_SalD_

Cleats are located outside both quarter blocks.  The length of the cleat is 125% the diameter of the yard.  The easiest way to make two identical cleats is to glue two pieces of the correct width wood together with PVA.  Shape them and then dissolve the bond in isopropanol.  The cleats were glued to the yard outside the quarter blocks. 
 
 
There are three more blocks on each side of the yard: two buntline and one clueline.  These are  single blocks and are stropped just as was done with the quarter blocks except the strops are not served.  I used 3 mm single blocks for them.  Because these strops are not served, it was easier to make an eye-splice on each end to form the loops, just as was done for the futtock shrouds (minus the thimble).  As with the other blocks, the strop seizing is on the fore side of the yard.  The buntline blocks point skyward and the clueline blocks downward, as seen below.

I have temporarily inserted the pin connecting the mast and yard.  The pin passes between the turns of the double strop of the jeer block.

Hmm ! Over a year now since my last post! I'm still here, model too, just got bored with it and decided to try some plastic kits as a change of pace.  As MacArthur said at Corregidor "I shall return!" 

For anybody interested, the kit is now available through the NRG store.  https://thenrgstore.org/collections/plans-and-projects/products/masting-and-rigging-kit
 
The jeers are the pulley system used to raise and lower the lower yard.  This ship has three jeer blocks, one attached to the lower yard and two others suspended by strops from the masthead.  These blocks are not included in the kit.  They are large enough that they are not difficult to make.  The jeer tye runs through the blocks.  The tye is a 6” rope with a scale diameter of 0.04”; the opening for the sheave is just large enough to allow the rope to run through it.
 
Look at the block proportion drawing.  The sheave opening width is “1” on the drawing.  The length of the block is 8, the width is 4, and the breadth is 6.  The sheave opening length is 5.5 times the sheave opening width.  It is not centered in the block, as shown in the drawing.  The jeer blocks have a double strop, so the blocks will need two grooves on their sides instead of just one.

 
To make the three blocks, I took a piece of boxwood a little larger than required and sanded the sides to the correct width and breadth.  Sanding instead of sawing prevented any burn marks on the wood.  The tops and bottoms of the three blocks, the sheave opening and the strop grooves were drawn onto the wood.  A  space was left between the blocks to make shaping the bottom of the blocks easier.  These blocks will have a false sheave and the sheave bolt is omitted because it is hidden by the strop.
 
I started with the sheave opening.  A 0.045” opening corresponds to a #57 drill bit.  I drilled the holes for all three blocks at the same time.  I used a drill press but this could be done with a pin vise.  The key is to keep the drill bit exactly at 90 degrees to the wood strip.  If you do not have a drill press, I would suggest drilling shallow holes from each side and having them meet in the middle.  This is what happens if your angle is slightly off and you drill through from one side.

A #11 blade was used to score the block along the pencil lines between the two holes and using a combination of files and #11 blade, the area between the score marks was shaped to simulate the sheave.  Two shallow cuts were made all around both ends of the blocks and halfway between them.  Using a V-shaped chisel, the strop grooves were cut.  The halfway cuts acted as a stop to prevent from cutting into the next block. 
 
With a sanding stick, the upper part of the block was shaped on all four sides.  I removed most of the wood between the saw cuts and start shaping the bottom of the block.  Finally, the block was cut free from the strip and the lower edge was shaped. 
 
The jeer block is located in the center of the yard.  The double strop for the jeer block is made from served 5” rope.  Just like the quarter blocks, the jeer block is not centered on the strop, but at the 1/3 mark.  The strop eyes are located on the fore side of the yard and secured with a seizing.

 
I made a template for the strop from a scrap piece of rope following the instructions below.  It took a few trials to get the correct length.  Once I was satisfied, the strop splice was unglued and the total length required was measured.  The pictures look somewhat crude but consider that the entire strop is less than 1.5” long.  These pictures are enlarged so that you can see the process.  I served a piece of rope, leaving extra unserved rope and serving thread for the splice.  The two ends were untwisted to make the splice.  This was glued and, when dry, served over with the extra serving thread.  Eyes were formed at both ends of the strop.
 
The block was positioned on the strop and seized so that one leg was twice as long as the other.  The splice is on the side of the block, where it will be less noticeable.

 
The arms were wrapped around the yard and the two loops were seized together.  These pictures show both sides of the yard.  The seizing is on the fore side. 
 
 

The lower yard is specified on the plans as 41.5 feet long, with a centerline diameter of 9.2”.  Just like the mast, the yard is divided into quarters.  There are four quarters on either side of the centerline.  The two center quarters are octagonal and the yard tapers from 9.2” to 7.8” at the end of the second quarter.  Because this is a desktop model, I did not want the yard to extend beyond the side of the hull and made only the middle twenty-five feet.
To make the yard, I started just like the mast, marking the dimensions on all four sides of the dowel.  Because this is such a short piece of wood, a template was not necessary.  The center octagonal section was made first.  Then I wrapped tape around the center quarters to protect them and tapered the outer part of the yards.  Finally, I rounded the tapered portions with sandpaper.  The drawing illustrates the dimensions.

 
A pin was placed in the center point of the yard to secure it to the mast.  The yard sits at the level of the futtock stave so I drilled a corresponding hole in the mast.  You can see the mast hole location in the picture in the previous post, just above the uppermost woolding.
Nine blocks were installed on the yard.  The jeer block is part of a pulley system to raise the yard.  Its configuration changed several times in the eighteenth century and varied with different sized ships.  This configuration is appropriate for a ship smaller than 28 guns in the last quarter of the 18th century.  Quarter blocks carry the topsail sheet falls.  Clew lines run from the corner of the lower sails (the clews) through the clew blocks.  The buntlines raise the foot of the sail for furling and run through the bunt blocks.   

 
The quarter blocks were installed first.  The kit will include 5 mm blocks; mine were slightly larger to be the correct length of 5.2 mm.  These blocks are stropped with served line.  This is my technique.  Serve a piece of line that you think will be the right length; on my model this was 1.6”.  This is running rigging so the serving thread is natural color.  I used Gutterman sewing thread.  Leave a long tail of serving thread on either end.

The first step was to make a loop at one end.  Untwist a short segment of rope next to the end of the serving on one side and cut the untwisted threads at a 45-degree angle to decrease the bulk.  Form a loop, with the untwisted threads laying alongside the served part of the rope.  With the tail of serving thread, wrap the untwisted threads and previously served line.  In actual practice, the untwisted line would be laced into unserved rope and then the service would continue along the loop, terminating at the throat of the loop.  Temporarily seize the block and measure how long the strop should be by wrapping it around the yard.  The loop ends do not meet; a seizing will run between the loops to secure it to the yard.  Make a kink in the rope to mark the spot.  Remove the block and make the second loop the same way.  Measure the length of the finished strop so you know how long to make the strop for the other side.
 
Reinsert the block and secure it with a throat seizing.  The seizing is located on the fore side of the mast and the block hangs below the mast.  This picture incorrectly shows the legs the same length.  Finally, the strop was wrapped around the yard and the two loops were seized together.
 
 

Hello all, just a little update.  I’m back up in Connecticut but the shipyard has been commissioned by my wife and daughter for wedding preparations.   My daughter will be getting married this coming September and the wife being frugal as always has voluntary me to make all the table center pieces.  Therefore the shipyard will be shut down for a bit longer. Not that I mind, looking forward to the wedding.
 
Air brushed flowers

I think that’s my civilians done for now. I’ll obviously have to change some dirt tones later when I place them in a base 

The best parties always take place in the kitchen.

First of all, of course, we need the kitchen worktop. Coincidentally, one of the prints I had made for the Revell Constitition fits like a glove, no wonder, almost the same scale and the design was based anyway on the design of the British 😉

Anyway, the kitchen and hearth are only worth as much as the life that takes place there.



The first three men assigned to kitchen duty were quickly pressed. Frederick Bush, the 24-year-old, hunky German is fetching firewood, Irishman Thomas Foley, at 47 one of the oldest crew members on board, will be working on a meat-like structure and Hans Yaul from Switzerland will be chasing the protein-rich maggots out of the cheese with his big knife.

Number 4 was more of a challenge. It's always nice when the kits come with little men, but they're usually not the right kind of hands-on character. Here on the right is a sailor from the Constitution kit.



Any sailor would immediately fall over on land with his legs in a row like this, so I first changed the leg position to a stable three-point position and also tilted the head slightly for the dynamics. After all, he should be fuelling the stove. However, the test position then showed a completely incorrect and far too static posture for this.

So he bent his back and brought his second arm into a working position. Now he finally looks like somebody doing a job.



Number 4 is alive 🙂

I then used one of my misprints to prepare the wood filling. The grill at the front of the Brodie Stove has 3 sections, so apparently you can fire it in 3 sections depending on what capacity you need. This is also the log length that dear Frederick has in his arms at the moment.



Afterwards, the lower decks are secured against falling objects with cotton wool pads ...



... and the grill is carfully loaded with firewood. We now know that our dear Lord of the Fire is 28-year-old James Caton from Brazil, with the logs that Frederik has placed in front of him and two bags of coals next to him for a nice, even heat.



And here you can already see why I had to shorten the height of the Brodie Stove compared to the original drawings: of course it has to pass under the deck beam and the two lids at the top should still be accessible. That's why there is a gap of exactly one deck beam width between the chimney and the lids at the top. How these two boilers could be effectively operated and cleaned with this limited access is still beyond my understanding.

Just like the automatic turning mechanism of the grill spit at the front. I know of English country houses that have a similar system, but there are usually much larger fires at work. The mechanics of the drive chain and the corresponding bearing of the spit are also not yet technically comprehensible to me in detail, even if they are based on identical plans in the NMM.

Furthermore, you have to bear in mind that the whole stove in Portsmouth is only a replica based on the plan just mentioned. I think back then, the stove size and installation situation were customised for each ship. Whether this is all correct in the replica is therefore not known. And fortunately, the difference in height is no longer noticeable once installed in the model.

And while we're on the subject of size and deck height, Frederick, with his height of 1.9 metres, which was unusual for the time but not uncommon, also has a problem here ...



... that standing is just about possible, but the next deck beam is already lurking for his head.



So he was clever enough to adopt a slightly more stooped posture to wriggle himself past the firewood, the coal bags and the water barrels.

In the small cooking chamber you can already see that with two people it's going to be a tight squeeze, especially if there's someone else working on the stove. I have deliberately avoided decorating the worktop like the breakfast buffet in Portsmouth, as everyone brings what they need for cooking from their mess and has to leave a clean worktop afterwards. After all, this is the only cooking area for 800+ crew members.

And that's the end of the small picture in the picture, just a few more impressions 🙂











Prost Mahlzeit,

XXXDAn

Well, that's an interesting change of pace! Thanks for the update.

Hello all, just a little update.  I’m back up in Connecticut but the shipyard has been commissioned by my wife and daughter for wedding preparations.   My daughter will be getting married this coming September and the wife being frugal as always has voluntary me to make all the table center pieces.  Therefore the shipyard will be shut down for a bit longer. Not that I mind, looking forward to the wedding.
 
Air brushed flowers

Hello all, just a little update.  I’m back up in Connecticut but the shipyard has been commissioned by my wife and daughter for wedding preparations.   My daughter will be getting married this coming September and the wife being frugal as always has voluntary me to make all the table center pieces.  Therefore the shipyard will be shut down for a bit longer. Not that I mind, looking forward to the wedding.
 
Air brushed flowers

Hello all, just a little update.  I’m back up in Connecticut but the shipyard has been commissioned by my wife and daughter for wedding preparations.   My daughter will be getting married this coming September and the wife being frugal as always has voluntary me to make all the table center pieces.  Therefore the shipyard will be shut down for a bit longer. Not that I mind, looking forward to the wedding.
 
Air brushed flowers

Hello all, just a little update.  I’m back up in Connecticut but the shipyard has been commissioned by my wife and daughter for wedding preparations.   My daughter will be getting married this coming September and the wife being frugal as always has voluntary me to make all the table center pieces.  Therefore the shipyard will be shut down for a bit longer. Not that I mind, looking forward to the wedding.
 
Air brushed flowers

Hello all, just a little update.  I’m back up in Connecticut but the shipyard has been commissioned by my wife and daughter for wedding preparations.   My daughter will be getting married this coming September and the wife being frugal as always has voluntary me to make all the table center pieces.  Therefore the shipyard will be shut down for a bit longer. Not that I mind, looking forward to the wedding.
 
Air brushed flowers

The futtock shrouds are attached to the futtock stave below and the futtock plate above.  An eye with a thimble is spliced into the upper end of the futtock shroud.  A double hook connects the shroud and the futtock plate. 
To make the stropped thimble, I took some line and unfurl the end.   Using a blunt needle, I made an opening in the line approximately the circumference of the thimble away from where the unfurling stopped and fed the unfurled end through the opening.  Once the line has been passed through the opening, the opening will naturally retwist itself.  A piece of  brass tube (the thimble) was inserted into the eye and the splice was glued.  The thimble was blackened after it was stropped because handling would have caused the patina to rub off. 

The brass tube is slightly wider than the diameter of the rope.  To keep the thimble from falling out of the splice, I placed it on an anvil and tapped each open end with a center punch.  This added a slight lip to the thimble. The double S-hooks are 1/8” long and were made from 24 g wire, using round-nose pliers.  The picture shows them attached to the futtock plates.

The futtock shroud was attached to the futtock stave by wrapping around the stave and securing it to the lower shroud with two round seizings.  In the drawing, the futtock shroud is shown in red and the lower shroud in blue.  After they were installed four rows of ratlines were added.

  

There are several holes in the top, which are marked in the picture below.  On the curved rim are eleven holes for the crow’s feet:  two between each slat and one through it.  There are three rectangular openings on each side rim for the futtock plates.  The four marks on the aft rim are for the railing stanchions.  Finally, there are four openings on either side of the center opening for the buntline and leechline blocks. 

Futtock plates are the metal straps that surround the lower topmast deadeyes.  The topmast shrouds are two-thirds the size of the lower mast shouds.  The deadeyes are 3” thick and 6” in diameter.  The futtock plate is one-third the thickness of the deadeye and three times its diameter long.  At 1:48 scale, that would be .02” x 0.375”.  They were made from 22 gauge wire.
 
The sequence of construction can be seen in the photo.  First, heat-soften the metal and wrap a piece around the deadeye.  Remove the deadeye and solder the ends of the two legs together.  Reinsert the deadeye to confirm the location of the throat and mark it with a Sharpie.  Determine the correct length for the plate by measuring 0.375” down from the throat and mark this measurement as well.  Remove the deadeye and  solder the legs together closer to the throat.  File the legs flat and cut the legs to the correct length.  Round off the end and drill a hole for a hook to insert into.  Pickle the plate and insert the deadeye.  Hammer or squeeze the legs of the futtock plate together for a snug fit and blacken. 

The holes in the top were enlarged and the plates were temporarily inserted.

Before the futtock shrouds can be installed, eight blocks must be stropped and installed on the undersurface of the top.  All my blocks are made of boxwood.  Blocks are not commercially available for all sizes.  For example, the quarter and truss pendant blocks should be 6.5 mm but the closest available block is only 5mm.  A good reason to learn how to make your own blocks!  The kit comes complete with all of the necessary blocks except the jeer blocks, which the modeler will learn how to make. 
 
Determining the dimensions of blocks is not difficult; all you need to know is the size of the line that passes through it.  The width of the sheave opening is 116% the diameter of the line.  For simplicity, call that  “1”.  The relative dimensions are as seen in the drawing below.  The only difference between a single and a double or triple block is/are the spacers between the sheaves The size of the strop grooves on the sides of the block varied; the relative size of the strop decreased as the size of the block  increased.
  
 
There are four leech line and four bunt line double blocks mounted under the top.  The bunt line blocks are closer to the center opening and the leech line blocks are closer to the rim.  The difference in the size of the blocks is small, so the kit will use the same size blocks for both.  They are secured to the top with a strop and peg.  To make the strop, I took a piece of 1” rope and untwisted both ends.  I cut across each untwisted end diagonally to decrease the thickness of the splice, wrapped the two ends together and glued the splice.  A simple knot was placed over the splice.  The block was inserted into the strop and secured with a throat seizing, hiding the splice.
 
The openings in the top were enlarged with a #11 blade, working from both sides of the top.  A thread was passed through the strop loop and both ends of the thread were inserted through the under surface of the top, pulling the strop through the top.  Wood pegs were used to hold the strops in place.  The futtock plates were inserted through the openings in the rim.

The diveplanes, rudder and propshafts have been finished - meaning they are functional and firmly attached, but removable for further sanding and coating. 
one very big risk is that I lack a flexible connection between motor and shafts - the prop - shaft - gearbox - motor turns easily but I’ll have to see if vibrations don’t cause problems.
I’ve assembled the main control components, they slide onto 4 M3 wires to form the “techrack”. This assembly slides nicely into the PVC pipes that keep the water out. The home made bajonet needs some more thought - having only two bolts to connect the two halves of the boat means it rotates a bit too easily.
ive now started on the sail - which will be built of 1mm boxwood on a frame - has some acute curves through. 

I made the top by laminating two layers of 1/32” basswood sheeting, each at 90 degrees to each other.  The kit will have a plywood template to trace the shape onto the basswood.  This gave the correct thickness and added strength.  On a real ship, the top was made up from tongue and grooved wood slats.  I drew the edges of the slats onto the top with a #11 blade. 

The top’s rim was made next.  I used template to trace the curved section onto sheet basswood.  The rim overlaps the edge of the top so draw another line onto the basswood 3.5” outwards from the first line.  I made a second template by outlining the top and drew another line 3.5” inwards from the edge of the template on the curved edge and both sides.  The template was trimmed at the inner line (see arrow below) and positioned on the basswood sheet 7” inwards from the first line.  This gave me the shape of the curved part of the rim.
  
The rim was glued onto the top and weighted down until dry. 

The front edge of the rim is raised.  I used a 3 mm chisel to remove one-third of the thickness of the rim.  If you do not have a chisel, you could use a sanding stick to shape the rim.  The inner edge of the rim was feathered so that only one-third the thickness was left where it met the top.

The side pieces also they extend 3.5” beyond the edge of the top and their thickness tapers to one third the thickness on its inside edge.  Because this piece is straight and with the grain, the tapering was done before it was glued to the top.  When you turn the top upside down, you can see the overhanging edges fore and both sides.
  
The top has multiple slats extending from the edge to the center opening.  The number depends on the size of the top.  I have penciled in the locations of the slats for this top (see two pictures down).  The slats that abut the curved portion of the rim have an unusual shape.  They are cut away to allow them to rest on top of the rim and tapered to a point as they approach the center opening.  Since they are all slightly different in shape, they were made individually.  The slat does not extend over the raised edge.  In the next picture I have incorrectly cut the side edges with a 45 degree bevel.  It should be a straight cut.  

The side slats pass through openings cut into the rim, and taper towards the center opening.  I laminated six pieces of wood together and shaped them into a triangle.  The height of the slat is flush with the rim.  The slats were unglued, openings were cut into the rim and they were installed. 

The aft slats are also triangular and extend to the edge of the top.  Lastly, a gunwale was glued on top of the aft slats and the side rim.  Take a look at this much later picture to see the relationships between the gunwale, side rim and aft slats. 


 
 
 
 

The futtock staves were made from 3” served rope and are located as far below the trestle trees as the top of the mast is above the trestle trees, approximately seven feet.  For ease of installation, I used served 24 gauge wire, rather than rope.  They were lashed to the shrouds.  The picture on the left shows the lashing in white for clarity and the finished product on the right.
 
And now it is time for the dreaded ratlines.  There are some lines on a ship that are a do not change with the size of the ship, such as the footropes and ratlines, both of which must hold a seaman’s weight.  The ratlines are made of tarred 1.5” rope.  At this scale, I simply tied, rather than lashed, them to the outer shrouds.  They are secured to the inner shrouds with clove hitch knots, a drawing of which is below.  This picture is also from The Boy’s Manual.

Ratlines are spaced 12-15” apart and are parallel to the waterline.  The easiest way to keep them even is to make a line jig.  There is a tendency to pull the shrouds inward as the ratlines are added.  I like to secure a brass rod or stick to the outer shrouds to keep them straight.  This is my setup.  The clips are holding the line jig in place.  The ratlines are parallel to the waterline, not to the deck. After several hours, 220 knots and fifteen scale feet of rope, the ratlines were finished. 
 
Catharpins are ropes with an eye at each end which extend across and are seized to the shrouds at the level of the futtock staves.  According to Steel, sloops were not equipped with catharpins but I included them in the kit to illustrate their construction.  I made them from 22 gauge wire with a loop on each end.  As there is no tension on them, I did not solder the loops closed.  The catharpins are served and the ends are painted black to simulate the eye splice.    The first catharpin is located just aft of the mast and the other two are spaced out evenly along the futtock stave.

This completed the standing rigging of the lower mast.  As mentioned earlier, because this is a cross section model, lines that would not terminate on the model, such as the stays and backstays, were omitted.

The shrouds were installed next.  The starboard shroud is always placed first and are they are installed from fore to aft.  Because this ship has an odd number of shrouds, the first shroud is single; the rest are double.  The first shroud is served its entire length, protecting it from the lower sail.  The starboard and port first shrouds are secured to each other with a cut splice, just as was done with the pendant tackle. 


The remaining paired shrouds are served where they could be chafed: the center 20-25%, based on the ship being rigged.  I cut a two foot piece of line and marked the midpoint and 10% the length of the shroud on either side of the midpoint, in this case 1.2”.  This is the area that was served.  The doubled shrouds were secured with a throat seizing tight to the mast head.  The lower ends of the served portion of the shrouds should be level when they are installed.  This means that the throat seizing is not exactly in the middle of the served section, but offset enough to allow this to occur.  You can see this in the next picture.  The aft shroud seizing is slightly longer than the fore.

The shrouds were installed, alternating starboard and port, taking care to stack them neatly.  The topmast is temporarily installed in the following pictures.
 
The next step was to attach the upper deadeyes to the shrouds.  The distance between the upper and lower deadeyes is a constant.  The easiest way to ensure this is to make a spacer jig.  You will actually need ten, five for each side.  The picture shows two jigs.  The one on the left is made by soldering the two wires together.  The other one uses twisted wire.  The prongs go through the two inner deadeye holes.
 

I started by inserting the prongs through the upper holes of the lower deadeye and bent the wire around the back of the deadeye to prevent it from coming out.  Next, I wrapped the shroud around the upper deadeye and adjusted the shroud length so that the upper deadeye could be threaded onto the jig.  These shrouds are cable laid (left twist), so the short end of the shroud went on the aft side of the shroud.  If the shrouds were rope (right twist), the short end would be on the fore side.  I secured the shrouds to the deadeyes with alligator clips.  I find it important to leave the model alone for several hours at this point.  This allows the rope to stretch and helps prevent sagging in the future.

The upper deadeyes are secured with three seizings.  A cross seizing was placed where the shroud crossed over itself next to the deadeye.  I  marked the location of the cross seizing on both sides of the shroud and removed the deadeye.  If left in, the loop is too big.  After making the cross seizing, the deadeye was reinserted and the middle and end round seizings were added.  The drawing shows a round seizing. 

And the picture illustrates the relative location of the seizings, using white thread to make it easier for you to see.

Brown paint was used to represent the leather cap at the end of the shroud.

The shroud lanyards were installed next.  They are considered running rigging and are not tarred.  A knot was tied at the end of the lanyard and it was inserted through the back of the upper deadeye in the foremost hole.  After reeving it through the deadeye, excess line was kept for tying off.  Once they were done, the lanyards were gradually tightened, making sure the mast was straight.  Just like with the shrouds, I gave it a few hours to allow the line to stretch.  To tie off the lanyard, the rope was passed between the shroud and the deadeye (below left) and looped under the last line of the lanyard (below right).  The lanyard was wrapped around the shroud a few times and finished by inserting it under the last loop.

So, time to continue. 
I do have plans now, but still I need to think about the sequence of construction. I also had some hesitation regarding 2 small pipes coming from the compressor room towards the manifold. I had made provisions for those pipes in way of making large supports on the big pipe to accommodate them, but I was never sure if I'd place them after all. 
Eventually I decided to place the pipes. I had put part of a pipe below that manifold. It didn't look right, so I removed it and built those pipes in different sections. The joints next to tank dome 2 will mostly be covered by the platform shown in previous posts. In below picture you can see the brass pipes running parallel to the big pipe. The joints are hidden in the shadows.

 
The reason I had to put them now was of course that they were also a bottleneck for construction of the manifold. I wouldn't be able to place them if I continued further on the manifold. 

 
And I've started the structure of the manifold on portside. All beams in place here. 

 

It is time to start rigging the mast.  Some lines are served with an additional layer of line wrapped around them to protect them wherever they would be at risk of damage from rubbing.  On this model, the pendant of tackles, the foremost shroud, the other shrouds above the catharpins and the jeer block strop are served.  Because this is a cross-section, the main and back stays will not be installed but they would also be served.  Standing rigging is protected from water damage with a tar-like compound.  This resulted in a dark brown appearance to the lines.  The running rigging was not protected and so was a natural hemp color.  On this model, the burton pendants and shrouds are standing rigging;  everything else is running rigging
 
Rope sizes are calculated from the diameter of the mast.  The kit contains a table with the dimensions for the various ropes, based on the diameter of the mast.  To measure the diameter of the line, I wrap it around a dowel twenty times, measure the width of the wrapping and divide by twenty.  This is much more accurate than  trying to measure an individual line. The first rope to go over the masthead is the pendant of tackles.  On the topmast, this line is referred to as the burton pendant.  This rope is completely served, and has a thimble on one end.  The other end is spliced to its opposite, resulting in the rope in the diagram below.  Where the red and blue lines meet are splices.  The pendants extend to approximately two feet below the hounds.  They were used with a tackle to raise and lower heavy weights.

To properly rig a model there is no substitute for the appearance of a served line.  I use 6-0 fly tying thread, which can be purchased at a sporting goods store or online.  I start by running thread, from left to right in this case, into the depression between the rope strands (worming), smoothing its surface (the yellow areas seen in the drawing below.  Then I serve the rope from right to left. 

I find it easier to serve short segments of rope, such as this, on the same piece of rope and then cut them apart.  I served the rope, leaving approximately six inches of serving thread for the splices (red circles).

Then I made a diagonal cut, following the lay of the rope ¼” away from the end of the serving.  The unserved line was held against the other line where the splice would go and I wrapped the two lines with the left-over serving thread “splicing” them together.  I continued the wrapping a few more twists to smooth out the transition and tied it off.  A tiny bit of dilute glue held everything together. The pendant was put over the mast head and onto the bolsters.  It was marked on each leg, two feet below the hounds and removed from the mast.  I used blackened 1/16” ID brass tubing for my thimbles.  The mark was placed on the side of the thimble and the pendant was wrapped around it.  For simplicity I used a simple seizing to secure the thimble and put it back on the mast.

 
 
 
 

Thanks to Phil and Glen for the comments, and for anyone else who has clicked the like button since I last said thank you.
 
Much to my surprise, the replacement parts for the missing stand parts arrived on Tuesday, so it took just 8 days for the mail from Spain to Austin, Tx.  I was a little unsure about what glue to use and finally got over to Home Depot today and bought some Loctite for Plastics glue.  It is two parts....you spread an "activator" on both surfaces, let that dry, then apply the glue to one surface and stick them together.  Seemed to work quite well and did not haze the acrylic.
 
Anyway, here are three more shots of the Camel on the stand provided in the kit.  In the bottom picture, you can see two of the three little cross pieces between the upright pieces of the stand.  Those are the pieces that were missing from the kit originally.
 

Finished
 
I sort of limped over the finishing line but I am calling this one done.  It was a bit of a roller coaster at times but I am pleased with the end results.  I completed the  rigging, at least as much as I plan to do.  There was supposed to be some rigging on the landing gear as well but I am going to leave that off.  Overall it was a very good kit with a lot of positives, but just a few really glaring negatives as well.  And it definitely had some challenging aspects too....I accept at least some blame for any flaws in the final product.
 
Initially I had thought about maybe creating some sort of diorama, or at least a base, something like @chadwijm6 created for his Sea King helicopter.  I still could do that in the future, but for now I will just display it on the stand once I get the remaining stand parts that were missing from the original kit.
 
As for the rigging, post #129 of @DocRob's AEG G.IV build log was a great help.  I used a lot of those techniques, except with the stainless steel braided thread and slightly larger aluminum tube.   I put a bit of CA on the end of the thread to hold it together, then passed the thread through the tube, then through the hole in the model, then back through the tube.  I then put a drop of CA on the thread near the eyelet and slide the tube up to the eyelet and it worked like a charm.  All that after trying several different types of thread or wire and several different methods of attaching it.  That method was easy and also very effective so thanks to docrob for that post.
 
Thanks also to everyone who has followed along and commented or at least hit the like button.
 
And finally the pictures.  This model is too large for my DIY photo stand/light box so I just put it on a somewhat beat up card table for its photo shoot.
 

 

Thanks for the likes and comments.   
 
@PvG Aussie  it is strange to me....though I admit I know nothing about manufacturing, I am a software guy....but the laser cut wood pieces for the most part fit together great.  It has been the cast and photo etch metal pieces causing most of the problems.   I would have expected the casting of metal to be more "precise" than laser cutting wood.  Though in the description below I guess there was a counter example to that.
 
And yes, I am getting close to completion, definitely in the dangerous "just want to finish the project" mode.
 
I got the windscreen and third small gun installed.  The windscreen does not look as scratched/fogged as it does in the picture.  All those bits were a challenge to get in place.  A lot of that work would have been easier before installing the top wing, but you really had to put the top wing on first to locate the struts.
 

 
I've also started on the landing gear.  Below is a picture of the two wheels.  The tires were cast metal, painted flat black, while the spokes were photo etched parts, and the hubs and axles were also cast metal, all glued together with CA.  The design of the wheels was such that they should be able to spin, but I guess I got a bit too much CA where it should not have been, so my wheels do not spin.  The cone shaped outer spokes were a bit of a challenge to get them in place.
 

I've now started trying to put the landing gear struts on the fuselage, but that is proving to be a challenge.  Each strut attaches to the frame in two places.  In the front, some of the cowling and internal photo etch are getting in the way a bit.  At the rear attachment point, it is not fitting due to a prior tweak I made.  Way back in post #17, in the second and third pictures, you can see that I doubled up the frame across the bottom in the cockpit area, to compensate for the poor fit of the wood pieces at the side of the cockpit....the laser cut wood pieces were too short for my model.  Anyway, the rear attach point of the landing gear is supposed to sort of clip on to that fuselage frame but it cannot because my frame is twice as thick right there.  So I need to figure out if I can cut away a bit of that doubled up frame or if there is some other way to compensate.
 

As always, thanks for the likes and comments, and to those who just take a look from time to time.
 
The kit continues to be a bit of a roller coaster, as some parts go well and others are a bit frustrating.   The most recent bits fall more into the latter camp.  I've put on the rest of the metal parts around the cowl and cockpit.  The fit of those parts ranged from mediocre to poor.  The one "poor" fit was the piece between the two machine guns....I admit the instructions did call that part out and say "adjust if necessary" showing someone taking a file to the side of the part.  Sadly, no amount of filing would make the part 1/8th of an inch longer, which probably would have helped.  As for the other parts, they did not always line up well and it was difficult to tell where the back side of the part came in contact with the rest of the model....e.g. where to apply glue.  Further, those parts had three different "access holes" to allow access to the filler caps for fuel or oil tanks.   Two of those holes do not line up at all with the tank filler below and the third partially lined up.  Oh well.  Below are some pictures.   Oh, you can also see some loose rigging...those lines had to be glued to the back of the metal parts before installing the metal parts.  The other ends will be attached in later steps.
 
Next up is the windshield, though I seem to have misplaced the clear plastic bit for that.  But it should be easy enough to recreate it from the ton of clear plastic packaging used to contain all the cast metal parts in the kit.