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The Spinning Wheel - De-Constructing an Original
02/22/2008, 04:10 | Norse WoodsmithWell, it seems my brother had been keeping great great granddad's old spinning wheel - I had forgotten the box that it was in when I left the homestead, and he had been storing it for me. After reading the last piece I did on spinning wheels, he must have read it and remembered he had it -and got it out in the mail to me - because it arrived a week or so afterwards:
It's missing some pieces, but there's a good majority of it still there. The legs and pedal are gone, and it's missing the two pieces that hold the bobbin/axle.
It's an interesting piece to me on several counts... First, it was made by great great grandad... Second, it's a study in wooden machinery - everything has a purpose and yet it's still elegantly constructed. Third, it's an example of true frontier craftsmanship. I'm not sure of the exact date, my best guess would have been somewhere near the 1870 to 1890 range, in the Dakotas. This would have been made with the most meager set of tools, and quite far out in the country... I think I remember reading the nearest flour mill at the time was a full day away.
Parts of a Spinning Wheel |
| To have a discussion about the construction of the old wheel above, it would probably help to review just what the parts are called... I got much of this information off of various web sites, including The Joy of Handspinning, which is a wonderful resource for the enthusiast - I'm more interested in the construction, but that doesn't do you much good if you don't know how the thing works!... I'm using dad's wheel, which is a replica of the old one I'm looking at:
|
| Tension Knob: A threaded knob, turned to raise or lower the bobbin and flyer assembly thusly reducing or increasing tension on the drive bands. Maidens: The upright posts that hold one end of the bobbin and flyer assembly Flyer Whorl: The pulley that drives the flyer - it has several different diameters so different speeds can be achieved Flyer: The U-shaped piece with hooks - the hooks are there just so the fiber can be spooled evenly onto the bobbin. This is what spins the fiber. Bobbin: A spool that collects the spun fiber Orifice: Where fiber is fed into the wheel as it is spun Drive Bands: Twine or string that drives the flyer whorl from the fly wheel Mother of All: The upright piece that holds up the tension knob, bobbin, and flyer Fly Wheel: The main drive wheel - the large wheel that is powered by the treadle Footman: Hard to see in the photo above, it's behind everything- it's the wooden piece that connects the treadle to the fly wheel Treadle: the foot pedal at the bottom |
It's made from at least three, but more likely four distinctively different woods, from what I can see - and I think you can tell somewhat in the top photo. I'm not positive of the exact species, but from my experience with wood and my knowledge of the trees native to the area in which it was made, my best guesses would be birch or elm, maple, and basswood or poplar. I will get into where each was used as I deconstruct the thing.
Metal pieces would have been difficult to fabricate and expensive to purchase, so their use was kept to an absolute minumum. Could he have bought the metal pieces, or had a machinist make them for him? It's a possiblity. The pieces could have been ordered via mail order and shipped to the closest dry-goods store... yet they do all show at least some amount of fabrication. That eveidence could just be the technology of the time showing through, however - I'm just not qualified enough to say.
The only metal pieces are the axle/treadle drive on the fly wheel, the metal hooks on the spinner/flyer, and the axle for the flyer/flyer whorl assembly. The metal reinforcement on the flyer (the U-shaped piece in the photo below) shows signs of hammering to shape, and is riveted in place with metal pins and is surely of his own making.
The part that would have probably been the most difficult to make would have been the axle for the bobbin/flyer assembly... It appears it was made from something else, and made to work. I'm not exactly sure what it would have originally been had he fabricated it - it might even be two pieces, I can't really tell. The center was drilled out from the end and from the side to create the orifice that allows the fiber to be fed through it.... Both holes are off center, and show some evidence of being drilled and filed by hand.
You can see the orifice on the axle of the flyer on the right in the above photo, where the fiber is fed into the wheel. The far end of the axle in the photo above has a small taper to it - and is also threaded to hold the bobbin and flyer whorl on. It looks to me like the tapering was done by mounting the bolt in a wood lathe and tapering it using a file while turning. Fine metal work would have been difficult on the prairie in those days... and this is one of the things that lead me to believe this piece was at least partially fabricated by old great great granddad.
The bobbin (on the left in the above photo), the flyer, and the flyer whorl are all made from a very dense, close-grained wood - my guess is maple, though it could be just about anything of a similar nature. It needed to be, as the walls of the pulleys on them as well as the U-shape of the flyer makes using a strong wood imperative. The bobbinis made from a single piece... You can see by the breaks that it was made from a straight piece of about 3" round wood. The hole the axle slides through goes all the way through the bobbin, obviously - my best guess as to how this was made would be to first drill the hole through the rough blank - then mount the blank in the lathe and turn the bobbin to its final dimension. This would assure the axle hole would be centered on the bobbin. The far end of the bobbin is actually the first pulley you would use as part of the flyer whorl assembly - you see it in the next photo and the one two down that shows the whorl in it's place.
Here you can see the far end of the bobbin and the leather "bearing" that the axle is pushed into (the flyer whorl is not in this photo - it would take up the space between the bobbin and the adjuster piece the leather bearing is pressed into):
Both ends of the axle were mounted in leather bearings... but unfortunately the maiden that holds the closer end was missing on the original. Using another wheel made by granddad's brother, he fashioned the maiden with a leather bearing similarly to how that wheel was constructed:
You can see that it was simply a thick chunk of leather, glued into the maiden. This allows for the bobbin assembly to be easily removed from the wheel, simply by turning the maiden. There's not a lot of pressure on these bearings so they function quite well (as evidenced by dad's copy), and the leather would simply have been replaced as it wore out. Lubrication, if any, would have been tallow or beeswax.
The flyer whorl is made with two different sized pulleys so you can adjust the speed of the flyer - faster for more twists per inch in your yarn, and slower for fewer. More twists made for a stronger thread - but took more raw fiber. Fewer produced more "fluffy" yarns, good for sweaters and the like.... at least that's what I think - I have no experience spinning my own yarn. I still have the flyer whorl for the original, though unfortunately only half of it - but it does show how it is constructed pretty well:
You can see the differing diameters of the pulley to allow the flyer to spin at different speeds depending on where you placed the drive bands. The bobbin spins freely on the axle so is independent of the flyer whorl. It is driven by its own pulley on the end next to the whorl that is a slightly different diameter - this is so the bobbin would spin at a different speed than the flyer. Otherwise the yarn would only spin in place - with the different speed it slowly spools onto the bobbin as you feed more fiber into the orifice.
This is known as a "Scotch Brake"... it basically means the yarn spools quite slowly onto the bobbin, while being twisted (for strength) many, many times for each single time it spools on the bobbin - which is the major function of the wheel. It is this twisting that gives the yarn it's strength - without it, it would simply pull apart.
A good spinner feeds fiber into the orifice at a steady rate, thusly avoiding thinned out or lumpy yarn that is strong enough to knit. More twists per inch results in a thinner, stronger thread - fewer provide fluffier, more insulating yarn.
The drive bands would have been simple twine or leather strips, or possibly even yarn - it didn't need a great deal of force to twist the fiber, so grip wasn't terribly crucial - speed was.
You can also see the tensioner knob assembly in the photo above at the top of the aptly named "Mother of All". It's broken as well, but it shows how it was made... A threadbox would have been pretty standard fair in most shops of the time, so that's not too surprising to find. It still works quite well, even after being exposed to the elements for many years.... The Mother of All is broken here as you can see in the photo above and below, but again at least we can see what it looks like:
The Mother of All is so aptly named as it is the main structural element of the wheel - everything pretty much hangs off of it. It, along with the maidens and most of the spindle work (with the exception of the spokes in the wheel) are made from a hardwood I would say is either elm or birch - it's hard to tell exactly as the wood is aged so. But those were common woods used in local furniture of the time - especially turned furniture. Oak was available and used extensively for standard casework, but wasn't preferred for turning because of it's open grain and it's tendency to tear out. I would imagine the elm or birch was riven and turned green, much in the fashion of windsor style chairs, and wedges were used to fasten the tenons to the half-moon shaped base (which I think was made of either poplar - but could be basswood)... There would not have been any kilns in the area, any dried lumber would have been air-dried.
Which brings me to the fly wheel, the most prominent piece of the spinning wheel, has some interesting construction methods. The outer wheel was constructed from four separate pieces. The wheel is made what I think is basswood, though it could be poplar, I suppose... both are plentiful in the area. There are a couple ofreasons that basswood would appropriate here. First, a lighter weight wheel would be easier to spin. Women using these wheels would often spin for many hours on end, for many days in a row... ease of use was paramount in their design. Second, basswood is a very easy wood to work... Mounting a wheel this size and turning it in a treadle lathe would have been quite a task... the easier one could make the task, the better. Third - since these wheels didn't carry a load, like say maybe a wagon wheel would, there would be little or no structural stresses on them, so basswood met the bill.
The pieces for the outer rim were first assembled before they were turned using splines and wooden pegs to hold them in place. You can see here where one of the pegs was placed too far out and was turned into:
The outer wheel itself was not constructed in the same manner as a wagon wheel - where the spokes have tenons that mount into the outer wheel - for the reasons mentioned above. It was first assembled and then turned without the spokes - they were added afterwards. Here you can see one I've pulled out:
After the main hub was turned, the spokes were made to fit inside the outer rim, then holes were drilled through the rim into the spokes - and a wooden dowel was driven in to hold the spokes in place. There just one problem with that - how do you make sure the hub is centered in the outer rim? Well - my best guess is that the hub and spokes were made first. The hub first, then the spokes, which could then be glued into the hub. The hub could then be mounted on a temporary axle and turned, allowing you to mark the end of the spokes in the same location as you turned the hub. The outer rim could then be turned to match this dimension... It's just an educated guess, mind you - but the best I can come up with given the circumstances.
As for the hub, it's one piece, with an axle that mounts into the adjacent spindles thusly:
The far side of the axle has an offset that attaches to the footman, which then is attached to the treadle. And yes - at the lower left of the hub in the photo above, that is a knot... As a matter of fact, it continues through to the other side:
Why would he have used a piece with a knot like that in it, you might ask? I would put forth that it was a matter of convenience... As I mentioned above, a lot of the wood used for the contruction of this wheel would probably have been worked green. The wheel would have had to be dried wood though. Most likely that meant that it was was harvested from already dead wood - possibly even seasoned firewood. There wasn't storage space available for storing wood while it dried... The house they lived in would probably have been the size of your living room and housed 5-7 people... The barn would have been similarly small was soley for livestock. The shed that served as a shop would have been more like a lean-to, perhaps with a pot-belly stove if the owner was well-off. So dried wood was a luxury most couldn't afford, but for the wheel it would have been necessary as green wood would have shrunk and rendered the wheel useless. So it's my guess it came from whatever was available - and since it didn't need to be all that strong, it wasn't a problem structurally. Also, I should mention that the knot would not have been this pronounced when it was made - this particular wheel was exposed to the elements for many years, so has weathered quite a lot. Originally, it would have been a very tight knot.
About all that's left is the base, legs, footman, and treadle - and all I have of those is the base... The base is made of poplar, it appears. I remember hearing the half-moon shape was a sort of trademark of his, but I'm not sure of this... compared to the other his brother did later, its a unique feature and was supposedly preferred by the people who used them as they were stronger. I do recall hearing that this makers' work was highly prized by those who received it, at least within the area he lived.
I may restore this old wheel someday - no, it will never be in working order again, but I may try to get it just so it is all in one piece and has all of the parts, just for display. I doubt it's worth much to anyone but me - but it sure is fun to have around to look at and to study, to give one appreciation for the original maker and the methods and material he used in creating it.
The maker, my great-great granddad, was a very adept turner, furniture maker, and woodoworker. He used green wood quite a bit, as I think can be seen in another of his works which I will show just for reference - a crib made of elm:
It appears he also used steam to bend wood, as you can see - obviously a very industrious fellow for someone truly out in the sticks... This crib was used all the way into the 1960's as I recall... It's been retired for obvious reasons since then, but still remains in the family, well over a century after it was made.
Catskill Craftsmen Wood Pastry Board with Baking Graphics
12/31/2007, 09:12 | Furniture Craft
- Roll out pie crusts to exact dimensions
- Reverses to plain side for other projects
- Measures 16 by 22 by 3/4 inches and weighs just over 6-1/2 pounds
- Wash with warm, soapy water; occasionally restore with mineral oil
- Includes 1-year warranty
- BUY NOW
Dash almost complete...
00/00/0000, 00:00 | The Refined Edge
In my last post I had the dash veneered on both sides and the cutouts for the gauges and switches prepared . I am now kicking myself for not taking a picture of the dash panel when I received it and the dismal state it was in. In any case, I began to apply the finish which consisted of a lightly tinted danish oil, the tint a light colored shade of walnut. After I let this dry for two days, I began to apply the top coat of a wipe-on polyurethane. Since the dash panel is exposed to temperature and environmental extremes, humidity, and possibly direct sunlight, polyurethane is a good finish to seal out the elements. The original dash panel delaminated and the veneer was flaking off due to these same environmental extremes, so I had to make sure the correct finish is applied.A different type of woodworking...
00/00/0000, 00:00 | The Refined Edge
I've been tasked with reconstructing the wood dash panel from a vintage British automobile which is currently being restored. The dash was previously veneered and after about thirty five years, it succumbed to the elements and began to delaminate. Along with this, the original veneered surfaces were cracked and flaking off. This is a type of work I have not done before. The only effective way to remove the veneer completely and uniformly was with a sanding machine. After performing this on either side of the dash panel, I had clean wood underneath. The wood was high grade plywood with many plies. I judiciously re-laminated the laminations which were separating, which was no small feat. Once I was completely satisfied that the plywood dash had regained its strength and rigidity I began to plan the application of veneers both on the face and back of the dash panel.The veneers were applied one at a time, beginning with the back of the dash panel. I cross banded or alternated two layers of the back cherry veneers to add rigidity and strength to the dash panel. I next cut out the multitude of holes from the back along with screw holes and rectangular cut-outs. I used reamers, sanding pads, and small half-round and round files to accomplish this.After I was satisfied with this, I applied veneer, bird's eye maple, to the face of the dash. Similar to the back, I re-created the holes, cut-outs, etc. from the front. Next, I veneered the glove compartment box door following the same procedure.
In the photo, I have just completed veneering and sanding the dash panel, glove compartment door, and have it fitted in its opening. Some more small detail work and I am almost ready to apply finish to the dash panel. There were some stressful moments in all this, veneer being so thin with very little margin for error, but it seems to have worked out. I thought I would share this experience.
Contrasting stiles...
00/00/0000, 00:00 | The Refined Edge
A cherry cabinet on stand I built three years ago had developed a small bow in the inside vertical stile of the right hand door. This happened a few weeks after I completed it. I kept telling myself I would one day either make some new doors or replace the bowed stile in the right hand door. Well, I finally decided to do this. I hunkered down , disassembled the right hand door and replaced both the inside lipped stile and the top rail. The cherry cabinet was originally finished with multiple thinned coats of super blonde shellac. Cherry develops a wonderful color and patina as it ages. There is no sense in staining this particular wood as the natural aging process and exposure to light and air provide the most beautiful color. We had this cabinet around for the past three years as it slowly developed the cherry patina. It is sometimes difficult to appreciate how much of a color change has actually occurred since the cabinet ages uniformly.Well, I found out how much it aged and developed a dark color when I began to replace parts of the right hand cabinet door. The photo has the inner lipped stile and the top rail as fresh, new wood. I made sure to have these two pieces acclimate in my studio for a couple of weeks. The contrast is incredible... with nothing originally applied to the cherry cabinet but super blonde shellac and wax, no stain of any type applied. I took this photo to be able to show any prospective clients just how much cherry changes over time.
I notice the issue of either staining or leaving cherry to develop it's own aged color comes up occasionally in forums and the overwhelming advice given is to let it develop its own color over time. When you see the difference, it is easier to accept this advice.
I thought I would share this..
Antique Bus and Trolley Restoration
00/00/0000, 00:00 | WoodworkingONLINE.com 
John Singley of Tucson, Arizona sent us a reader’s tip for ShopNotes magazine. In his letter, he mentioned that he volunteers for the Old Pueblo Trolley Museum. John says,
“The trolley I am working on is the Lisbon/Aspen P&MU. It was taken down to the frame and we are replacing most of the woodwork. We have been working on it for 2 years and expect to have it complete and in operation in about another year.”
Needless to say, there is a lot of woodworking that has to take place to restore these vehicles to their former glory. Check out some of the restoration work at the museum’s web site.
Some thoughts on dovetails - part I
00/00/0000, 00:00 | Sauer & Steiner
For the last several weekends, I have been working on our kitchen drawers. I have just crossed a major milestone - there are more drawers completed than remain (only by 1... but it still feels great!). So I have had “dovetails” floating around in my head quite a bit lately.
There was in interesting thread about dovetails in one of the forums a week or so ago. The thread was titled “Skinny pins in hand cut dovetails”. After reading most of the thread - I started thinking on my own dovetail evolution - and the whys and how's of it. I have also had a bit of an epiphany moment sparked by that thread, and it has to do with the relationship between process and efficiency. I am fully aware that I may to step on a few toes with this one - and I am fine with that.
My goal with woodworking and planemaking is to become extremely efficient while continuing to improve my accuracy... and in that order. I make my living in the woodworking field - I have to be efficient. So everything I do is motivated by using the fastest method even if it means a slow initial learning curve - complete with bumps and errors. Sharpening is a perfect example. I made a very conscious decision to learn to freehand sharpen because once you know how - it IS the fastest way to sharpen. Sure, it made for a lot of frustrating sharpening sessions and the dizzying parade of sharpening jigs were quite tempting - but I can honestly say I am glad I stuck to my guns and learned to do it freehand. I am now fast at it, and don't hesitate to stop work to restore an edge. I will write more on freehand sharpening in another post.
Back to dovetails & efficiency. I believe that the dovetail joint is a functional mechanical joint that can be extremely beautiful if well executed. There are a lot of times when dovetails are used and they are not seen - and in these instances how it looks is less important (though they still need to be tight fitting and designed for mechanical strength). The drawer is usually to blame for all the discussion about dovetails - skinny pins vs fat pins, machine cut vs hand cut, spacing, angles, pin lengths etc. This is because these dovetails can be seen, and rightly or wrongly, have come to symbolize the quality of the piece they live in.
I decided that I would hand cut my dovetails for several reasons (in no particular order). I like the somewhat random and irregular look of handcut dovetails - they tell me that a person spent time making this - and I like that. I like skinny pins - especially in contrasting woods - they make everything look lighter and more delicate. I like irregular spacing. I tend to put narrower tails on the outside edges and gradually increase them as they get closer to the center. It means I don't need to do as much math and is really quite fast to lay out. Here is an example;
The tails on the top and bottom are 3/4", 1/16" pin, 1" tail, 1/16" pin, 1-1/4" pin. It makes for a somewhat rounding effect.
Once I made the decision to hand cut my dovetails it meant I needed to be as fast and efficient as I could be. To me, this means the goal is to be able to fit the dovetails off the saw - no paring. My friend Karen was over a few weeks ago and we were talking about this as we stood in a sea of kitchen drawer parts. I commented that I was going to cut to the line and not intentionally cut inside and then pare to the line. If I overcut and there was a gap - so be it. I would not scrap the drawer but live with it. I explained that I felt this was part of my learning process and working towards maximum efficiency. She gave me an affirming nod and agreed. As we continued to talk we realized that there are many woodworking schools out there that teach to cut well inside the line and to pare to get the right fit. Looking at that now - it seems a little off - it is teaching a process where the outcome is consistently a 10 hour dovetailed drawer! It may be beautiful and perfect - but the process strikes me as questionable - not to mention it is unrealistic to expect a client to pay for a drawer that took 10 hours to make. I would much rather endure the pain, suffering, and disappointment of a few gaps here and there knowing that I am slowly, over time, getting closer to dovetails that fit right off the saw (I am aware that I am building drawers for my own use and not for a client - so I do have the luxury of “learning” through my work). So with that in mind - here are a few examples of dovetails I have produced spanning my entire woodworking life.
This was the first furniture project I made with a drawer. The front is cherry and the sides are pine. Drat... it is a bit out of focus:)
These are the drawers on my left handed, shaker inspired bench. There are 10 drawers in all. The sides are 5/8" basswood and the fronts are 3/4" mildly curly soft maple. They are still a little clunky - but the spacing was starting to feel right on these.
This is a drawer in a table I built for my sister and her husband as a wedding gift. Skinny pins have arrived and are here to stay! 1/2" maple sides, 3/4" walnut front. Note the African Blackwood pull... I shaped them by hand... no lathe:(
Which brings us to the most recent dovetail project - the kitchen drawers. I have just finished 5 more kitchen drawers - here is a shot of the stack.
There was a magical moment that happened while building these 5 drawers - I did actually cut a set of dovetails that fit right off the saw. It is pictured below.
There are a few wee gaps - but after they were glued and planed flush, they were gone. And after this set - there was another set of 1/2 blinds and two sets of through dovetails that fit off the saw. This was most encouraging and confirmed to me that this longer road was the right road to take.
And hey... I have 7 more drawers to practice on!
Ancient Kauri wood ring with a black wood band
00/00/0000, 00:00 | Wooden Rings from Touch Wood Rings
Ancient Kauri wood.
One new story and one very old story.
A lovely couple from Ohio contacted us a few months ago and asked if David would make them rings of Kauri wood. The couple specially ordered the wood from ancientwood.com and had the wood shipped directly to David.
The ring you see here is David's first kauri wood ring; his test ring.
Dusty and Erin's rings will be kauri wood with bird's eye maple liners.
Now for the old story. This Touch Wood Ring is crafted from ancient kauri timber that is aged from 30,ooo to more than 50,ooo years old. Ancient Kauri wood comes from forests buried at the time of the last Ice Age, which are located on the Northern Island of New Zealand. It is called the World's Oldest workable timber. Read The Kauri Story on the Ancientwood website. These points are from their pamphlet.
- The harvesting of Ancient Kauri is a very ecologically friendly practice.
- No standing trees are cut
- These incredible trees are excavated from underground and any disturbed land is carefully restored.
- Every tree grew for more than 1200 years.
- They stopped growing over 50,000 years ago.
This ancient Kauri wood is pretty spectacular stuff and it fills us with a sense of wonder to hold something so very very old.
Bespoke Wooden rings
meticulously hand crafted
in Canada
by David Finch.
Touch Wood Rings
