuum chamber at the top with a larger volume than the section of tubing you would see the water from the top bucket pulled (or more accurately, pushed) up, accumulate at the bottom of the vacuum chamber and flow back down again. The section of "air" at the top of the vacuum chamber would have to remain below 1 atm enough for the atm at the surface of the top bucket to push water into the chamber. The mass of the height of the column of water going to the bottom bucket (along with gravity) preserves the vacuum below 1 atm.
The second point follows from the first in that the partial vacuum and water at the top section of the tube can be separated but this can never happen with just the tube itself but requires a separate break section with greater volume than the rest of the tube.
Stop clicking the pen lids on and off its very annoying!
3:00 “it’s trying to empty itself, but it can’t, because it creates a vacuum in the tube and the vacuum can only suck water until the water level drops below the entry to the pipe.
I got absolutely blasted off some Zaza and looked this up thanks for the explanation
Show how much energy we got by siphon at maximum level
Stp and ntp
Siphon under high or low pressure created more energy efficient???
Well explained.
I'm only watching because literally every series of taskmaster they try this and no one has yet to succeed.
Is the height from one body of water to another the cause of the vacuum strength for the suction or is it gravity
Hi and thanks for the video, but I have a question. Let's imagine a straight pipe from the tank, with a turn at 90 °, then a straight horizontal section of pipe, another turn toward the bottom at 90 ° again, and finally a straight vertical section of the pipe. I made the hypothesis that at the initial condition, the fluid in the pipe is at rest. So, I calculate the pressure at the inlet of the pipe into the tank Pe = rho * g * (Za + H – Ze) + Pair (where Za is the free surface altitude, Ze the altitude of the inlet of the pipe, and H is the distance between the free surface and the highest point on the vertical straight section of pipe because, in my opinion, all that height of fluid weighs on the inlet ?). So, I used the Bernoulli law and calculate the condition for having an outlet speed > 0. The result is that Zs < Za + H (where Zs is the altitude of the outlet). Am I right? Because I have seen also in a video that the condition should be Zs < Za, with a classical flexible pipe. Thanks in advance.
Than you for the wonderful explanation!!! <3
So, syphons wouldn't work in vacuum?
Thanks for the physics refresher. Actually used it to drain a pool at home.
I still don't understand the definition of the "pressure" of the water that allows it to flow via a siphon.
Is it correct to assume that the reason it continues to flow is purely because of the possibility of a vacuum that causes the exiting water to always drag the adjacent water out until equilibrium between the exterior environment and the environment at the point of entry to the siphon?
Thanks for making this video, its finally one that actually explains why this happens. Really appreciate it. :]
Thank you ❤️
Thanks from IND to UK …
Water level “haiche”.
This was really helpful, thank you!
This was actually a terrible presentation by any standard
I just bought a jiggle siphon but couldn’t sustain the flow. Now I realise the hose needed to be filled first.
you did not speak about siphon you spoke about placing the siphon pipe in top of the water tank what if we put the siphon in the same location of the first example?
can we use the siphon as a valve when the pressure is high the water will go when the pressure is low the water will stay? you did not answer that
and siphon has S-shaped you did not drew that
Thank you so much
super…………….
Christ. Thank you! It took like 5 videos before I found this one that didn’t just say “and then the water is sucked out”. WHY is the water sucked out. Finally someone actually answered, thank you.
I am currently working on a new hydraulics lesson series, using models and real world examples. The first part of the first lesson can be found here:
https://www.youtube.com/watch?v=EYvudBeHhWQ&list=PLgswUthJnnpDA5NLfqEZi6X46rkwwRec1&index=2
এটা বায়ু শূন্য স্থানে কাজ করে স্যার
rubbish ….the siphon should extend to the bottom of the tank….idiot.
Thanks!
Thank you very much, I mean it.
I cant unterstand
Please show how much workdone in joules
One meter higher one meter cubic water volume tank siphoning by a pipe of one inch to ground tank
Vise versa
How much workdone required?
I need your help please. I am trying to drain off some water from a flooded piece of land to an area that's about 1 foot higher. Can you recommend something please?
That pipe needs to reach to the bottom of the container to have the same pressure as the first container