Tuesday 9 December 2014

Associated Press (AP) Television - Man attempts world's largest Meccano model

"Weighing 1.3 tonnes, it took retired lecturer, Graham Shepherd five years to make his coal extractor model.  Measuring 12.5 metre long by 4.9 metre high (41 by 16 foot) Bagger 288 coal extractor is a labour of love."

Thursday 4 December 2014

Wikipedia article on Meccano: mention of Bagger 288

Wikipedia article on Meccano:

Excerpt:
......A contender for the largest model on record was built in 2014 by Graham Shepherd of Grahamstown, South Africa. The fully motorized Krupp 288 Bucket Wheel Excavator (as used on large opencast mining) is complete with auxiliary conveyors. Construction utilised Meccano parts as well as replica and strengthened parts (thickened profile plates and high tensile bolts in areas carrying large loads). Shepherd reports the model as being 1,335 kilograms (2,943 pounds) in mass and 17 ft tall. It required substantial timber support frames to facilitate final assembly..."

Wednesday 12 November 2014

World's Largest Meccano model??? View it operating - You Tube clip


CCTV AfricaPublished on Aug 2, 2014
If you're of a certain age, Meccano is definitely your childhood toy of choice. Well, a Meccano model builder in South Africa is attempting to break the record for the world's largest model. And by the look of things it just might be: (commentary by Tatchell Venn (Meccano Historian[pictured below])

Thursday 11 September 2014

Miscellaneous pictures (29-35)

Cable sling from bucket wheel arm to central unit (motor/roller of conveyor in bucket wheel arm behind

Upper roller rail on rotating torus, showing pair of anti-toppling wheels

From below (floor-level) looking up at from of conveyor belt

Similar to previous view


And another shot

Another thruster drive

Official ThyssenKrupp outfut kindly presented to me by Mr Klaus-Peter Mueller, Managing director ThyssenKrupp Materials Handling, Johannesburg at a lunch function in Johannesburg in July 2014!

Miscellaneous pictures (21-28)

Anchor blocks for 8mm threaded rods supporting counterbalance arm

Slewing motor for service crane to winding drum area

Winding drum over service crane

Lounge furniture restored in a small triangular nook of lounge!
View past fireplace

Lounge furniture again!

View of driver's cab from below

Bucket-wheel protruding into family room

Miscellaneous pictures (13-20)

Stage walkway on an upright

More stairways

Closed cage ladders going up an upright

More closed cage ladders
Mining company and machine ID

Driver's cab (right)

Cable sling to driver's cab

Maker's nameplate

Miscellaneous pictures (1-12)

Anchorage of a 25x3 mm strip below a support fin to prevent possible splaying of toroidal mainframe

2 and 1/2 " diameter brass bush to maintain parallel planes of lower plate of main fin and bridge support of crawlers

Steering thruster to swing a group of 4 main crawlers on central unit (note strong cantilever for delivery arm support)
Another view of the anti-splay mechanism

Stabiliser device to help prevent bridge supports rocking (aluminium collars & M12 thread rods)

More stairways on central unit
Motor/gearbox driving a double-sided winding drum which positions final delivery cross-slider on auxiliary unit.

Booster motor/roller in centre of 20 foot static conveyor

Cable sling to offloader arm
35 kg of concrete blocks at end of counterbalance arm

View of main winding drums from below (showing 4 drive motors)

Swivelling cable sling to offloader

Monday 8 September 2014

Some postscripts



A video clip (about 6 minutes) of the model  has now been made  (by Neil Shaw, an independent film-maker from Cape Town) showing the various motorisations working (traversing back and forth, slewing of upper arms, raising and lowering of bucket when arm rotation of bucket wheel, and all 6 conveyor belts running (including static conveyor of 20 foot).  All the minor movements (accuated with a total of sixteen 6 volt Meccano motors) are also featured (5 service cranes, and up and down movement of front driver’s cabs).  This clip is now owned by AP (Associated Press) and will be sold to about 300 TV stations worldwide.  These stations then have the right to edit the clip for their own use. A short version (about 1 minute) has already appeared on YouTube.
I am happy to say that the final assembly went well with no mishaps.  Stage one was to lift the central unit onto its crawler system.  This was done as follows:  first the wooden lifting cradle was attached to the three upper protruding M20 bolts which go down into the crawler bridge units.  This was then lifted (by 8 people, as the combined unit now weighed over 240kg) onto two strong A-frames, which in turn rested on eight stacks of 2-high bricks.  This allowed enough room under the M20 bolts to slip the bridges on from underneath and to bolt up with M20 locknuts from below (once three 65mm diameter brass spacers had been slipped into place, to get the correct distance between bridges and vertical finlike structures on the outside of the main unit.) These brass fittings had cuplike voids machined out on one side to accommodate the locknuts.  This ensured that flat surfaces on the bridges remained parallel with flat surfaces below the fins.  This had the effect of helping to keep the bridges from buckling forward or backward. Of course, for such buckling to occur, the M20 bolts would have to bend quite seriously. This is not likely, as they are high tensile.
At this stage the whole structure had to be lifted by the 8 lifters and held while the bricks were removed from under the A-frames, a rather tense interval.  When the cradle was replaced on the A-frames there was just enough room to slide the twelve main crawler units sideways onto their M20 rocker axles protruding from the bridges.  Large brass collars then locked them securely in place.
With the crawlers and bridges securely in place the whole central unit weighed more than 500kg.  This was too heavy for even for 8 lifters so the final downward trip of about 1 inch was done using my 2-ton hydraulic car jack and some supporting timber, first at one end of the cradle and then the other.  For the first time the central unit was on its “feet” and mobile.  The 24 cores to the 12 motors were connected to a 12 volt source and the crawler system and found to be satisfactory (before the final lowering onto the ground I had been very careful to check all motor polarities – to have one motor trying to work against the other 11 would be very rough on the works!)
The next big task for the lifting team was performed a week later and involved fixing the main horizontal arms in place.  First the rotating upper toroidal ring had been put in place on its roller race of 65 brass flanged wheels.  A set of 6 locking flanged wheels had been put in place on three strong vertical arms which came up the inside of the upper torus.  These wheels roll on another roller race on the top of the upper torus.  Their purpose is to prevent the whole upper machine from toppling over, should any unforeseen accident occur (the machine will sit on a vertical surface for its lifetime and is well-balanced even if slight tipping happens, having a low centre of gravity in relation to the main support).
The first arm to be attached was the counterbalance. This had already been bolted to the heavy central triangular frame of box girders by means of four M10 bolts into heavy straps (rather than multiple M4 bolts, since the angles were not 90°, as explained elsewhere).  My helpers carried the 140 kg arm over and lifted it into place on some wooden scaffolds (since the winding drum end needed to be over 8 feet off the ground.   There were some anxious moments for me as the four 12mm holes drilled on the bottom of the box girder frame came down on four M12 bolts protruding from the upper ring.  This match had not been tested before, as the separate parts were too heavy for me to move around on my own.  Fortunately the fit was good.  I must admit that I had a 14mm drill bit on standby on my portable drill in case I had to ream a 12mm hole out to 14mm!
Once the counterbalance arm had been bolted in position the bucket wheel arm could be brought over and two M12 bolts slipped into place to act as pivots on which this arm can move (to change the height of digging wheel). Again, the fit had not been tested, due to the enormous weight, but all went together smoothly.  Several of the bolts in critical places on the two components had been replaced by countersunk bolts (into 2mm plate) to avoid bolthead clash as the bucket wheel arm moved.  This turned out to be a wise move.  So ended the day’s work with the horizontal arms resting on trestles at their outer ends.
The next main stage was the upright arm placement.  To be safely accomplished this required some serious scaffolding.  I had made the components ahead of time and now they needed to be erected: two 9 foot high scaffolds were built, one on either side of the model, during the next 2 weeks.
On the day of the fitment my helpers passed each 45kg upright arm up handlers sitting on top of the 9 foot scaffolds. From there they were lowered and M10 bolts put through lugs on the arms and on the waiting model below. All went well except I put an upright on back to front! It had to be turned around and re-bolted. At this stage the upright arms were held in place by wooden struts bridging the gap between scaffolds.
Over the next week or so the 2mm braided steel wires were run onto the large winding drums and around the thirty-four 4 inch aluminium pulleys atop the two upright arms.  The fixed length 8mm threaded rods were slipped into their retaining blocks and lock-nutted.  The winding drums were then started and the cables brought into tension so that the whole model became self-supporting.  By trial and error it was determined that the balance of the model was optimum when 35kg of concrete blocks were placed under the winding drum area.  All motions could now be tested:  traversing, slewing, raising and lowering the bucket wheel, running all 6 conveyor belts, bucket wheel rotation,  all motions of the 5 service cranes, the up and down movement of the 2 drivers’ cabs and the motorised positioning of the final output chute over the static conveyors.  All now works.
Engineering on the models appears to have been adequate.  As a precaution against the finlike structures trying to splay outwards under load (thus deforming the large toroidal frame out of round) I installed 3 heavy straps at the bottoms of the fins and meeting in the central point with a M8 bolt. However, the tension in these has not increased at all after fully loading the structure, indicating that the engineering is adequate (no measureable deformation). 
The mass of the model has now been accurately calculated to be 1335kg.  This calculation was done with the help of my friend Prof Perry Kaye, retired professor of chemistry at Rhodes University.  He accurately weighed each of the most commonly used basic parts on a chemical balance and I was then able to calculate the number of each part used by subtracting what was left over from the total made.
To the best of my knowledge this makes “Bagger 288” the largest Meccano model in the world. I have not been able to find one of greater weight anywhere.  The Ripley’s Museum Ferris wheel (which they claim is the largest Meccano model in the world) has a mass of 544kg.  Purists will claim that my model is not Meccano because of the heavy gauge versions of Meccano parts used, but to the best of my knowledge the Ferris wheel is also not pure Meccano, as, for safety reasons, it had to be re-engineered, with all its Meccano strip spokes replaced by 8mm stainless steel rods.  The fact remains that it is not possible to build a model of this size in Meccano without some heavy gauge adaptation, especially if the model is as mobile and articulated as a bucket wheel excavator.  My philosophy was to rank engineering safety as first priority, followed closely by architectural accuracy.  I wanted to avoid any retrofitting, due to a collapse due to engineering inadequacy.
In conclusion, I must express my grateful thanks to the members of the lifting team. 
Dr Jennifer Williams, Prof John Williams, Dr Kevin Lobb, Andrew Shepherd, myself, Tim Bull, Landman Bester, Charlie O'Donoghue, Jessica Harris, Alexander, Richard Grant, Stefan Just


Monday 17 March 2014

Fitting the vertical arms

View from bucket-wheel end


Awaiting vertical arms

View of winding drums from below

All set to install vertical arms
Lifters at the ready!
Front vertical arm going up


On the way up
Safely at 9 feet

Manoeuvering the front vertical arm into position





Moving front vertical arm forward into position


Putting M10 bolts in place

Mission accomplished, Part 1
Sending 2nd vertical arm upwards
Getting 2nd arm into position


Another bolter at work

Just enough head room!
Attaching service crane
Service crane at ceiling height (about 17 feet) on top of back vertical arm

View from below - service crane in place on top of  2nd vertical arm

Mission accomplished, Part 2!
Whew! Now for the cables