00:06 Mechanical properties of fluids explained with live experiment. 02:21 Fluids are divided into hydrostatics and hydrodynamics. 06:56 Fluid pressure is proportional to depth and acts in all directions. 08:53 Pressure and area are inversely proportional. 13:06 Derivation of pressure variation with depth in a fluid 15:21 Fluid pressure and forces are at play within a cylinder. 19:17 Water pressure increases with depth 21:10 Equal pressure by fluid in containers 25:17 Pressure of fluid depends only on height 27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container. 31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid. 33:05 Hydraulic lift operation and incompressible fluid 37:14 Hydraulic lift can easily multiply forces 39:00 Demonstration of Pascal's law using syringes 42:28 Understanding atmospheric pressure and its impact on us 44:26 Atmospheric pressure is equal everywhere 49:11 The relationship between density and pressure in fluids 51:07 Mechanical demonstration of atmospheric pressure and density 54:56 Understanding atmospheric pressure and buoyant force 56:49 Objects float or sink in fluids based on buoyant force 1:01:01 Archimedes' principle explains fluid displacement and buoyant force. 1:03:25 Design objects to displace as much water as possible to increase buoyant force. 1:07:15 Explanation of particle stability and kinetic energy 1:09:14 Surface tension is the property of the liquid. 1:13:27 Surface tension affects the spreading and sticking of particles. 1:15:22 Soap reduces surface tension 1:19:09 Understanding surface energy and tension 1:21:09 Surface energy is stored in a film of fluid when it is stretched. 1:25:07 Surface tension on a curved surface 1:26:51 Understanding access pressure and its impact on liquid and soap bubbles 1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble 1:33:12 The experiment demonstrates the impact of two layers in a soap bubble. 1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes. 1:39:04 Capillary action and its applications 1:42:33 Capillary action and determination of height using a capillary tube. 1:44:30 Derivation of height pressure formula 1:48:15 Discussing the height formula and ascending property in fluid mechanics 1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure 1:54:48 Explaining the concept of viscosity and its formula 1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics. 2:01:10 Mustard oil flows the fastest due to its low viscosity 2:03:02 Different liquids have different viscosities affecting their flow. 2:07:05 Viscosity is higher in thicker liquids with higher density. 2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions 2:12:49 Mechanical properties of fluid and its effects on rainfall 2:14:35 Explaining the concept of laminar flow in liquid mechanics. 2:18:26 Streamline flow is defined by the smooth motion of particles without intersection. 2:20:15 Stream line flow and its impact on velocity 2:23:50 Critical velocity is the threshold for flow transition. 2:25:47 Deriving the formula for critical velocity of liquid flow 2:30:16 Fluid flowing through a pipe follows the principle of continuity. 2:32:03 Explains the equation of continuity and its implications 2:35:55 Understanding unit volume and pressure energy in thermodynamics 2:37:53 Understanding the importance of Bernoulli's theorem in physics. 2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow. 2:44:31 Understanding work done by fluid and energy conservation 2:48:51 Fast moving fluids create low pressure 2:50:53 Demonstrating Bernoulli's theorem with live experiment 2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed. 2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples 3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow. 3:02:20 Calculation of water flow through a pipe
Mere bhai dhanywaad yrr ... 😊 Bhot khoje par koi diya nhi tha halaki ab to 2 hour dekh hi liya hai but 1 hour me bhi to bahot kuch padhna hai so thanks to give this time stamps
0:00 Introduction 1:44 Fluids 2:25 Hydrostatics 2:50 Hydrodynamics 3:56 Physics of Liquids or Hydrostatics Pressure 11:50 Application Of Pressure 12:50 Variation of Pressure with Depth (Derivations) 20:27 Hydrostatics Paradox 27:35 Pascal's Law 41:28 Atmospheric Pressure 56:20 Bouyncy 1:00:29 Law of Flotation 1:01:22 Archimedes Principal 1:04:36 Intra - Molecular - Bindings - Energy of Liquids 1:06:33 Surface Tension 1:12:24 Application 1:19:27 Surface Energy 1:23:43 Excess of Pressure on Curved Surface of Liquid Convex Meniscus Concave Meniscus 1:26:53 Execes Pressure Inside a Liquid Drop 1:34:16 Angle Of Contact 1:37:09 Capillarity 1:41:38 Accent Formula 1:50:46 Rise of liquid in a tube of insufficient length 1:53:39 Viscosity 2:03:40 Strokes Law 2:11:20 Importance 2:15:10 Tube of Flow 17:05 Stream Line Flow 2:19:23 Turbulent Flow 2:23:30 Critical Velocity 2:27:43 Equations of Continuity 2:34:58 Kinetic Energy 2:38:58 Bernoulli's Theorem 2:48:14 Easy Tip 2:55:06 Application 2:59:56 Velocity of Efflux
*TIME STAMP* 00:06 Mechanical properties of fluids explained with live experiment. 02:21 Fluids are divided into hydrostatics and hydrodynamics. 06:56 Fluid pressure is proportional to depth and acts in all directions. 08:53 Pressure and area are inversely proportional. 13:06 Derivation of pressure variation with depth in a fluid 15:21 Fluid pressure and forces are at play within a cylinder. 19:17 Water pressure increases with depth 21:10 Equal pressure by fluid in containers 25:17 Pressure of fluid depends only on height 27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container. 31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid. 33:05 Hydraulic lift operation and incompressible fluid 37:14 Hydraulic lift can easily multiply forces 39:00 Demonstration of Pascal's law using syringes 42:28 Understanding atmospheric pressure and its impact on us 44:26 Atmospheric pressure is equal everywhere 49:11 The relationship between density and pressure in fluids 51:07 Mechanical demonstration of atmospheric pressure and density 54:56 Understanding atmospheric pressure and buoyant force 56:49 Objects float or sink in fluids based on buoyant force 1:01:01 Archimedes' principle explains fluid displacement and buoyant force. 1:03:25 Design objects to displace as much water as possible to increase buoyant force. 1:07:15 Explanation of particle stability and kinetic energy 1:09:14 Surface tension is the property of the liquid. 1:13:27 Surface tension affects the spreading and sticking of particles. 1:15:22 Soap reduces surface tension 1:19:09 Understanding surface energy and tension 1:21:09 Surface energy is stored in a film of fluid when it is stretched. 1:25:07 Surface tension on a curved surface 1:26:51 Understanding access pressure and its impact on liquid and soap bubbles 1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble 1:33:12 The experiment demonstrates the impact of two layers in a soap bubble. 1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes. 1:39:04 Capillary action and its applications 1:42:33 Capillary action and determination of height using a capillary tube. 1:44:30 Derivation of height pressure formula 1:48:15 Discussing the height formula and ascending property in fluid mechanics 1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure 1:54:48 Explaining the concept of viscosity and its formula 1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics. 2:01:10 Mustard oil flows the fastest due to its low viscosity 2:03:02 Different liquids have different viscosities affecting their flow. 2:07:05 Viscosity is higher in thicker liquids with higher density. 2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions 2:12:49 Mechanical properties of fluid and its effects on rainfall 2:14:35 Explaining the concept of laminar flow in liquid mechanics. 2:18:26 Streamline flow is defined by the smooth motion of particles without intersection. 2:20:15 Stream line flow and its impact on velocity 2:23:50 Critical velocity is the threshold for flow transition. 2:25:47 Deriving the formula for critical velocity of liquid flow 2:30:16 Fluid flowing through a pipe follows the principle of continuity. 2:32:03 Explains the equation of continuity and its implications 2:35:55 Understanding unit volume and pressure energy in thermodynamics 2:37:53 Understanding the importance of Bernoulli's theorem in physics. 2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow. 2:44:31 Understanding work done by fluid and energy conservation 2:48:51 Fast moving fluids create low pressure 2:50:53 Demonstrating Bernoulli's theorem with live experiment 2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed. 2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples 3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow. 3:02:20 Calculation of water flow through a pipe
31:25 Yes 1:36:46 90 degrees 1:50:30 Liquid will stop at the top of the tube (Actually, the angle of contact or the meniscus will adjust itself to compensate for the length of the capillary tube)
sir i wrote a poem for u In the realm of knowledge, where wonders unfold, There stands a guide, inspiring and bold. Ashu Sir, a beacon in the scientific sea, Igniting curiosity with unwavering glee. With a passion for learning, he lights the way, A mentor in science, come what may. In the classroom, where ideas take flight, He nurtures young minds, pure and bright. Equations dance in the canvas of his class, A maestro of wisdom, making concepts amass. With patience as his ally and knowledge as his sword, Ashu Sir, our guide in this academic chord. Through atoms and galaxies, he charts our course, Fanning the flames of curiosity with a powerful force. In the laboratory of life, where discoveries stir, We're grateful for the lessons from our Ashu Sir.
Sir (P= P° + ρgh) (P° = 1.013 × 10⁵) hoga kyuki atmosphere hamesha force apply kar raha hai . We can say ∆P = ρgh . ρgh is gauge pressure but P is actual pressure I am a jee aspirrant and read it in many books and teachers
TIME STAMP 00:06 Mechanical properties of fluids explained with live experiment. 02:21 Fluids are divided into hydrostatics and hydrodynamics. 06:56 Fluid pressure is proportional to depth and acts in all directions. 08:53 Pressure and area are inversely proportional. 13:06 Derivation of pressure variation with depth in a fluid 15:21 Fluid pressure and forces are at play within a cylinder. 19:17 Water pressure increases with depth 21:10 Equal pressure by fluid in containers 25:17 Pressure of fluid depends only on height 27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container. 31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid. 33:05 Hydraulic lift operation and incompressible fluid 37:14 Hydraulic lift can easily multiply forces 39:00 Demonstration of Pascal's law using syringes 42:28 Understanding atmospheric pressure and its impact on us 44:26 Atmospheric pressure is equal everywhere 49:11 The relationship between density and pressure in fluids 51:07 Mechanical demonstration of atmospheric pressure and density 54:56 Understanding atmospheric pressure and buoyant force 56:49 Objects float or sink in fluids based on buoyant force 1:01:01 Archimedes' principle explains fluid displacement and buoyant force. 1:03:25 Design objects to displace as much water as possible to increase buoyant force. 1:07:15 Explanation of particle stability and kinetic energy 1:09:14 Surface tension is the property of the liquid. 1:13:27 Surface tension affects the spreading and sticking of particles. 1:15:22 Soap reduces surface tension 1:19:09 Understanding surface energy and tension 1:21:09 Surface energy is stored in a film of fluid when it is stretched. 1:25:07 Surface tension on a curved surface 1:26:51 Understanding access pressure and its impact on liquid and soap bubbles 1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble 1:33:12 The experiment demonstrates the impact of two layers in a soap bubble. 1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes. 1:39:04 Capillary action and its applications 1:42:33 Capillary action and determination of height using a capillary tube. 1:44:30 Derivation of height pressure formula 1:48:15 Discussing the height formula and ascending property in fluid mechanics 1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure 1:54:48 Explaining the concept of viscosity and its formula 1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics. 2:01:10 Mustard oil flows the fastest due to its low viscosity 2:03:02 Different liquids have different viscosities affecting their flow. 2:07:05 Viscosity is higher in thicker liquids with higher density. 2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions 2:12:49 Mechanical properties of fluid and its effects on rainfall 2:14:35 Explaining the concept of laminar flow in liquid mechanics. 2:18:26 Streamline flow is defined by the smooth motion of particles without intersection. 2:20:15 Stream line flow and its impact on velocity 2:23:50 Critical velocity is the threshold for flow transition. 2:25:47 Deriving the formula for critical velocity of liquid flow 2:30:16 Fluid flowing through a pipe follows the principle of continuity. 2:32:03 Explains the equation of continuity and its implications 2:35:55 Understanding unit volume and pressure energy in thermodynamics 2:37:53 Understanding the importance of Bernoulli's theorem in physics. 2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow. 2:44:31 Understanding work done by fluid and energy conservation 2:48:51 Fast moving fluids create low pressure 2:50:53 Demonstrating Bernoulli's theorem with live experiment 2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed. 2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples 3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow. 3:02:20 Calculation of water flow through a pipe
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kya laga tha kuch nahi likha 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This is probably the best one shot i have ever seen for this chapter!! thankyou so much sir 🫶 hats off to you and yes we want the deleted topics and left dervations too
Waise ye poora video mujhe chahiye tha😅...I like your videos ashusir...kyunki aapke alaawa aur koi nhi hai school ka padhane k liye...baki sab to NEET, JEE ke level ki videos provide krte hain❤❤
SIRR URGENT SIR final exams aane vale h we need more one shot with derivations for next chapters please make videos of that sir I am just depend on you for physics. really this series are helping us!!
00:06 Mechanical properties of fluids explained with live experiment. 02:21 Fluids are divided into hydrostatics and hydrodynamics. 06:56 Fluid pressure is proportional to depth and acts in all directions. 08:53 Pressure and area are inversely proportional. 13:06 Derivation of pressure variation with depth in a fluid 15:21 Fluid pressure and forces are at play within a cylinder. 19:17 Water pressure increases with depth 21:10 Equal pressure by fluid in containers 25:17 Pressure of fluid depends only on height 27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container. 31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid. 33:05 Hydraulic lift operation and incompressible fluid 37:14 Hydraulic lift can easily multiply forces 39:00 Demonstration of Pascal's law using syringes 42:28 Understanding atmospheric pressure and its impact on us 44:26 Atmospheric pressure is equal everywhere 49:11 The relationship between density and pressure in fluids 51:07 Mechanical demonstration of atmospheric pressure and density 54:56 Understanding atmospheric pressure and buoyant force 56:49 Objects float or sink in fluids based on buoyant force 1:01:01 Archimedes' principle explains fluid displacement and buoyant force. 1:03:25 Design objects to displace as much water as possible to increase buoyant force. 1:07:15 Explanation of particle stability and kinetic energy 1:09:14 Surface tension is the property of the liquid. 1:13:27 Surface tension affects the spreading and sticking of particles. 1:15:22 Soap reduces surface tension 1:19:09 Understanding surface energy and tension 1:21:09 Surface energy is stored in a film of fluid when it is stretched. 1:25:07 Surface tension on a curved surface 1:26:51 Understanding access pressure and its impact on liquid and soap bubbles 1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble 1:33:12 The experiment demonstrates the impact of two layers in a soap bubble. 1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes. 1:39:04 Capillary action and its applications 1:42:33 Capillary action and determination of height using a capillary tube. 1:44:30 Derivation of height pressure formula 1:48:15 Discussing the height formula and ascending property in fluid mechanics 1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure 1:54:48 Explaining the concept of viscosity and its formula 1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics. 2:01:10 Mustard oil flows the fastest due to its low viscosity 2:03:02 Different liquids have different viscosities affecting their flow. 2:07:05 Viscosity is higher in thicker liquids with higher density. 2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions 2:12:49 Mechanical properties of fluid and its effects on rainfall 2:14:35 Explaining the concept of laminar flow in liquid mechanics. 2:18:26 Streamline flow is defined by the smooth motion of particles without intersection. 2:20:15 Stream line flow and its impact on velocity 2:23:50 Critical velocity is the threshold for flow transition. 2:25:47 Deriving the formula for critical velocity of liquid flow 2:30:16 Fluid flowing through a pipe follows the principle of continuity. 2:32:03 Explains the equation of continuity and its implications 2:35:55 Understanding unit volume and pressure energy in thermodynamics 2:37:53 Understanding the importance of Bernoulli's theorem in physics. 2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow. 2:44:31 Understanding work done by fluid and energy conservation 2:48:51 Fast moving fluids create low pressure 2:50:53 Demonstrating Bernoulli's theorem with live experiment 2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed. 2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples 3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow. 3:02:20 Calculation of water flow through a pipe
Thank you so much sir perso hi mera physics ka paper hai ❤ mai is ch ke one shot ka kabse wait kar rahi thi finally aapne yeh video upload kar di😊😊😊😊😊😊
Hats off to your dedication sir 🙌. Literally enjoyed the session Along with wonderful experiments . I felt ki science padh rahe via experiments . We are lucky to live in this for having access of these information & teachers like you . Thank you so much for your efforts Sir😊. Keep smiling 😇 & keep shining ✨.
Thank you so much for such a lovely one shot. It was such a pleasure learning theory with experiments for concept clarity. Will be waiting for many more such one shots❤
Sir, viscosity does not depend upon the density. For example, oil is more viscous than water but less dense than water. If you put oil in water, it will float because of the density difference. When it comes to flow, water flows faster than oil.
In fluid dynamics, viscosity is the parameter to measure the thickness or thinness of any given fluid. Density is the measure of spaces between two particles in a given fluid. Viscosity and density are the characteristics of a fluid, but there is no direct relation between viscosity and density. @@jitendramishra3696
1:18:50 you said sphere has maximum surface area and every soap bubble tries to achieve max surface area. I may be wrong, but doesnt sphere have the least surface area to volume ratio ?
Sir, I want to thank you from the bottom of my heart , it's because of you that finally I am able to understand the applications of these principle's and laws ! otherwise I used to mug up things and didn't knew where to apply . Physics was never so clear before!
I am a jee student except all teachers i like your teaching skills that how you teach each and every topic by experimentally and that permanantly fixed in our mind i wish sir you teach for jee batches as well
1:53:28 , Sir kya iska mtlb ye hai ki at the top of capillary tube liquid will no longer be concave or convex? Which means liquid per koi bhi atmospheric pressure (from above) nhi lagega? Please Explain!
liquid at the top rise isliye ho rha he kyunki andar ka pressure zyada he....jab voh surface pe aata he toh liquid ka pressure atmosphere ke pressure ke equal ho jata he.....Aur jo convex and concave meniscus hoti he voh pressure difference ki wajah se hoti he...Aur yahan pe koi pressure difference he nhi isliye capillary tube will no longer be concave or convex....😄
Liquid rise isliye ho rha tha kyunki uspe pressure lag raha tha lekin jab wo surface pe pahunche ga to atmosphere pressure liquid pe lagne wale pressure to balance kar dega
30:00 yes sir i have noticed this just 2 days ago I just opened my room door and I saw that the curtains of my window are moving like they are pushing and I told this to my mom that I will ask my teacher about this and today you told me
00:06 Mechanical properties of fluids explained with live experiment. 02:21 Fluids are divided into hydrostatics and hydrodynamics. 06:56 Fluid pressure is proportional to depth and acts in all directions. 08:53 Pressure and area are inversely proportional. 13:06 Derivation of pressure variation with depth in a fluid 15:21 Fluid pressure and forces are at play within a cylinder. 19:17 Water pressure increases with depth 21:10 Equal pressure by fluid in containers 25:17 Pressure of fluid depends only on height 27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container. 31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid. 33:05 Hydraulic lift operation and incompressible fluid 37:14 Hydraulic lift can easily multiply forces 39:00 Demonstration of Pascal's law using syringes 42:28 Understanding atmospheric pressure and its impact on us 44:26 Atmospheric pressure is equal everywhere 49:11 The relationship between density and pressure in fluids 51:07 Mechanical demonstration of atmospheric pressure and density 54:56 Understanding atmospheric pressure and buoyant force 56:49 Objects float or sink in fluids based on buoyant force 1:01:01 Archimedes' principle explains fluid displacement and buoyant force. 1:03:25 Design objects to displace as much water as possible to increase buoyant force. 1:07:15 Explanation of particle stability and kinetic energy 1:09:14 Surface tension is the property of the liquid. 1:13:27 Surface tension affects the spreading and sticking of particles. 1:15:22 Soap reduces surface tension 1:19:09 Understanding surface energy and tension 1:21:09 Surface energy is stored in a film of fluid when it is stretched. 1:25:07 Surface tension on a curved surface 1:26:51 Understanding access pressure and its impact on liquid and soap bubbles 1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble 1:33:12 The experiment demonstrates the impact of two layers in a soap bubble. 1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes. 1:39:04 Capillary action and its applications 1:42:33 Capillary action and determination of height using a capillary tube. 1:44:30 Derivation of height pressure formula 1:48:15 Discussing the height formula and ascending property in fluid mechanics 1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure 1:54:48 Explaining the concept of viscosity and its formula 1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics. 2:01:10 Mustard oil flows the fastest due to its low viscosity 2:03:02 Different liquids have different viscosities affecting their flow. 2:07:05 Viscosity is higher in thicker liquids with higher density. 2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions 2:12:49 Mechanical properties of fluid and its effects on rainfall 2:14:35 Explaining the concept of laminar flow in liquid mechanics. 2:18:26 Streamline flow is defined by the smooth motion of particles without intersection. 2:20:15 Stream line flow and its impact on velocity 2:23:50 Critical velocity is the threshold for flow transition. 2:25:47 Deriving the formula for critical velocity of liquid flow 2:30:16 Fluid flowing through a pipe follows the principle of continuity. 2:32:03 Explains the equation of continuity and its implications 2:35:55 Understanding unit volume and pressure energy in thermodynamics 2:37:53 Understanding the importance of Bernoulli's theorem in physics. 2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow. 2:44:31 Understanding work done by fluid and energy conservation 2:48:51 Fast moving fluids create low pressure 2:50:53 Demonstrating Bernoulli's theorem with live experiment 2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed. 2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples 3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow. 3:02:20 Calculation of water flow through a pipe
Thank you, dear teacher, for being the guiding light in our educational journey. Your passion for knowledge, dedication to our growth, and unwavering support have sculpted not just our minds but our hearts. You've planted seeds of curiosity that will bloom into a lifetime of learning. Your impact is immeasurable, and we are grateful for the wisdom and inspiration you generously share every day❤❤
Sir In my home there is shop and there is a back door which is open inside my house when I close the door ,the sater of shop sound now I know why its sound, due to pascal law.😊😊😊
Ppt telegram pe daal di hai 🫡
Link : t.me/scienceandfun9th10th11th
Sir yeh pls app pe bhi dal do
❤❤
Hbbbb
Sir wave kab ho ga
sir solids ki bhi ppt daldo please
00:06 Mechanical properties of fluids explained with live experiment.
02:21 Fluids are divided into hydrostatics and hydrodynamics.
06:56 Fluid pressure is proportional to depth and acts in all directions.
08:53 Pressure and area are inversely proportional.
13:06 Derivation of pressure variation with depth in a fluid
15:21 Fluid pressure and forces are at play within a cylinder.
19:17 Water pressure increases with depth
21:10 Equal pressure by fluid in containers
25:17 Pressure of fluid depends only on height
27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container.
31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid.
33:05 Hydraulic lift operation and incompressible fluid
37:14 Hydraulic lift can easily multiply forces
39:00 Demonstration of Pascal's law using syringes
42:28 Understanding atmospheric pressure and its impact on us
44:26 Atmospheric pressure is equal everywhere
49:11 The relationship between density and pressure in fluids
51:07 Mechanical demonstration of atmospheric pressure and density
54:56 Understanding atmospheric pressure and buoyant force
56:49 Objects float or sink in fluids based on buoyant force
1:01:01 Archimedes' principle explains fluid displacement and buoyant force.
1:03:25 Design objects to displace as much water as possible to increase buoyant force.
1:07:15 Explanation of particle stability and kinetic energy
1:09:14 Surface tension is the property of the liquid.
1:13:27 Surface tension affects the spreading and sticking of particles.
1:15:22 Soap reduces surface tension
1:19:09 Understanding surface energy and tension
1:21:09 Surface energy is stored in a film of fluid when it is stretched.
1:25:07 Surface tension on a curved surface
1:26:51 Understanding access pressure and its impact on liquid and soap bubbles
1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble
1:33:12 The experiment demonstrates the impact of two layers in a soap bubble.
1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes.
1:39:04 Capillary action and its applications
1:42:33 Capillary action and determination of height using a capillary tube.
1:44:30 Derivation of height pressure formula
1:48:15 Discussing the height formula and ascending property in fluid mechanics
1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure
1:54:48 Explaining the concept of viscosity and its formula
1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics.
2:01:10 Mustard oil flows the fastest due to its low viscosity
2:03:02 Different liquids have different viscosities affecting their flow.
2:07:05 Viscosity is higher in thicker liquids with higher density.
2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions
2:12:49 Mechanical properties of fluid and its effects on rainfall
2:14:35 Explaining the concept of laminar flow in liquid mechanics.
2:18:26 Streamline flow is defined by the smooth motion of particles without intersection.
2:20:15 Stream line flow and its impact on velocity
2:23:50 Critical velocity is the threshold for flow transition.
2:25:47 Deriving the formula for critical velocity of liquid flow
2:30:16 Fluid flowing through a pipe follows the principle of continuity.
2:32:03 Explains the equation of continuity and its implications
2:35:55 Understanding unit volume and pressure energy in thermodynamics
2:37:53 Understanding the importance of Bernoulli's theorem in physics.
2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow.
2:44:31 Understanding work done by fluid and energy conservation
2:48:51 Fast moving fluids create low pressure
2:50:53 Demonstrating Bernoulli's theorem with live experiment
2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed.
2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples
3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow.
3:02:20 Calculation of water flow through a pipe
Appreciable 🎉❤
Mere bhai dhanywaad yrr ... 😊 Bhot khoje par koi diya nhi tha halaki ab to 2 hour dekh hi liya hai but 1 hour me bhi to bahot kuch padhna hai so thanks to give this time stamps
Thank you so much bhaii❤❤❤ much appreciated
I was missing youu😢
Sabka time bachanai kai liya tunai khud kaa kitna time waste kardiya
thankyou ❤
0:00 Introduction
1:44 Fluids
2:25 Hydrostatics
2:50 Hydrodynamics
3:56 Physics of Liquids or Hydrostatics Pressure
11:50 Application Of Pressure
12:50 Variation of Pressure with Depth (Derivations)
20:27 Hydrostatics Paradox
27:35 Pascal's Law
41:28 Atmospheric Pressure
56:20 Bouyncy
1:00:29 Law of Flotation
1:01:22 Archimedes Principal
1:04:36 Intra - Molecular - Bindings - Energy of Liquids
1:06:33 Surface Tension
1:12:24 Application
1:19:27 Surface Energy
1:23:43 Excess of Pressure on Curved Surface of Liquid
Convex Meniscus
Concave Meniscus
1:26:53 Execes Pressure Inside a Liquid Drop
1:34:16 Angle Of Contact
1:37:09 Capillarity
1:41:38 Accent Formula
1:50:46 Rise of liquid in a tube of insufficient length
1:53:39 Viscosity
2:03:40 Strokes Law
2:11:20 Importance
2:15:10 Tube of Flow
17:05 Stream Line Flow
2:19:23 Turbulent Flow
2:23:30 Critical Velocity
2:27:43 Equations of Continuity
2:34:58 Kinetic Energy
2:38:58 Bernoulli's Theorem
2:48:14 Easy Tip
2:55:06 Application
2:59:56 Velocity of Efflux
1:46:35 funniest movement😂😂😂
Yeah!! Mujhe khud k shaadi m nhi Jane ka mann th was epic!.💭
@@mahii_bb.😂
😂😂
1:46:27 Hats off Sir
Respect + 🫡
I never felt I was watching a 3 hour video. It went smooth and Crystal clear 😮💨
kl paper h naa tabhi dekhrii h 😂😂
acha tu bhi ye sb dekhti h kya mujhe lga instagram se fursat hi nhi milti
@@rishavranjan9429 😂😂 haat be.. Meh insta chalti bhi nahi.. Tu kab se mereko note karne laga.. Ek tho mereko unfollow karke rakha h😛
Ab to top maaregi....🤐
@@salonisingh763 pass hone de pahle 😂😂
Anyone is there in November 😅😅 watching this video
Yes bro
@@prathamprasad2009 same
Me in December
Us
Us
Anyone is here for March examination 2024
😭😭
How r u so accurate 😢
Brooooo I am in tension...17 chapters are coming 😔😔
Correct bro
Yes 😢
Worth to watch , deserves a lot of likes👍
*TIME STAMP*
00:06 Mechanical properties of fluids explained with live experiment.
02:21 Fluids are divided into hydrostatics and hydrodynamics.
06:56 Fluid pressure is proportional to depth and acts in all directions.
08:53 Pressure and area are inversely proportional.
13:06 Derivation of pressure variation with depth in a fluid
15:21 Fluid pressure and forces are at play within a cylinder.
19:17 Water pressure increases with depth
21:10 Equal pressure by fluid in containers
25:17 Pressure of fluid depends only on height
27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container.
31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid.
33:05 Hydraulic lift operation and incompressible fluid
37:14 Hydraulic lift can easily multiply forces
39:00 Demonstration of Pascal's law using syringes
42:28 Understanding atmospheric pressure and its impact on us
44:26 Atmospheric pressure is equal everywhere
49:11 The relationship between density and pressure in fluids
51:07 Mechanical demonstration of atmospheric pressure and density
54:56 Understanding atmospheric pressure and buoyant force
56:49 Objects float or sink in fluids based on buoyant force
1:01:01 Archimedes' principle explains fluid displacement and buoyant force.
1:03:25 Design objects to displace as much water as possible to increase buoyant force.
1:07:15 Explanation of particle stability and kinetic energy
1:09:14 Surface tension is the property of the liquid.
1:13:27 Surface tension affects the spreading and sticking of particles.
1:15:22 Soap reduces surface tension
1:19:09 Understanding surface energy and tension
1:21:09 Surface energy is stored in a film of fluid when it is stretched.
1:25:07 Surface tension on a curved surface
1:26:51 Understanding access pressure and its impact on liquid and soap bubbles
1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble
1:33:12 The experiment demonstrates the impact of two layers in a soap bubble.
1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes.
1:39:04 Capillary action and its applications
1:42:33 Capillary action and determination of height using a capillary tube.
1:44:30 Derivation of height pressure formula
1:48:15 Discussing the height formula and ascending property in fluid mechanics
1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure
1:54:48 Explaining the concept of viscosity and its formula
1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics.
2:01:10 Mustard oil flows the fastest due to its low viscosity
2:03:02 Different liquids have different viscosities affecting their flow.
2:07:05 Viscosity is higher in thicker liquids with higher density.
2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions
2:12:49 Mechanical properties of fluid and its effects on rainfall
2:14:35 Explaining the concept of laminar flow in liquid mechanics.
2:18:26 Streamline flow is defined by the smooth motion of particles without intersection.
2:20:15 Stream line flow and its impact on velocity
2:23:50 Critical velocity is the threshold for flow transition.
2:25:47 Deriving the formula for critical velocity of liquid flow
2:30:16 Fluid flowing through a pipe follows the principle of continuity.
2:32:03 Explains the equation of continuity and its implications
2:35:55 Understanding unit volume and pressure energy in thermodynamics
2:37:53 Understanding the importance of Bernoulli's theorem in physics.
2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow.
2:44:31 Understanding work done by fluid and energy conservation
2:48:51 Fast moving fluids create low pressure
2:50:53 Demonstrating Bernoulli's theorem with live experiment
2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed.
2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples
3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow.
3:02:20 Calculation of water flow through a pipe
🎉
you copied from him
1:04:37
27:52 Sir hydraulic break syllabus mai hai vo nhi hata plz like this comment guys to show comment 😢
Ya
1:46:35 mai to apni khud ki shaadi me nhi jaana chahta tha
Kaash nhi gya hota 😂😂
kash class 9 offline hota toh aj yeh din na dekh na padta
Sch m bhai. Ek saal jo barbaad hua uski vjh se aaj tk pareshaan h
One shot series is just fire 🔥
31:25 Yes
1:36:46 90 degrees
1:50:30 Liquid will stop at the top of the tube (Actually, the angle of contact or the meniscus will adjust itself to compensate for the length of the capillary tube)
Tum kV wadsar me padhti ho na?
@@harsittiwari474 hlo bro
31:24 yes sir maine notice Kiya hai
sir i wrote a poem for u
In the realm of knowledge, where wonders unfold,
There stands a guide, inspiring and bold.
Ashu Sir, a beacon in the scientific sea,
Igniting curiosity with unwavering glee.
With a passion for learning, he lights the way,
A mentor in science, come what may.
In the classroom, where ideas take flight,
He nurtures young minds, pure and bright.
Equations dance in the canvas of his class,
A maestro of wisdom, making concepts amass.
With patience as his ally and knowledge as his sword,
Ashu Sir, our guide in this academic chord.
Through atoms and galaxies, he charts our course,
Fanning the flames of curiosity with a powerful force.
In the laboratory of life, where discoveries stir,
We're grateful for the lessons from our Ashu Sir.
ChatGPT use karta hai
@@thelegend6132 😂😂
@@thelegend6132 The poem was amazing anyways!
yes@@thelegend6132
chatgpt se chaap karke likhna, aur khud se likhna alag hota hai be lodu
1:18:51 sir sphere has minimum surface area not maximum
Chalo kal physics ka paper hai aaj one shot aa gaya😂😂❤
Who came here to see this lecture in winter vacation 2024😉🥳 .........😅👍
Hey riya
31:30 Yes Sir Notice Kiya hai
1:30:53 ∆R= 0.001
1:36:50 Angle = 90°
1:50:44 Stop
Amazing series for our exams....that will help us Crystal clear our doubts...
Thank you ashu sir❤
Sir (P= P° + ρgh)
(P° = 1.013 × 10⁵) hoga kyuki atmosphere hamesha force apply kar raha hai .
We can say ∆P = ρgh .
ρgh is gauge pressure but P is actual pressure
I am a jee aspirrant and read it in many books and teachers
Brother what is your study routine??
TIME STAMP
00:06 Mechanical properties of fluids explained with live experiment.
02:21 Fluids are divided into hydrostatics and hydrodynamics.
06:56 Fluid pressure is proportional to depth and acts in all directions.
08:53 Pressure and area are inversely proportional.
13:06 Derivation of pressure variation with depth in a fluid
15:21 Fluid pressure and forces are at play within a cylinder.
19:17 Water pressure increases with depth
21:10 Equal pressure by fluid in containers
25:17 Pressure of fluid depends only on height
27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container.
31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid.
33:05 Hydraulic lift operation and incompressible fluid
37:14 Hydraulic lift can easily multiply forces
39:00 Demonstration of Pascal's law using syringes
42:28 Understanding atmospheric pressure and its impact on us
44:26 Atmospheric pressure is equal everywhere
49:11 The relationship between density and pressure in fluids
51:07 Mechanical demonstration of atmospheric pressure and density
54:56 Understanding atmospheric pressure and buoyant force
56:49 Objects float or sink in fluids based on buoyant force
1:01:01 Archimedes' principle explains fluid displacement and buoyant force.
1:03:25 Design objects to displace as much water as possible to increase buoyant force.
1:07:15 Explanation of particle stability and kinetic energy
1:09:14 Surface tension is the property of the liquid.
1:13:27 Surface tension affects the spreading and sticking of particles.
1:15:22 Soap reduces surface tension
1:19:09 Understanding surface energy and tension
1:21:09 Surface energy is stored in a film of fluid when it is stretched.
1:25:07 Surface tension on a curved surface
1:26:51 Understanding access pressure and its impact on liquid and soap bubbles
1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble
1:33:12 The experiment demonstrates the impact of two layers in a soap bubble.
1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes.
1:39:04 Capillary action and its applications
1:42:33 Capillary action and determination of height using a capillary tube.
1:44:30 Derivation of height pressure formula
1:48:15 Discussing the height formula and ascending property in fluid mechanics
1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure
1:54:48 Explaining the concept of viscosity and its formula
1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics.
2:01:10 Mustard oil flows the fastest due to its low viscosity
2:03:02 Different liquids have different viscosities affecting their flow.
2:07:05 Viscosity is higher in thicker liquids with higher density.
2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions
2:12:49 Mechanical properties of fluid and its effects on rainfall
2:14:35 Explaining the concept of laminar flow in liquid mechanics.
2:18:26 Streamline flow is defined by the smooth motion of particles without intersection.
2:20:15 Stream line flow and its impact on velocity
2:23:50 Critical velocity is the threshold for flow transition.
2:25:47 Deriving the formula for critical velocity of liquid flow
2:30:16 Fluid flowing through a pipe follows the principle of continuity.
2:32:03 Explains the equation of continuity and its implications
2:35:55 Understanding unit volume and pressure energy in thermodynamics
2:37:53 Understanding the importance of Bernoulli's theorem in physics.
2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow.
2:44:31 Understanding work done by fluid and energy conservation
2:48:51 Fast moving fluids create low pressure
2:50:53 Demonstrating Bernoulli's theorem with live experiment
2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed.
2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples
3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow.
3:02:20 Calculation of water flow through a pipe
1:27:45 excess pressure inside a liquid drop....
2:27:53 eqn of continuity
2:39:6 bernaulli theorm
well tried🙂
@YashGupta-vj6vc padh lo bro
..............
*************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************** kya laga tha kuch nahi likha hoga***************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************************
just want say thank you to ashu sir who made that much efforts to blew our mind with their concepts ❤
bhai aapne angrezi ki dhajjiyan uda di
@@JohnWick-c2z8h aayeeinn
1:01:21
Bouyan force ki wajah se hi dead sea me koi nhi dubta 😅
This is probably the best one shot i have ever seen for this chapter!! thankyou so much sir 🫶 hats off to you and yes we want the deleted topics and left dervations too
How many oneshot have u seen for this chapter 😂
Waise ye poora video mujhe chahiye tha😅...I like your videos ashusir...kyunki aapke alaawa aur koi nhi hai school ka padhane k liye...baki sab to NEET, JEE ke level ki videos provide krte hain❤❤
31:29 yes sir kiya hai
Aashu sir se accha physics 1 shot me koi nahi padhata
You are right bro ❤😂🎉
Jee in one shot
SIRR URGENT
SIR final exams aane vale h we need more one shot with derivations for next chapters please make videos of that sir I am just depend on you for physics. really this series are helping us!!
Already hai UA-cam pe
@@KittuSingh-el9hyaur oscillation and waves ka kya hoga
Oscillation hai bro but waves nhi h@@bloodfluid2331
Anyone is here for supplementary exam's 😢
Re exam 😢
Yes bro 😢😢
Yes😢
5 tarik ko ha
Present sir😅😢
Literally loved this session ❤❤
all the concepts are now crystal clear
lots of love to you sir❣❣
Radhe Radhe 🙏🚩
Bolo
Radhe Radhe...🙏🏻
@@hustling_ladka9 Radhe radhe
Hi
Hi
00:06 Mechanical properties of fluids explained with live experiment.
02:21 Fluids are divided into hydrostatics and hydrodynamics.
06:56 Fluid pressure is proportional to depth and acts in all directions.
08:53 Pressure and area are inversely proportional.
13:06 Derivation of pressure variation with depth in a fluid
15:21 Fluid pressure and forces are at play within a cylinder.
19:17 Water pressure increases with depth
21:10 Equal pressure by fluid in containers
25:17 Pressure of fluid depends only on height
27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container.
31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid.
33:05 Hydraulic lift operation and incompressible fluid
37:14 Hydraulic lift can easily multiply forces
39:00 Demonstration of Pascal's law using syringes
42:28 Understanding atmospheric pressure and its impact on us
44:26 Atmospheric pressure is equal everywhere
49:11 The relationship between density and pressure in fluids
51:07 Mechanical demonstration of atmospheric pressure and density
54:56 Understanding atmospheric pressure and buoyant force
56:49 Objects float or sink in fluids based on buoyant force
1:01:01 Archimedes' principle explains fluid displacement and buoyant force.
1:03:25 Design objects to displace as much water as possible to increase buoyant force.
1:07:15 Explanation of particle stability and kinetic energy
1:09:14 Surface tension is the property of the liquid.
1:13:27 Surface tension affects the spreading and sticking of particles.
1:15:22 Soap reduces surface tension
1:19:09 Understanding surface energy and tension
1:21:09 Surface energy is stored in a film of fluid when it is stretched.
1:25:07 Surface tension on a curved surface
1:26:51 Understanding access pressure and its impact on liquid and soap bubbles
1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble
1:33:12 The experiment demonstrates the impact of two layers in a soap bubble.
1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes.
1:39:04 Capillary action and its applications
1:42:33 Capillary action and determination of height using a capillary tube.
1:44:30 Derivation of height pressure formula
1:48:15 Discussing the height formula and ascending property in fluid mechanics
1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure
1:54:48 Explaining the concept of viscosity and its formula
1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics.
2:01:10 Mustard oil flows the fastest due to its low viscosity
2:03:02 Different liquids have different viscosities affecting their flow.
2:07:05 Viscosity is higher in thicker liquids with higher density.
2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions
2:12:49 Mechanical properties of fluid and its effects on rainfall
2:14:35 Explaining the concept of laminar flow in liquid mechanics.
2:18:26 Streamline flow is defined by the smooth motion of particles without intersection.
2:20:15 Stream line flow and its impact on velocity
2:23:50 Critical velocity is the threshold for flow transition.
2:25:47 Deriving the formula for critical velocity of liquid flow
2:30:16 Fluid flowing through a pipe follows the principle of continuity.
2:32:03 Explains the equation of continuity and its implications
2:35:55 Understanding unit volume and pressure energy in thermodynamics
2:37:53 Understanding the importance of Bernoulli's theorem in physics.
2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow.
2:44:31 Understanding work done by fluid and energy conservation
2:48:51 Fast moving fluids create low pressure
2:50:53 Demonstrating Bernoulli's theorem with live experiment
2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed.
2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples
3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow.
3:02:20 Calculation of water flow through a pipe
Ye sare topic, s 2024_25 mai aarhe h n kuch delete topic to ni h??
@@saritasahu664 delete topic kareye nahi vo jee ke syllabus mai hai
30:54 Yes Sir this happens in my room most of the time, whenever I opens my room's door the curtains flows to outward direction.
Ya this happens
Ya ya
Yes and i gwg acared for my life thibking its a ghost
Thank you so much sir perso hi mera physics ka paper hai ❤ mai is ch ke one shot ka kabse wait kar rahi thi finally aapne yeh video upload kar di😊😊😊😊😊😊
31:20 Yes, sir notice kia hai
1:18:59 Spheres have the least surface area for a given volume.
Nahi Bhai maximum
31:41 yes sir notice Kiya hai👍🏼👍
thanks a lot sir , this lecture was amazing , all the topics are covered in detail with live practicals without any time pass , hats off to you sir 🙌💥
R uhh frm orai?
@@gaming_hayato4269nope , but why did u ask this ?
Feeling accomplished and blessed after watching this oneshot ❤🔥
Vote for waves chapter 〰️〰️
Hats off to your dedication sir 🙌. Literally enjoyed the session Along with wonderful experiments . I felt ki science padh rahe via experiments . We are lucky to live in this for having access of these information & teachers like you . Thank you so much for your efforts Sir😊. Keep smiling 😇 & keep shining ✨.
buoyancy and archemede's are deleted or not in 2023 revised book.
@@tufgaming9730 hai syllabus me
@@learnwithnagma nahi hai pura check kia book ko bhee aur syllabus ko bhee.I think May be it is in cbse coz I have state board.
@@tufgaming9730 ok 👍
@@tufgaming9730but. bro book to dono me same hi lagti hai(NCERT) na pls confirm bata do hai ki nhi ?
31:28 Sir Yee Aap Hee Observe Kar Rahe Hoo Be Safe Aapke Ghar Mai Koi Negative Energy Hai Shayad 🤣🤣🤣🤣👍🏻
Thanks a lot sir for such a crystal clear explanation with interesting experiments!🙏🥰😊
1:46:34 "khud ki shaadi pe nahi jana chahta tha, kaash nahi gaya hota" 💀💀
Sir being harassed
1:46:27 sir jyada sach nhe bolte wrna mam khana nhe denge
Thank you so much for such a lovely one shot. It was such a pleasure learning theory with experiments for concept clarity. Will be waiting for many more such one shots❤
31:01 yes notice kiya h
I want to study from Ashu sir offline . The explanation with experiment is mind blowing , you can't feel bored in his class . Thankyou sir❤❤❤❤❤❤❤
All my doubt are clear now.... Thank you so much for one short sir...✨💗
Sach bolu tou experiments ki vajh se dekhne aayi hoo😂..love u sir ❤
Sir, viscosity does not depend upon the density. For example, oil is more viscous than water but less dense than water. If you put oil in water, it will float because of the density difference. When it comes to flow, water flows faster than oil.
no this is exceptional he
no this is exceptional he
no this is exceptional he
no this is exceptional he
In fluid dynamics, viscosity is the parameter to measure the thickness or thinness of any given fluid. Density is the measure of spaces between two particles in a given fluid. Viscosity and density are the characteristics of a fluid, but there is no direct relation between viscosity and density.
@@jitendramishra3696
I was waiting for this lecture as this chapter will come in my exams and I don't understand physics except Ashu sir thank you ❤🫶🏻
1:13:13 soaps❌ sabuns ☑️
Sir I am very excited for the new experimental chapter🌊🌊🌊🌊🌊
Me too
3:03:01 thank you so much sir ❤
31:25 yes sir i have noticed
Thank you so much sir....never stop this free content for us...❤❤❤
You explanation was just awesome...😊 thanku so much sir for your support
Kash schl teacher app ki trh padhate..
Thanku sir ❤
thank you so much sir for this amazing video god bless you, your family & your team☺💌
Instr ki I'd send kardo plz apne
🤣
🤣🤣
🎉
.
march section attendance here
Hey bro your exam was clear?
1:17:57 justice for bubble
sir this is a very long chapter and creates confusion in some topics but you helped me to counter those doubts and confusions. thank you sir💟
1:18:50 you said sphere has maximum surface area and every soap bubble tries to achieve max surface area. I may be wrong, but doesnt sphere have the least surface area to volume ratio ?
31:23 Yes sir notice Kiya hai
Finally the longest chapter completed 🎉
All thanks to you sir
Sir, I want to thank you from the bottom of my heart , it's because of you that finally I am able to understand the applications of these principle's and laws ! otherwise I used to mug up things and didn't knew where to apply . Physics was never so clear before!
I am a jee student except all teachers i like your teaching skills that how you teach each and every topic by experimentally and that permanantly fixed in our mind i wish sir you teach for jee batches as well
I THINK NO ONE CAN EXPLAIN LIKE THIS , IT IS LITERALLY AWESOME LECTURE!!!👌👌
Hats off to your dedication sir 🙌. Literally enjoyed the session Along with wonderful experiments
1:53:28 , Sir kya iska mtlb ye hai ki at the top of capillary tube liquid will no longer be concave or convex?
Which means liquid per koi bhi atmospheric pressure (from above) nhi lagega?
Please Explain!
Shape atm per depend nhi karata
liquid at the top rise isliye ho rha he kyunki andar ka pressure zyada he....jab voh surface pe aata he toh liquid ka pressure atmosphere ke pressure ke equal ho jata he.....Aur jo convex and concave meniscus hoti he voh pressure difference ki wajah se hoti he...Aur yahan pe koi pressure difference he nhi isliye capillary tube will no longer be concave or convex....😄
Liquid rise isliye ho rha tha kyunki uspe pressure lag raha tha lekin jab wo surface pe pahunche ga to atmosphere pressure liquid pe lagne wale pressure to balance kar dega
awesome you really did a great job man hats off to you
1:46:29. Truth revealed by Ashu sir
Good Luck for Your Final exams 😢
Thank you vamuu
Thank you sir for providing me a best one shot video❤❤
31:15 iska mtlb haunted jagah jaisa kuch nhi hota
dynamic lift is also present in new ncert
30:00 yes sir i have noticed this just 2 days ago I just opened my room door and I saw that the curtains of my window are moving like they are pushing and I told this to my mom that I will ask my teacher about this and today you told me
Kal mera paper hai or mai raat ke 12 baje padhne baithi hu
Thankyou sir to give this beautiful video ❤
POV:) Legends completing their syllabus one night before exam at 2x 😂
1:46:40 - Really sir...apko Reema mam itni buri lagti h😂😂
Papa se pucho apne kya hota hai shadi ke baad 😂
Learning in school ❌
Learning in UA-cam ✅
Who agree like it👍🏻
Sir ur teaching skills are inexplicable 👏👏
1:45:55 Reema mam ka msg AAGYA😂😂😂
Thank you sir for providing us best one shot and Demonstrations 😊❤❤
00:06 Mechanical properties of fluids explained with live experiment.
02:21 Fluids are divided into hydrostatics and hydrodynamics.
06:56 Fluid pressure is proportional to depth and acts in all directions.
08:53 Pressure and area are inversely proportional.
13:06 Derivation of pressure variation with depth in a fluid
15:21 Fluid pressure and forces are at play within a cylinder.
19:17 Water pressure increases with depth
21:10 Equal pressure by fluid in containers
25:17 Pressure of fluid depends only on height
27:26 Pascal's Law states that pressure applied to a closed container with fluid is transmitted equally throughout the container.
31:22 Pascal's law states that pressure is transmitted equally everywhere in a fluid.
33:05 Hydraulic lift operation and incompressible fluid
37:14 Hydraulic lift can easily multiply forces
39:00 Demonstration of Pascal's law using syringes
42:28 Understanding atmospheric pressure and its impact on us
44:26 Atmospheric pressure is equal everywhere
49:11 The relationship between density and pressure in fluids
51:07 Mechanical demonstration of atmospheric pressure and density
54:56 Understanding atmospheric pressure and buoyant force
56:49 Objects float or sink in fluids based on buoyant force
1:01:01 Archimedes' principle explains fluid displacement and buoyant force.
1:03:25 Design objects to displace as much water as possible to increase buoyant force.
1:07:15 Explanation of particle stability and kinetic energy
1:09:14 Surface tension is the property of the liquid.
1:13:27 Surface tension affects the spreading and sticking of particles.
1:15:22 Soap reduces surface tension
1:19:09 Understanding surface energy and tension
1:21:09 Surface energy is stored in a film of fluid when it is stretched.
1:25:07 Surface tension on a curved surface
1:26:51 Understanding access pressure and its impact on liquid and soap bubbles
1:31:09 Discussion on the formula for work done in a liquid drop and soap bubble
1:33:12 The experiment demonstrates the impact of two layers in a soap bubble.
1:37:04 Capillarity is the phenomenon where liquids rise in narrow tubes.
1:39:04 Capillary action and its applications
1:42:33 Capillary action and determination of height using a capillary tube.
1:44:30 Derivation of height pressure formula
1:48:15 Discussing the height formula and ascending property in fluid mechanics
1:50:32 The height of the liquid in a capillary tube is determined by the angle of contact and atmospheric pressure
1:54:48 Explaining the concept of viscosity and its formula
1:57:07 Understanding the concept of viscosity and its impact on fluid mechanics.
2:01:10 Mustard oil flows the fastest due to its low viscosity
2:03:02 Different liquids have different viscosities affecting their flow.
2:07:05 Viscosity is higher in thicker liquids with higher density.
2:08:59 Discussing the power of AT-1 and AT-2 with relation to dimensions
2:12:49 Mechanical properties of fluid and its effects on rainfall
2:14:35 Explaining the concept of laminar flow in liquid mechanics.
2:18:26 Streamline flow is defined by the smooth motion of particles without intersection.
2:20:15 Stream line flow and its impact on velocity
2:23:50 Critical velocity is the threshold for flow transition.
2:25:47 Deriving the formula for critical velocity of liquid flow
2:30:16 Fluid flowing through a pipe follows the principle of continuity.
2:32:03 Explains the equation of continuity and its implications
2:35:55 Understanding unit volume and pressure energy in thermodynamics
2:37:53 Understanding the importance of Bernoulli's theorem in physics.
2:42:39 Bernoulli's theorem explains the energy conservation in fluid flow.
2:44:31 Understanding work done by fluid and energy conservation
2:48:51 Fast moving fluids create low pressure
2:50:53 Demonstrating Bernoulli's theorem with live experiment
2:54:54 Swinging the ball in cricket depends on surface roughness and wind speed.
2:56:43 Fluid mechanics and Bernoulli's theorem explained with real-world examples
3:00:26 Bernoulli's equation relates velocity, pressure, and height in fluid flow.
3:02:20 Calculation of water flow through a pipe
Thanks a lot bro ... MERRY CHRISTMAS
(SHAURYA) Thala for a reason.......(7)
@@nasahens haa yeh karlo phele😂😂
Velle
@@itzjoey307 Abe iske vajah se humara time to bacha 😂😂
Ab samaj aaya windows aur door ka system itne saal se main yeh sochti thi ki aisa kyu ho raha hai ?????
How many 11th students are here in December??
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Me
Thank you so much Ashu sir exams arhe the aapne bacha lia ❤
Sir parcel aaya h , kisi bache ne comment section me aapke liye pyar bheja h 📢📢📢📢
Thank you, dear teacher, for being the guiding light in our educational journey. Your passion for knowledge, dedication to our growth, and unwavering support have sculpted not just our minds but our hearts. You've planted seeds of curiosity that will bloom into a lifetime of learning. Your impact is immeasurable, and we are grateful for the wisdom and inspiration you generously share every day❤❤
Thank you so much for this amazing lecture, sir :D
at 49:45 in statement it should be 1.01x10^5pa or 1.01x10^5nm-2 instead it is 1.01Nm, same goes for density
Sir In my home there is shop and there is a back door which is open inside my house when I close the door ,the sater of shop sound now I know why its sound, due to pascal law.😊😊😊
THERMAL PROPERTIES ONE SHOT BUTTON ❤️