Your didactic methods are fantastic. For the first time in my life, I've understood why a crevasse rescue traditional Z-drag is 3:1. Everything has become clearer now, and I feel that I can more intuitively set up more complex hauling systems in the mountains when tired or stressed. Can't thank you enough.
@@TheRopeAccessChannel yeah seriously man, this stuff always just worked like magic to me, but now for big hauls I can actually understand whats going on
WOW So informative. I need to move some renovation materials up a hill. Your video has helped me design my pulley system. I'm 58 and never understood a pulley system and you made it so clear in 20 minutes! THANK YOU!!
I'm studying for a physics exam so probably not your target audience but still this video was incredibly clear and I think you are a great teacher! Awesome video!
Back again, such an incredible video. I had to skim through this a second time. Thanks a ton! Very interesting stuff. I really appreciate the effort you put into this, it's making me think a lot about what would be best for my situation. Thanks!
thanks a lot. l finally have a better understanding about how pully system works and way to arrange the pully stuff since l began to watch your videos.
(5:1,6:1,5:1) All the examples have a CD, if that CD wasn't important for the job, but you needed more MA, you could flip all of these "upside down" and gain +1:1. Just a fun fact of a CD. The last one gives the illusion of using the CD as advantage, but you'd still get more MA pulling with the load, as always. In all of them there is more MA to the anchor than the load. Anytime you pull against the load this is true, even if you try to cleverly "input" the CD into the system. Pullies are fun, I'm loving this series already.
Correct on all points and thanks for adding to the conversation🙏, Moving the CD into the system in the last example does add to the MA. That is not an illusion. We go from a 3:1 Simple to a 5:1 Complex. adding 1/5th of the load towards the anchor should put anything in the system in the danger zone. Otherwise I think you are rigging wrong anyway and have more pressing concerns. Same goes for the 3:1 CD by the way. I think the only reason to put a CD in is to make pulling easier or go in a direction we can get more hands on the rope (in horizontal movement). Otherwise a CD makes no sense. And pulling direction can make more difference than adding more MA. For instance a simple 2:1 with a CD where you pull down is easier to haul then a 3:1 pulling up. On paper switching the system around might seem "lighter" while in practice it is not. (when hauling in a vertical plane which I was drawing out here) Pullies are fun ;-)👊✌😀
@@TheRopeAccessChannel No doubt, agreed on all accounts. We're sort of speaking from different worlds is all. You use these things daily and are always thinking about the practical side of how you would use it in the real world. I'm just a nerd who loves pulley systems, the practicality is never a concern when I think about this stuff. Obviously if adding a CD is going to overload your anchors, you need to reconsider what you're doing. I just meant it as more of a mathematical statement, no matter how complicated you rig it, it's a "law of pullies", kind of deal, not that it's more practical to flip the rigging "upside down". It's sort of the same deal with the "illusion", perhaps I worded that poorly. Moving the CD from the anchor to the rope clamp definitely adds to the MA. The point I was referring to is it doesn't get you around the fact that adding a CD only adds to the MA to the anchor. You did go from 3:1 to 5:1, but you also went from 4:1 to 6:1 on the anchors. Even though you moved the CD from the anchor to an "input" of the system, it still shows up in the end, that's what I meant by illusion. It was just again reinforcing the idea that no matter how complicated you get, if there's a CD in the system, there's more MA to the anchor than the load. And again, purely as a mathematical/theoretical thing, not a "you should do this in the real world thing". I do need to remember this is a rope access channel and not a math channel, sorry about that. But, we're definitely on the same page here, we just might be reading the book in different languages.
@@richskater I see what you mean and in that context you are absolutely correct. You are putting more strain on the anchor point with a CD. But not as much as I how i read it. When I read (past tense) what you wrote it looked like we went from 4x the load on the anchor to 6x the load. My bad... Here is how I drew the situation out. We start with a 3:1 lifting, we add a CD because the direction of pull is easier and we can put our weight in it. A 100kg load in a 3:1 CD means in order to start moving the load, the anchor will see a little more than 132kg. As you said, a 4:1 on the anchor. 33x4=132 We want a little more MA and change it to a Complex 5:1 by moving the CD onto the rope. Turning that into the Complex 5:1 will make the load on the anchor less, it would be 120kg. Your general statement is true. Pull with the load and the anchor sees less than pulling through a CD. The way I see it is that if that little increase or decrease in force will blow out an anchor you have a lot more things to worry about! (Like you said). That is why we have safety factors in place right. But I am not a wilderness rope rescue tech working with cam placements to build anchors. When I work we are aiming for 15kN per anchor and we need two independent ones. Adding a couple of kilograms should not make a difference. It still is important to know though so like I said, thank you for adding to the conversation and giving valuable information 🙏🏼👊🏻🙏🏼
Thanks for all your video, it's really helpful for everyone. I will love to see a video about using an oversize harness and all the disadvantages wath comes with. I'm a lvl 1 rope access technician and I try to make a idea. Thanks
Great suggestion! But the answer is simple. Not comfortable and things like chest ascender positioning can be weird. Gear loops on the wrong places and maybe in case of an accident you might not last as long..
Hey buddy first and foremost I really enjoyed your video and benefited from it. In saying that, I'm having a lot of problems with the pull that I'm attempting. I know that you deal with rescues etc. but I'm begging you if you could help me maybe. I'm trying to pull a stump for a project that someone has paid for. Only thing is I don't have any heavy equipment. What I do have is a good amount of pulleys IE snatch blocks, 600 ft of 1 in line double braided of course, and a 12,000 lb winch with synthetic 3/8 line on it totaling in 100 ft. I have plenty of anchor to be able to anchor to I know all the safety stuff I know all the precautions and I know all the risks so please don't think that I'm trying to do something unsafe where you won't help me. Lol. What my question I guess is is with the winch, and the pulleys i have, along with the double braided line, what would be the most strong mechanical advantage I could achieve? I know by looking at watching your videos there are so many factors that come into play, and I'm not trying to I guess dumb you down to chime in on my pool and give your opinion at all I promise. But I have plenty of line for the distance between the angles would be barely if any and the friction I understand. Without all that in effect or taken into account is there a simple or compound system that you would recommend understanding as best you could on how I've described it? Again I know you're probably extremely busy and this is probably an annoyance, but I don't really think and can't honestly find anyone that seems knowledgeable as you are in this area. Hopefully I'll hear back from you.... Will Panama City Beach, FL. U.S.A. 🤙🏼
First question is cant you rent something designed for that? I have seen stumps fly and break stuff when doing that. The forces can get immense. If you make a 3:1 and have the 12 ton winch on it? or add a 3:1 and create a 9:1. You are theoretically pulling with 100+tons!!. Just be carefull. The forces are huge so make sure your prussiks of what ver you use as a rope clam dont damage the ropes. My advice is to not do it like this and rent a machine for a few hours..
You never fail to impress me. they try very hard. Thank you very much. 5:1 A... 5:1 B... 6:1 C... I'm really looking forward to the resolution in the next video. kind regards from Germany.
A: 5 to 1 simple. B, 4 to 1 compound. C, 5 to 1 complex. It’s a little sneaky, because the title of your video is simple pulley system is, but then at the very end you ask about compound and complex in the quiz. But hey I’m curious to read all the answers in your explanation in the next videos. Excellent presentation, thanks for putting this up. 🤙
It is not sneaky I think... I spend 15 minutes explaining Simple Pulley Systems. And then a little quiz with two teasers in there to just to get the mind to think on the other possibilities and tease a little for the next two video's of course ;-)
@@johngo-jl3uz the worst thing is I am not even going te explain the complex one. That is for the third video.😜. I’m sorry, I’m only giving bite sized pieces👊🏼
I appreciate what your doing I have been trying to have these conversations with ppl and find myself getting nowhere. Your bringing the information I need to have an informed understanding of MA
A 5:1; B 6:1; C 5:1. This was the first time I heard about complex pulley systems like in example C. So, I had to test it to confirm my calculations. I set a pulley system like in example C, I lift a load of 18 kg and "to stabilize" the system , I had to apply a "counter weight" of 3.5 kg. 18/3.5 = 5.14. For measurements, I used simple hanging spring scales that are not very precise ...
Thats a great way of finding out. Good test to get in the ball park. You got a tiny bit more than what the ideal mechanical advantage would be with a practical test, so I agree with you that the scales are not very precise. But for ballpark measurements definetely super good enough
Lets try! A) 5:1 B) 6:1 (3*2:1?) C) 5:1? Btw I want to thank you very much for your time and effort to create these interesting and educational videos. Looking forward for more. PS: C) is not as easy as I first thought but I will understand in the next video Im sure.
@@TheRopeAccessChannel ooh yeah, I just checked the web and I understood why I failed! Very nice videos! thank you a lot! some weeks ago I started making some R+D with an other rigger friend and we are doing similar things also with an LS3 and 2 simple load cells. and this videos help a lot to give us ideas and understand why sometimes we get strange numbers.
A: 5:1+CD B: 6:1+CD C: 9:1 Ideally with auto blocking integrated A is 5:1 and CD B Is 2:1 on 3:1 and CD (1/2×1/3=1/6) C Is 3:1 on a 3:1 super efficient (1/3×1/3=1/9)
@@NickyHendriksCheck out the top comment here for the answers: www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/ The how of it will be in next weeks video
Excellent content, delivery and explanations....however I'm still confused on when you 'add up' a system vs 'multiply' a system to get the MA. Watched this and next video several times and looked at comments: but don't see an explanation to C: of the first quiz.... how is it a 5:1? recently joined volunteer Fire service and recently learning these systems. can you point me toward answers of why C: is a 5 to 1? to be 5 it has to be product of addition ...yes?
Its been a while since I published this and I think C was more of a teaser of what was to come in later video's.. The T-method video should explain all of it. Globally (not the right English term) when you have an MA pulling on an MA you multiply and they move at different speeds. When they move in opposite directions towards each other you add up. That is for complex systems
For C the last pulley does move (mechanical advantage) but not same speed as load (compound) MA at the first rope grab is 3:1, and MA at the second rope grab is 2:1 so that makes it a 6:1
Great video. A, B, and, C. Well well, the change of direction is misleading and makes you want to say 4:1 on A? I'll have to watch it again ( of course). Thank you, Jim
Hi Jim, the correct answers are on the site: www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/ After next week you will understand the Complex one as well👍🏻👍🏻
Hello, respecfully as I am new to your channel. But is it not true that if there is only one rope tied to the load, regardless of multiply pulleys above load, should we not worry about strength of single rope when in one case mentioned, the forces to lift applied to upper portion of line we as only 25% of single line. And that would regardless of a jam situation. Thanks, but know it's a while ago, but great information.
There is some information getting lost in translation here. THe load is distributed over multiple strands of rope. The thing we should be mindful of is what happens at our anchor point. When the load would jam into something the forces of our pull are multiplied onto our load (which could be a casualty and cause bodily damage) or the anchor point. Does that answer you question?
Most cross hauls are done with a basic Z-Rig or 3:1 on each end. One lifts a bit and stops. the other end lifts then and the first end lowers out at one point. that would be the easiest description. Longer video will come next year... I just published a reel on IG showing a crosshaul.. instagram.com/p/C0hQ_hkote6/ Did that help??
Use the links in the description. If you want to sign up, maybe send me an email and I’ll get things going for you. Email address is on the site and here at RUclips
The last ons is incorrect. Check out the top comment here for the answers: www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
Almost got it. That last one though.... Check out the top comment here for the answers: www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
The answers are on the website: www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/#searchwp-modal-652ea0d21b1427a1bfa685e40d9bc1de
How did you do on the quiz?
Answers will be on the site on wednesday 😀
Your didactic methods are fantastic. For the first time in my life, I've understood why a crevasse rescue traditional Z-drag is 3:1. Everything has become clearer now, and I feel that I can more intuitively set up more complex hauling systems in the mountains when tired or stressed. Can't thank you enough.
Great to hear!
@@TheRopeAccessChannel yeah seriously man, this stuff always just worked like magic to me, but now for big hauls I can actually understand whats going on
WOW So informative. I need to move some renovation materials up a hill. Your video has helped me design my pulley system. I'm 58 and never understood a pulley system and you made it so clear in 20 minutes! THANK YOU!!
That is soo cool to hear! I love it! Glad it helped 😃
A.5:1
B.6:1
C.5:1
Tanks from Romania for all your videos .
You are welcome
I'm studying for a physics exam so probably not your target audience but still this video was incredibly clear and I think you are a great teacher! Awesome video!
Wow, thank you! That is great to hear!!
Alright this is the best video on explaining pulley ratios ive seen!
Great to hear, thank you🙏🏼🙏🏼🙏🏼
A 5:1
B 6:1
C 5:1
Hope and Nice Clip
👍🏻
Hi Alex - great video! A= 5:1CD simple, B = 6:1CD compound, C=5:1 complex
I'm not saying 😉😉. Solution in next weeks video
Smart arse 😂
Correct
Simple 5:1. Compound 6:1, and Complex 5:1. 🤘
👍🏻
Back again, such an incredible video. I had to skim through this a second time. Thanks a ton! Very interesting stuff. I really appreciate the effort you put into this, it's making me think a lot about what would be best for my situation. Thanks!
Thanks a lot, that is great to hear!!
A 5:1 CD, B: 7:1 CD, C: 6:1 thanks you for this video
My pleasure and almost, answers will be in next weeks video ;-)
Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
thanks a lot.
l finally have a better understanding about how pully system works and way to arrange the pully stuff since l began to watch your videos.
Glad it helped!! :-)! That is why I am doing it!!
(5:1,6:1,5:1) All the examples have a CD, if that CD wasn't important for the job, but you needed more MA, you could flip all of these "upside down" and gain +1:1. Just a fun fact of a CD.
The last one gives the illusion of using the CD as advantage, but you'd still get more MA pulling with the load, as always.
In all of them there is more MA to the anchor than the load. Anytime you pull against the load this is true, even if you try to cleverly "input" the CD into the system.
Pullies are fun, I'm loving this series already.
Correct on all points and thanks for adding to the conversation🙏,
Moving the CD into the system in the last example does add to the MA. That is not an illusion. We go from a 3:1 Simple to a 5:1 Complex. adding 1/5th of the load towards the anchor should put anything in the system in the danger zone. Otherwise I think you are rigging wrong anyway and have more pressing concerns. Same goes for the 3:1 CD by the way.
I think the only reason to put a CD in is to make pulling easier or go in a direction we can get more hands on the rope (in horizontal movement). Otherwise a CD makes no sense. And pulling direction can make more difference than adding more MA. For instance a simple 2:1 with a CD where you pull down is easier to haul then a 3:1 pulling up. On paper switching the system around might seem "lighter" while in practice it is not. (when hauling in a vertical plane which I was drawing out here)
Pullies are fun ;-)👊✌😀
@@TheRopeAccessChannel No doubt, agreed on all accounts. We're sort of speaking from different worlds is all. You use these things daily and are always thinking about the practical side of how you would use it in the real world. I'm just a nerd who loves pulley systems, the practicality is never a concern when I think about this stuff. Obviously if adding a CD is going to overload your anchors, you need to reconsider what you're doing. I just meant it as more of a mathematical statement, no matter how complicated you rig it, it's a "law of pullies", kind of deal, not that it's more practical to flip the rigging "upside down". It's sort of the same deal with the "illusion", perhaps I worded that poorly. Moving the CD from the anchor to the rope clamp definitely adds to the MA. The point I was referring to is it doesn't get you around the fact that adding a CD only adds to the MA to the anchor. You did go from 3:1 to 5:1, but you also went from 4:1 to 6:1 on the anchors. Even though you moved the CD from the anchor to an "input" of the system, it still shows up in the end, that's what I meant by illusion. It was just again reinforcing the idea that no matter how complicated you get, if there's a CD in the system, there's more MA to the anchor than the load. And again, purely as a mathematical/theoretical thing, not a "you should do this in the real world thing". I do need to remember this is a rope access channel and not a math channel, sorry about that. But, we're definitely on the same page here, we just might be reading the book in different languages.
@@richskater I see what you mean and in that context you are absolutely correct. You are putting more strain on the anchor point with a CD. But not as much as I how i read it. When I read (past tense) what you wrote it looked like we went from 4x the load on the anchor to 6x the load. My bad...
Here is how I drew the situation out.
We start with a 3:1 lifting, we add a CD because the direction of pull is easier and we can put our weight in it.
A 100kg load in a 3:1 CD means in order to start moving the load, the anchor will see a little more than 132kg. As you said, a 4:1 on the anchor. 33x4=132
We want a little more MA and change it to a Complex 5:1 by moving the CD onto the rope. Turning that into the Complex 5:1 will make the load on the anchor less, it would be 120kg.
Your general statement is true. Pull with the load and the anchor sees less than pulling through a CD.
The way I see it is that if that little increase or decrease in force will blow out an anchor you have a lot more things to worry about! (Like you said). That is why we have safety factors in place right. But I am not a wilderness rope rescue tech working with cam placements to build anchors. When I work we are aiming for 15kN per anchor and we need two independent ones. Adding a couple of kilograms should not make a difference.
It still is important to know though so like I said, thank you for adding to the conversation and giving valuable information
🙏🏼👊🏻🙏🏼
Thanks for all your video, it's really helpful for everyone. I will love to see a video about using an oversize harness and all the disadvantages wath comes with. I'm a lvl 1 rope access technician and I try to make a idea. Thanks
Great suggestion! But the answer is simple. Not comfortable and things like chest ascender positioning can be weird. Gear loops on the wrong places and maybe in case of an accident you might not last as long..
Hey buddy first and foremost I really enjoyed your video and benefited from it. In saying that, I'm having a lot of problems with the pull that I'm attempting. I know that you deal with rescues etc. but I'm begging you if you could help me maybe. I'm trying to pull a stump for a project that someone has paid for. Only thing is I don't have any heavy equipment. What I do have is a good amount of pulleys IE snatch blocks, 600 ft of 1 in line double braided of course, and a 12,000 lb winch with synthetic 3/8 line on it totaling in 100 ft. I have plenty of anchor to be able to anchor to I know all the safety stuff I know all the precautions and I know all the risks so please don't think that I'm trying to do something unsafe where you won't help me. Lol. What my question I guess is is with the winch, and the pulleys i have, along with the double braided line, what would be the most strong mechanical advantage I could achieve? I know by looking at watching your videos there are so many factors that come into play, and I'm not trying to I guess dumb you down to chime in on my pool and give your opinion at all I promise. But I have plenty of line for the distance between the angles would be barely if any and the friction I understand. Without all that in effect or taken into account is there a simple or compound system that you would recommend understanding as best you could on how I've described it? Again I know you're probably extremely busy and this is probably an annoyance, but I don't really think and can't honestly find anyone that seems knowledgeable as you are in this area. Hopefully I'll hear back from you....
Will
Panama City Beach, FL.
U.S.A.
🤙🏼
First question is cant you rent something designed for that?
I have seen stumps fly and break stuff when doing that. The forces can get immense.
If you make a 3:1 and have the 12 ton winch on it?
or add a 3:1 and create a 9:1. You are theoretically pulling with 100+tons!!. Just be carefull. The forces are huge so make sure your prussiks of what ver you use as a rope clam dont damage the ropes.
My advice is to not do it like this and rent a machine for a few hours..
You never fail to impress me. they try very hard. Thank you very much. 5:1 A... 5:1 B... 6:1 C... I'm really looking forward to the resolution in the next video. kind regards from Germany.
Wow, thank you!
Answer will be in next weeks video 👊🏻
Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
I wish you would test some of your pulley systems on me 😉
Gosh he’s so tall & dreamy too 😍
Haha, thank you for making my day 🙏🏼😃
A: 5 to 1 simple. B, 4 to 1 compound. C, 5 to 1 complex. It’s a little sneaky, because the title of your video is simple pulley system is, but then at the very end you ask about compound and complex in the quiz. But hey I’m curious to read all the answers in your explanation in the next videos. Excellent presentation, thanks for putting this up. 🤙
It is not sneaky I think... I spend 15 minutes explaining Simple Pulley Systems.
And then a little quiz with two teasers in there to just to get the mind to think on the other possibilities and tease a little for the next two video's of course ;-)
@@TheRopeAccessChannel OK, fair enough. I’m looking forward to your next episodes on compound and complex.
@@johngo-jl3uz the worst thing is I am not even going te explain the complex one. That is for the third video.😜. I’m sorry, I’m only giving bite sized pieces👊🏼
I appreciate what your doing I have been trying to have these conversations with ppl and find myself getting nowhere. Your bringing the information I need to have an informed understanding of MA
That is great to hear. Thank you🙏🏼😃🙏🏼
A: 5:1 w/ CD Simple
B: 6:1 Compound
C: 5:1 Complex
👍🏻
A 5:1; B 6:1; C 5:1. This was the first time I heard about complex pulley systems like in example C. So, I had to test it to confirm my calculations. I set a pulley system like in example C, I lift a load of 18 kg and "to stabilize" the system , I had to apply a "counter weight" of 3.5 kg. 18/3.5 = 5.14. For measurements, I used simple hanging spring scales that are not very precise ...
Thats a great way of finding out. Good test to get in the ball park. You got a tiny bit more than what the ideal mechanical advantage would be with a practical test, so I agree with you that the scales are not very precise. But for ballpark measurements definetely super good enough
Lets try!
A) 5:1
B) 6:1 (3*2:1?)
C) 5:1?
Btw I want to thank you very much for your time and effort to create these interesting and educational videos. Looking forward for more.
PS: C) is not as easy as I first thought but I will understand in the next video Im sure.
My pleasure, the solution will be in next weeks video ;-)
A) simple 5:1 with CD
B) compound 6:1 with CD
C) complex 5:1
👍🏻
Love your videos man. Keep it up. 🙌🏻
Appreciate it!
A=5 B=6 C=4 Very Nice video
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
@@TheRopeAccessChannel ooh yeah, I just checked the web and I understood why I failed!
Very nice videos!
thank you a lot! some weeks ago I started making some R+D with an other rigger friend and we are doing similar things also with an LS3 and 2 simple load cells. and this videos help a lot to give us ideas and understand why sometimes we get strange numbers.
That is great! If you have any questions you can always shoot me an email👍🏼
Thank you🙏👍
Welcome 👍
Great channel thanks for the very good videos
Thank you very much🙏🏼
great stuff! thanks
Thanks !
I really enjoyed
Glad you liked it👍🏻👍🏻😃
A: 5:1+CD
B: 6:1+CD
C: 9:1
Ideally with auto blocking integrated
A is 5:1 and CD
B Is 2:1 on 3:1 and CD (1/2×1/3=1/6)
C Is 3:1 on a 3:1 super efficient (1/3×1/3=1/9)
Almost got it. Answer will be in next weeks video ;-)
Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A) 5:1 CD
B) 4:1 CD
C) 3:1 CD
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
Placement of. Petzl Pro progressive capture traxion in the 20:10 configuration, please?
20:10 is the same as a 2:1 so only one pulley in play. Easy choice right.
Parabéns pela explicação. Muito bom.
thanks!!
A: 5:1
B: Not sure but I think 4:1
C: I think its a 3:1, the added rope clamp acts as a change of direction, nothing more if I understand correctly.
It does add something because it is moving ;-)
@@TheRopeAccessChannel yeah that was the part that was bugging me in the calculation 😅
@@NickyHendriksCheck out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
The how of it will be in next weeks video
Excellent content, delivery and explanations....however I'm still confused on when you 'add up' a system vs 'multiply' a system to get the MA. Watched this and next video several times and looked at comments: but don't see an explanation to C: of the first quiz.... how is it a 5:1? recently joined volunteer Fire service and recently learning these systems. can you point me toward answers of why C: is a 5 to 1? to be 5 it has to be product of addition ...yes?
Its been a while since I published this and I think C was more of a teaser of what was to come in later video's..
The T-method video should explain all of it. Globally (not the right English term) when you have an MA pulling on an MA you multiply and they move at different speeds. When they move in opposite directions towards each other you add up. That is for complex systems
good man, excellent video
cheers🙏🏼👍🏻
super useful, thank you
You are welcome!
@@TheRopeAccessChannel a 3 pulley system helped us empty a 200m2 roof full of lumber, squirrel nests and old trash in 2 days,. learned from you.
That is cool to hear !! :-)
A5:1 B5.5:1 C5:1
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
brilliant!!!
Thanks a lot 🙏🏻🙏🏻
For C the last pulley does move (mechanical advantage) but not same speed as load (compound)
MA at the first rope grab is 3:1, and MA at the second rope grab is 2:1 so that makes it a 6:1
And not in the same direction as the load making it a complex system.....
Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
And with a complex system we don't multiply
A: 5:1 simple system CD..B :6:1 Compound CD C: 5:1 Complex CD
Sounds about right
Great video. A, B, and, C. Well well, the change of direction is misleading and makes you want to say 4:1 on A? I'll have to watch it again ( of course). Thank you, Jim
Thanks Jim, the solution will be in next weeks video 👍🏻
Hi Jim, the correct answers are on the site:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
After next week you will understand the Complex one as well👍🏻👍🏻
Hello, respecfully as I am new to your channel.
But is it not true that if there is only one rope tied to the load, regardless of multiply pulleys above load, should we not worry about strength of single rope when in one case mentioned, the forces to lift applied to upper portion of line we as only 25% of single line.
And that would regardless of a jam situation.
Thanks, but know it's a while ago, but great information.
There is some information getting lost in translation here.
THe load is distributed over multiple strands of rope. The thing we should be mindful of is what happens at our anchor point.
When the load would jam into something the forces of our pull are multiplied onto our load (which could be a casualty and cause bodily damage) or the anchor point.
Does that answer you question?
Yes, and thank you so much for answering in a way that helped me get to that "got-it" understanding.
A: 5:1 B: 4:1 C: 5:1
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
Ouch, I fell. 😒
For you 😏
😂😂
Hahaha Finally got it hahaha. Thank you!!
@@TheRopeAccessChannel I have more if you want more just tell me to do More lines I can
A=5:1 B=4:1 C=3:1
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A=5:1 B=6:1 C=4:1? 🤓 great vid btw.
Thanks, answer in next weeks video!
Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A: 5-1
B: 6-1
C:9:1
That is incorrect.
You can find the answers here:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A 5:1 CD
B 4:1 CD
C 3:1 CD
Almost right. You got one wrong:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
Hi sir plz explain to team rescue cross hauling rescue plz would explain sir
Most cross hauls are done with a basic Z-Rig or 3:1 on each end. One lifts a bit and stops. the other end lifts then and the first end lowers out at one point. that would be the easiest description. Longer video will come next year... I just published a reel on IG showing a crosshaul..
instagram.com/p/C0hQ_hkote6/
Did that help??
A 5:1, B 4:1, C 6:1
For the answers
www.theropeaccesschannel.com/what-is-a-complex-pulley-systems-the-t-method-and-mechanical-advantage/
A is 5:1 system B is a 4:1 system and C one is a 3:1 system
Only A is correct. B and C are incorrect.
Answers are on the website👍🏼
A 5:1
B 6:1
C 5:1
hello man, I want to study Rope access technician level one, how can you help me to your or any institution. thank you.
Use the links in the description. If you want to sign up, maybe send me an email and I’ll get things going for you. Email address is on the site and here at RUclips
A) 5:1 B) 6:1 C) 6:1
Answers are on the website and in some of the comments. I don’t remember them of the top of my head ;-)
A is 5:1 number.
B is 4:1 and number
C is. 3:1
You can find the answers here:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A) 5:1 CD B) 6:1 CD C) 5:1
👍🏻
5.1
What is 5:1?
A - 5:1 .... B - 6:1 ...... C - 5:1 😄
👍🏻
6, 6, 9 🤷♂️
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A=5:1 B=5:1 C=5:1
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
5/1 4/1 3/1
I think it was 5:1
6:1
5:1
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
5:1, 6:1,9:1
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A 5:1
B 6:1
C 9:1
The last ons is incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
Almost got it. That last one though....
Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A: 5:1
B: 5:1
C: 5:1
It has been a while and I am pretty sure those answers are partially incorrect. You can find the answers on the site..
A 5:1 B 6:1 C 5:1
Correct:
If you want the answers, check out the top comment on this post:
bit.ly/3hM2Hai
A = 5: 1
B= 3 : 1
C = 3 : 1
Incorrect. Check out the top comment here for the answers:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/
A 5:1
B 6:1
C 5:1
Correct!
A= 5:1
B=6:1
C=5:1
The answers are on the website:
www.theropeaccesschannel.com/this-is-how-simple-pulley-systems-work-rope-access-rigging/#searchwp-modal-652ea0d21b1427a1bfa685e40d9bc1de