I just have to say that these guides are pure gold for anyone interested in learning hydraulics. Im currently studying to become an hydraulic technician in norway. From reading my books, i learn very little. From your videos, a great deal. Even though it's in english and it can sometimes be hard to understand or follow since english is not my native language, you still speak straight to the point, explaining well and in funny ways which makes me laugh and having fun while learning contrary to being bored to death reading native language books and learning nothing. I have no previous experince or knowledge to hydraulics. But your method of teaching is so simple even a 10 year old could learn from you. Im going to continue watching everything and then perhaps move on to your electricity tutorials. Cheers.

there should be more lecturer like you. your expression and examples are enjoyable and very understandable. thanks for hydraulic context

I don't even wanted to watch whole video, but I get attached by your teaching skills. I like it!

Thank u very much for sharing quality educational videos Mr. Jim. Clear scams for relief v/v’s. Very clear explanation.

Fantastic Jim! Excellent for this beginner/novice. You Perfectly and concisely answered "All" my questions on this topic..Thank you!

Best intro music, I had ever seen.

I love All of your videos... Very knowledgeable

Slide @ 11:29 has numerous blockages on some of the channel ways that make the flow hard to understand. Also, i think there should be some sort of notation on the springs themselves, are they in a compression or tension scenario to make it easier to understand the physical forces on the springs. Some sort of Force vector arrow showing the amount forces. Spring force vs fluid force.

This guy is good thank you

Hi Jim. Thank you for this lecture. Helluvalot easier to understand than the 1 or 2 paragraph descriptions in the textbooks I found. As you mentioned, most valves are devilishly clever and require effort to understand properly. You're doing a great job. I'm into numerical simulations of coupled systems involving hydraulics and multibody dynamics at large time steps. In this context, poppets and small spools pose problems -- small masses, very small range, etc. -- so I use alternative modeling techniques suitable for large time step size. My current relief valve is an array of biased check valves with different opening area. What kind of (numerical) experiments should I do to figure out whether that's close enough to a pilot operated relief valve. My model has only a small difference between cracking and fully opened pressure and reacts instantly in simulation time. If you know what that means, it's a fixed step implicit method so the states are consistent at each step, without slowdown. Whether there's an actual poppet or not in the simulation is irrelevant, as long as I can figure out the overall equations and inequalities which capture the behavior. Also, could you perhaps construct a lecture about simulation software for hydraulics or even electronics and share your experience with and opinion of them? Most people studying your lectures will work with simulation software at some point -- everyday for many -- and as with anything else, much guidance is needed to choose the right package for a given job. With best wishes.

Excellent Jim!

Jim, you are awesome! Incredibly valuable information on your channel. I'm very grateful!

for the pilot operated relief valves, doesn't the orifice in the spool always ensure that the pressure is the same on both sides even if the pilot is opened to tank?

Thank you.....this helped me to a great extent

I like how you said "stupid pump"

I love the intel you pour in the explaining. As compared to many out there trying to tackle the same topics. With the following two questions I want to get deeper into explaining the "why"-s of the Pilot Operated Valve. Q: What in essence is different/better in the relief that the pilot offers? Is it just the small diameter of the orifice? Because of it being small, it senses the same pressure, while a much smaller force, allowing for a proportionally smaller spring dimension, therefore increasing the capacity of the valve?). Q: The associated decrease in the pressure override, is it because of the small volume and therefore time, it takes to refill the area upstream the orifice, after the pilot is extended back to the seat, once it has released the overpressure?

Thank s for great lecture

thanks for great lecutre...!

amazing video. thanks a million

This is insanely valuable! 😁 thanks🤗

Very good information...thank you very much

you are saving me!

Thank you. Fantastic

Jim, is the preset pressure equal to the cracking pressure?

Good info

Thank you sir

Jim, I can't understand why the pilot spring is a light biasing spring. Let's consider the pressure system 500 psi and the set pressure as 600 psi. In normal conditions, both sides of the spool and the dart fells the same pressure and the valve remains closed by the primary spring, right? Then, the pressure reaches 600 psi and the pilot spring open unbalancing the spool and the valve opens. Think this way the pilot spring must be a heavy biasing spring and there are no advantages over the direct pressure relief valve when thinking about the spring size and power.

Fantastic explantions, thanks a lot!

awesome.

Hi Jim, I am confused about how did you make the narrow pilot passageway in the pipe?

Sir, Please explain, relief valve with 3 numbers of pressure setting.

Please Jim can you tell me the exact difference between a differential area pressure relief valve and the normal direct acting poppet pressure relief valve ? Why is it called a differential area PRV ?

Why is the little orifice in the piston? Why can't it be an independent path to the poppet (e.g. like vent port).

thanks

Great!!

8:21

fluid gospel

not the stupid pump hahhaah

My lab partner sent me this 🤔?!

Some ai-generated lectures!!

stupid pump eh

Lengthy and overexplained for the begginer