technical rescue

Well…it’s Carbon Monoxide (CO), so there isn’t a smell. But there is something interesting going on with the hose lines in this Supplied Air Breathing Apparatus system.

Air Line CO

115 PPM of CO !

 

While scouring the internet for all things pertinent to Rescue work, our newest member, Jimbo H, found an interesting after action report from LA County. Apparently, two firefighters entered a tank using SCBA to make a rescue of a downed worker. After about 15 minutes the firefighters switched from SCBA to Supplied Air; 3 minutes after the switch is when things started going downhill for them. An attentive  person working the communications kit noticed the firefighters breathing funny and started the process to get them out.

 

I’m not sure how they switched from SCBA to SABA. It’s possible they switched out their entire system while in the space, which seems like a bad idea. Or, they could have been using their SCBA and then just hooked up to their EBSS or URC from a remote source. If that were the case, the air from the remote source would seem to be the problem.

 

I’m not sure that the level of CO present in our hoses and in that small of a volume would cause the same problem as experienced in LA County, but it’s interesting to note that bad air can exist in the hoses.

LA County Blue Sheet

 

 

 

 

Check out this video sent to us by Francisco Palacios, owner of Ascendere SAS in Cali, Columbia. There seems to be a slight disagreement between the firemen and police on the scene of this training. What they are arguing over brings itself to light around the 00:46 mark.

There seems to be much debate about how to properly load the pulley on the track line. Ultimately the law does win, but they certainly are not right.

 

 

While there is great debate about whether the mirrored Two Tensioned Rope System (TTRS) using CMC Rescue Multi-Purpose Devices (MPDs) should or shouldn’t be the way to go, one argument seems to be more popular than others regarding it: If one of the lines should fail and the person operating the second MPD fails to let go, the load will have a catastrophic fall. This is a simplified statement that I feel sums up the majority of what the argument seem to be about.

 

Mirrored system run off the head of an Appalachian Doortex:

IMG_1008

What I find most interesting with this argument is that we now want to account for a SECOND point of failure i our system. What if: one rope is cut, one anchor blows out, etc… AND what if the belayer doesn’t let go, doesn’t realize the first line is compromised, etc…

No other system rope rescue system is viewed in this perspective despite the fact that any belay system can be overridden by an inattentive belay operator. So if we want to assume a second point of failure, do we need a third rope? Of course not; we need a fourth in case the third one goes. I’m kidding, of course.

The arguments seem to hinge on whether or not failure one causes failure two and if the nebulous “human factors” can be accounted for. It’s an acceptable thought, but again, we don’t apply this anywhere else in our rigging process. Otherwise we would have tertiary anchors and ropes for every main anchor and change of direction. While human factors that can affect performance and safety are certainly worth looking at, I find it difficult to see how they can be applied equally to ALL systems.

What I think this segues into is a topic of the BCCTR BCDT (or more correctly ASTM F2436-05) criteria and whether or not it needs to be changed. The MPD meets the BCDT criteria. So does a T3WP and a 540. Both of these can be overridden when in use, but meet the BCDT criteria. How do we apply an equal rule about not letting go (human factor) of a device during a belay event? I don’t think there is one. By simply doing what ever you can to make a device fail while operating it during a belay test will only lead to a witch hunt against whatever device you don’t like.

 

The pessimist in me wants to do a presentation at ITRS entitled “They all Suck. A look at modern belay Devices” Now of course I don’t believe that, but I think this is the area that you will get to if you try and account for human factors in a test. As a fireman, I’ve seen lots of ways people have gotten themselves in trouble and I am positive that the rope world is not ready to account for human ignorance as part of a test method. I think the line has to be drawn somewhere. To quote the great author Douglas Adams: “A common mistake that people make when trying to design something completely foolproof is to underestimate the ingenuity of complete fools.” A better idea, and one already in NFPA 1006 (make of that what you will), is to have people pass a competency test to operate a belay system.

But do we really need another test? We’ve got the BCDT to determine if the device is capable. We’ve got the “whistle test” to test our rigging if everybody were to let go. These two tests can be equally applied to a traditional main and belay system as well as a TTRS. Is there a way to devise a test that can be equally applied to every system? If there isn’t, then maybe now is the time to figure it out. If not then I think the arguments, while not pointless, will probably not be solved. I can stand on one side of the argument and talk until I am blue in the face that the the TTRS with MPDs meets all of our current criteria and somebody else can stand on the other side and talk about what will happen when somebody doesn’t let go of the handle.

Here is a suggestion for one (expensive) way to solve this problem:

 

2016-02-06 08.37.22

While the Petzl ASAP and L57 Absorbica are rated for two person loads for what Petzl calls “Accompanied Descent”, it is not shown in the instruction manual that you can attach it to the anchor to be used in the way shown in the picture above. I am extrapolating that it can be used that way. I have not tested this method yet, so I am only guessing as to its effectiveness. It is merely a possible solution to a problem that people have with an MPD based TTRS.

We get all off the benefits the TTRS has to offer as well as being protected from a runaway belay in the event of an inattentive operator.

 

Is an MPD based TTRS the be all, end all of rope rescue? Maybe, maybe not. But I do think it solves more problems than it causes. It also allows people who are required to perform rope rescue but don’t like it a safe way to operate, while at the same time allowing some unique options for the geek that a traditional slack belay system doesn’t allow.

After sharing a bunch of stories from around the world, here are two rope stories from the general where Rescue 2 Training is based out of.

 

The first story is of a cave rescue out of Monroe County, WV. The victim was approximately 4000′ inside of the cave when he fell approximately ten feet and broke his leg.  A mere 8 hours and 75 members later, he was back outside of the cave and on the way to the hospital. A picture from one of the local news stations shows just how much rope work went into this rescue.

I wasn’t there, so I feel a little bad about Monday Morning Quarterbacking it, but… A picture is just a snapshot of one small moment in time, but from looking at the picture, it seems that there were a couple of missed opportunities to tighten up the rigging a little bit. For starters, the double overhand safeties on the 8’s seems like a bit overkill. Additionally, the bights on the 8’s are overly long. And if clearance is an issue, and I assume it is being in a cave, why not just tie direct to the litter bridle with a scaffold knot and get yourself an extra 1′ or more of additional space?  Those minor quibbles aside, to looks like it was a difficult rescue and that they had to construct a highline in a cave just to provide a high anchor point to pull him up.

 

CAVE-RESCUE-jpg

 

Even closer to home is the report of a man who fell 75 feet down Sugarloaf mountain while hiking and then had a seizure. Being on the dividing line between two counties, both Frederick and Montgomery County units assisted with the helicopter evacuation flown by Maryland State Police. I’m not sure about Mont. Co, but I know for certain the the Frederick County ATR (Advanced Technical Rescue) team does perform regular drills with the MSP helicopters in order to perform on these types of calls without any confusion. If your agency has the potential to run extract calls with a helicopter, do you have any special training to make sure nothing goes wrong when the helicopter shows up?

 

From the Frederick ATR Facebook page (cool video there of rescuers perspective too):

sugarloaf hoist

 

 

An interesting point from the news interview in the link below: When asked if he would go hiking again, the man who fell said that he probably wouldn’t do it unless he go there proper footwear and even then, would only stay on the trail. That’s an interesting point that might be lost on most people who have no idea why they might have fallen. Good for him for being self aware!

http://www.fox5dc.com/news/local-news/26972833-story

 

 

 

sugarloaf

 

A department in Oregon was on the news for a rescue they accomplished when they rescued a kid who fell 50′ down a cliff while trying to retrieve a cell phone (thank goodness for job security). In the video footage win the link below, you can briefly see the setup they used during the actual rescue. The Fire Chief also took the opportunity of the news interview to have his guys using an Arizona Vortex at ground level for some good public education. Nicely done!

http://www.ktvz.com/news/crr-teen-seriously-injured-in-40-to-50foot-falll/35441476

 

If you are interested in upping your game on how to use the Arizona Vortex, we still have a few spots available for our Oct. 19 and 20 Modern Technologies in Rope Rescue class.  HERE

2015-09-24 10.08.31

The title of a “The Greatest Highline Ever” is being given to a group of people who probably knew very little about rope rescue as we know it and also probably wish they never had to set up this highline.

 

On May 11, 1945 an aircraft carrier called the USS Bunker Hill was near Okinawa, Japan supporting the invasion of Okinawa when it was struck by two kamikaze planes in quick succession. The ship was heavily damaged and the crew suffered massive casualties. 346 sailors and airmen were killed, 43 were lost at sea and never found, and 264 were wounded.

 

A light cruiser named the USS Wilkes Barre was one of several ships that came to the rescue. The Wilkes Barre was brought alongside Bunker Hill, with the Wilkes-Barre‍ ’​s bow placed hard against the Bunker Hill’s starboard quarter. The cruiser played 10 streams of water on the persistent fires, while 40 men, trapped astern in Bunker Hill scrambled to safety. Additionally, the injured were ferried to safety from one ship to another utilizing a highline. The title of “Greatest Highline Ever” goes to the “Greatest Generation”. Take a look at the pictures below and see if you agree.  Additionally, take 3 minutes to watch the Youtube video below. There is some really compelling footage of the actual attack as well as some pretty gruesome pictures of the aftermath. Let’s not forget the sacrifice these guys made.

bunker hill highline

 

Bunker Hill 2

 

Wounded Yorktown Crewman Transferred Via Breeches Buoy

 

It seems that despite the lack of American popularity, the technique of the “Kickoff Pickoff” is pretty widely used throughout the rest of the world. Take the video below, sent to us by Will Paces from NIPSTA, as an example. It’s the latest in a line of this “unique” style of rescue that we have presented here. Looks like a fun drill to practice at work! I don’t think I’d want to be the victim though.

 

Judging by the results of the technique, it would appear that speed and power are a vital part of making the “Kickoff Pickoff” technique work properly. Witness what happens when you pussyfoot around with the technique (I’m not sure why I can’t get the video to embed, but it is definitely worth watching):

 

 https://www.youtube.com/watch?v=2_Wsy_EF_JY

 

Not quite as high speed, but certainly just as interesting is this awesome pickoff grab of a guy who was caught midair and wrestled back over the railing. Quick acting by all parties involved!

 

 

 

 

You may have heard of it as many different names, but if you want to learn practical, well researched information on suspension trauma than you have before, take an hour and watch the video below. In it, Dr. Roger Mortimer, gives his take on what is actually happening to people who are hanging in a harness and why he thinks they sometimes die because of it. I had the pleasure of seeing Dr Mortimer present this at the International Technical Rescue Symposium. He’s a great great presenter without any qualification. As a doctor explaining medical stuff to a lay crowd, he’s surely the best in the business. He’s also a cave rescue guy and has spent his share of time in a harness.

Someone who was left hanging:

 

high five fail

The readers digest version of the big points:

– Death from hanging in a harness is caused by lack of victim movement, not the amount of time they are hanging.     Have the victim move their legs if they are able.

– Tell the hospital the victim has rhabdomyolysis and to prepare to treat them for that. It will save a lot of time and confusion on both sides.

– It’s okay to lay the victim down after they have been removed from rope.

Here is a link to the paper published in the Wilderness Medical Society Journal:

http://www.wemjournal.org/article/S1080-6032%2810%2900320-0/fulltext

 

 

 

 

We’ve had a huge demand to run this class again this spring, so we’ve finally added this open enrollment class to our calendar. Here is your chance to keep up on the latest equipment and trends in the rope rescue world.

Join us in Pennsylvania Dutch country for our latest presentation of Modern Technologies in Rope Rescue at the  Lancaster County Public Service Training Center on April 25 and 26 2015. Using the newest techniques on the newest equipment in an urban setting, come learn ideas that have been proven and tested in the real world in both urban and wilderness settings.

Topics included this time around include:

Use of the AZTEK kit to pass knots, perform a pickoff, basket attending, and a whole lot more.

In depth discussion and use of the Two Tension Rope System utilizing the MPD.

Use of  the Arizona Vortex  high directional in the urban environment.

The Rescue 2 Training original: The Appalachian Doortex! For urban anchoring and elevator rescue. High Directional? Anchor? Both!?… Come find out!

3 dimensional anchoring with the UFO.

The Skyhook capstan winch.

…And much more.

The cost of this two day, 16 hour class is $295 per person. Just bring a harness, helmet, and any ideas or equipment you would like to see used.

Please contact Kelly Byrne at 240-462-6610 or kelly@rescue2training.com for registration information or questions.

 

azorp gin poleIMG_0221IMG_0211

 

IMG_7687IMG_1428IMG_1415IMG_1419

Learning from others’ mistakes is something we can and should do, particularly when it pertains to rescue work. The situations below are prime examples of this. Take a minute to laugh a little at their misfortune (I’m pretty sure nobody died), but then try and absorb what happened and make sure it doesn’t happen to you.

The first example of things going bad could have been solved by a couple of easy solutions like: knowing how to tie a knot, having somebody who knows how to tie a knot look over your system, use a backup line that is tied with an appropriate knot, etc… There’s a trend there somewhere.

Knowing how your system is going to react when acted upon is a REALLY good skill to have when performing rope rescue operations. See if you can figure out what is going to happen in the video below when the helicopter pulls up to lift the rescue package:

 

Here at Rescue 2 Training we are pretty big fans of getting our rope systems up off of the ground for the edge transition. Combine a low rope over the edge with not knowing what your rope system is going to do when you load it (as mentioned above) and you have recipe for a bad time. Here is what the finished, face smashing product (and Bad Edge Transition Hall of Fame member) looks like when you pull it out of the oven: