Jump to content

Log in or register to remove this advert

rigging ropes


sethgill
 Share

Recommended Posts

Hi folks just wondering if anyone has any feedback my rigging ropes had it and was wondering if anyone knows of any deals, honey brothers are doing this Liros Rigging Rope on the link below at a good price but if its not any good I might just bight the bullet and buy a yale Yale Double Esterlon as I know they are good!

 

Liros Rigging Rope - 16mm

Link to comment
Share on other sites

Log in or register to remove this advert

  • Replies 24
  • Created
  • Last Reply

Top Posters In This Topic

Top Posters In This Topic

A lot of very good rigging lines out there I see the Liros is very static thats good if you are working with static loads but once you start working with dynamic falling timber things change so you need to work out what you want from your rigging rope. I lifted the following text from the Yale Cordage website I hope they wont mind.

 

Dynamic Energy in Arborist Rope - Arborist Rope | Yale Cordage

 

One of the most misunderstood aspects of rope selection is the disconnect between breaking strength and a ropes ability to absorb dynamic loads. Many people wrongly assume that the stronger a rope’s rating the harder it is to break. That is not the case as a rope can be parted if called upon to carry a load greater than its breaking strength or, if asked to absorb a dynamic load greater than its energy absorption capability.

 

Everyone is used to talking about a rope’s breaking strength but almost no one describes a rope’s energy absorption capability. This is obtained by studying a stress strain curve of load vs. elongation. The area described under the stress strain curve pertains to force acting through distance (or the work required to break it).

 

On the previous page you will find the bar graphs of our ropes’ dynamic characterists. The first shows each types’ working energy absorption which describes how much energy each will absorb before reaching its working load, which in the case of rigging ropes is 1/5 or 20% of its breaking strength. The more work the rope can do getting to 20% of breaking strength the longer it will last. A very stiff rope, with little or no elongation, gets to its working load without doing much work and quickly becomes loaded beyond its safe working load, regardless of how strong it is. These ropes are poor choices for rigging with the single exception where stretch cannot be tolerated, such as working with a zip line over a roof with limited clearances.

 

The second graph is of the lines ultimate energy absorption. This represents the amount of dynamic loading a line will take before it parts. If you subtract the working energy absorption from the ultimate it tells you how much reserve energy you have to play with. *See supporting graph on bottom of previous page.

 

A further complication is that these numbers are expressed as foot lbs/lb of rope in tension. So to calculate the rigged lines’ energy capabilities you need to know the length of the line that will bear the load.

 

A couple of examples may help:

 

Example 1 – We will use 5/8 diameter Double Esterlon line rigged into a tree with a block in such a way that 25 ft. of line is required to arrest a 500 lb section of trunk falling 5 ft. From the Double Esterlon specification table and energy graph we will need its weight of 13.7 lbs/100 ft or .137 lbs/ft, its green working energy absorption maximum of 544 ft lb per lb of rope in use, and its maximum recommended working load of 3,400 lbs.

 

First, we will calculate the ft lbs of energy needed to arrest the 500 lb trunk section falling 5 ft. The simple equation of the weight multiplied by the fall will get the result within 1%, so

 

• 500 lb x 5 ft = 2500 ft lbs.

 

Next, we will calculate the lines energy absorption capacity for a 25 foot length

 

• 25 ft x 544 ft/lb x .137 lb/ft = 1863 ft lbs.

 

 

From these two calculations we can see that in this scenario the maximum recommended energy absorption is exceeded by 637 ft lbs or 34% (2500 ft lbs / 1863 ft lbs). We can also estimate the load reached in the line multiplying the maximum recommended working load by 134% or

 

 

• 3400 x 1.34 = 4,556 lbs.

 

 

 

To illustrate the importance of energy capacity of ropes we will take a look at using a high energy absorption line.

 

 

 

Example 2 – We will substitute a 5/8 diameter Polydyne. Same diameter, but very different energy capacity. Doing the same calculations with Polydyne’s physicals we get the following:

 

 

• 500 lb x 5 ft. = 2,500 ft lbs. required

 

 

• 25 ft x 1040 ft/lb x .133 lb/ft = 3,458 ft lbs. capacity

 

 

 

In this case, we have reserve energy absorbing capacity of 958 ft lbs and the peak load in the line is estimated at:

 

 

• (2500/3458) x 3600 lbs = 2,602 lbs.

 

 

 

The more area in the stress strain graphs (green working and red ultimate) the higher the ropes ability to absorb dynamic loads.

Link to comment
Share on other sites

All very clever stuff but Im fairly sure the last thing I want is a rigging rope that is going to stretch then hit the targets im trying to avoid by rigging in the first place.

 

A fairly static rope with a good climber and a good groundie every time.

 

Otherwise if it has to get that technical just cut and chuck it.:thumbup:

Link to comment
Share on other sites

All very clever stuff but Im fairly sure the last thing I want is a rigging rope that is going to stretch then hit the targets im trying to avoid by rigging in the first place.

 

A fairly static rope with a good climber and a good groundie every time.

 

Otherwise if it has to get that technical just cut and chuck it.:thumbup:

 

I disagree recently did a big rigging job one tree with 2 climbers 2 grcs,s one line was similar to liros 16mm quite static, other I think was a Yale 13mm fairly dynamic, the Yale was a dream to lower with I didn't, even need gloves, it absorbed the shock the climber felt and didn't shake the tree, the give was very subtle we are not talking bungee rope here!

The static 16mm required much more running to ease shock loading with far more grip control/gloves.

 

The more static line was better for tensioning lines obviously, but using both side by side in that day made me appreciate that big static lines are not the be all and end all particularly when drop loading, yet still have a place and are good workhorse lines.

Link to comment
Share on other sites

Create an account or sign in to comment

You need to be a member in order to leave a comment

Create an account

Sign up for a new account in our community. It's easy!

Register a new account

Sign in

Already have an account? Sign in here.

Sign In Now
 Share


  •  

  • Featured Adverts

About

Arbtalk.co.uk is a hub for the arboriculture industry in the UK.  
If you're just starting out and you need business, equipment, tech or training support you're in the right place.  If you've done it, made it, got a van load of oily t-shirts and have decided to give something back by sharing your knowledge or wisdom,  then you're welcome too.
If you would like to contribute to making this industry more effective and safe then welcome.
Just like a living tree, it'll always be a work in progress.
Please have a look around, sign up, share and contribute the best you have.

See you inside.

The Arbtalk Team

Follow us

×
×
  • Create New...

Important Information

We have placed cookies on your device to help make this website better. You can adjust your cookie settings, otherwise we'll assume you're okay to continue.