Tuesday, August 16, 2016

Practical Geometry - as described by those who used it, Part 2

The last post  discussed how Asher Benjamin and Owen Biddle presented Practical Geometry in their pattern books in 1805 and 1806.
This post focuses on Minard Lefever, and finally Peter Nicholson, who inspired them all.

Minard Lefever ( 1798-1854) wrote 5 pattern books between 1829 and 1856.
The Modern Builder's Guide was published in September 1833, in New York.
In his Preface Lefever says "...it will be proper to specify the authors whom I have either consulted or made extractions from,..."
One of these was Peter Nicholson.  Because Lefever copies Nicholson's drawings  directly I will post only the latter's introductory geometry.

Lefever writes 35 pages of  descriptions for 21 plates on "Geometry Adapted to Practical Carpentry".
Here are Plate 8  and Plate 20.

Minard Lefever, The Modern Builder's Guide, NY, 1833, reprint by Dover Publications, NY, 1969.

Peter Nicholson (1765-1844) practiced architecture, mathematics, and engineering in Scotland.  He taught and wrote 27 books.  The Carpenter's New Guide was first  published in 1792 in Great Britain. His books were regularly reprinted in the States.

The book reproduced here was printed in Philadelphia in 1830, his 10th Edition with, he writes,"6 new Plates".  The book is 121 pages long not including the Index.
27 of those pages are of - as his title page says - Practical Geometry for Carpentry and Joinery, "the whole founded on the geometric principals; the theory and practice well explained and fully exemplified" on 10 copper-plates.

In the Preface he says, "...it is Geometry which lays down all the first principals of building, measures lines, angles, and solids, and gives rules for describing the various kinds of figures used in buildings; therefore, as a necessary introduction to the art treated of, I have first laid down, and explained in the terms of workmen, such problems of Geometry as are absolutely prerequisite to the well understanding and putting into practice the necessary lines for Carpentry."

His introductory geometry plates match those of Asher Benjamin, Owen Biddle and Minard Lefever, all of whom acknowledge him in their prefaces.

Nicholson's Plate 10 is Lefever's Plate 8.

I will bring this book to the 2016 IPTN Workshops in September. It is fragile.

If you would like to read the titles of Peter Nicholson's books, they are listed at the end of his Wikipedia biography.

Other architectural historians must have looked at the first pages of these books. Everyone cannot have just turned to the illustrations of mantles and window casings, building plans and elevations and ignored the plates on geometry. Why hasn't someone else wondered out loud why so many pages on geometry were included in a book about construction?

Someone must have considered that if Nicholson's The Carpenter's New Guide went through 10 editions and was published in the States as well as Great Britain - as well as being directly copied - that carpenters were reading it, using it, that his information was useful, that maybe we should understand what he wrote.

The builders who came before us used geometry to design and build. The knowledge was taught to the next generation hands-on. Books were not needed.
Boys were 'apprenticed', learned their craft and became 'journeymen', traveling to sites to earn and learn. Eventually these men became full carpenters, 'masters', and were admitted to a guild. The guild system was not always possible in the States. Men quit their apprenticeships. moved west or into cities. The skills and knowledge that masters were expected to impart had to be taught in other ways. Asher Benjamin and others set up a school in Boston. The pattern book was another solution - a way for 'young carpenters'  (to quote Owen Biddle) to teach themselves the necessary construction skills, beginning with geometry.

Monday, August 15, 2016

Practical Geometry - as described by those who used it, Part 1

Asher Benjamin, Owen Biddle, Peter Nicholson, and Minard Lefever

What they wrote about Practical Geometry in their pattern books: Asher Benjamin in 1806, Owen Biddle in 1805, Peter Nicholson beginning in 1792, Minard Lefever in 1833.

I want their words to be easily available to anyone who is curious - someone who comes upon this blog or someone who comes to the 2016 IPTN workshops in September.

Remember that the pictures can be expanded - click on them.

Asher Benjamin's,The American Builder's Companion, was first published in 1806, updated and edited through 6 editions to 1827.

His title included the various chapters he has included. The first is  "Practical Geometry".

In his preface he says, " I have first laid down and explained such problems of Geometry, as are absolutely necessary to the well understanding of the subject."

His first 18 of 114 pages are about using geometry to design and build.

I have copied here his Plate I and its accompanying notes.

Asher Benjamin, The American Builder's Companion, Boston, MA, 6th ( 1827) edition, Dover Publications Reprint, 1969. Benjamin wrote at least 6 pattern books beginning in 1797, all popular.

Owen Biddle's book , Biddle's Young Carpenter's Assistant, 1805, was half the size of Benjamin's, easy to tuck into a tool chest. His first 9 pages of 112 are devoted to Geometry.
First comes how to construct a drafting board and attach paper to it, followed by how to make a T square and what kind of instruments to use. Then he says, " I shall now proceed to explain some of the most useful geometrical problems, which every Carpenter ought to be acquainted with". p.4

Owen Biddle, Biddle's Young Carpenter's Assistant, Philadelphia and New York, 1805, Dover Publications reprint, 2006. This is his only book  A respected master carpenter in Philadelphia, he died in 1806.

to be continued....

Friday, August 12, 2016

2016 Preservation Trades Network Workshops, September 9-11, Clermont Farm, Berryville, Virginia

The annual gathering will be at Clermont  Farm now owned by the Commonwealth of Virginia.

Here is the link to the farm: http://www.clermontfarm.org/ Their facebook page has good pictures.
The National Barn Alliance will be there too.  On Friday there will be a barn tour - http://ptn.org/iptw-2016/barn-tour

There will be blacksmiths, lime mortar makers, timber framers, window repair people, masonry specialists, painters, roofers...

 Last year at Shelburne Farm I watched dimensional lumber come out of a log with bark, all by hand. I saw a Georgian cabinet built, and windows become like new.  The pictures are from that gathering.

I will be there to teach 2 sessions on
                Practical Geometry
 which, to quote Owen Biddle in 1805 "every Carpenter ought to be acquainted with".

Or more formally: "Geometry is the foundation on which practical Carpentry is based." Minard Lefever, 1833,

The sessions will be hands-on.
I will have compasses, pencils, erasers and straight edges. And drawings.
I will be helping whoever shows up see the geometry which governed framing and design for churches, mansions, houses, barns. As we uncover the geometry participants will see how design and structure come from the compass.

We will decipher brick houses in Virginia, wood frame churches in New England, houses built from 1680 to 1840. For people who want to see how much they already know I will have the plates from the first pages of the pattern books which present  "such problems in Geometry, as are absolutely necessary to the well understanding of the subject." (Asher Benjamin, 1827) Will they master the problems with a compass and a straight edge?

The pattern books of Asher Benjamin, Owen Biddle, Peter Nicholson, Minard Lefever,  will be available along with posters and handouts on Robert Adam and William Buckland.
And paper for experimenting

I demonstrate twice. There will be  plenty of opportuity for me to watch and learn from the other presenters, to explore the farm and its buildings, and talk with people. I know I will have a great time.

You can come too.

Monday, July 25, 2016

Washington County, NY, House - a Dutch vernacular frame

written January, 2016

The house has been stripped to its frame. The sheathing removed, each board numbered as it came down. The stair and moldings (inside and out) carefully moved into storage.

Now the frame is visible -
no ridge beam,
12 bents: each is a post on either end mortised to a 2nd floor joist.
The plate across the top holds them all together; The 14 rafters sit on the plate and are not spaced to match the bents.

The joists on each end are mortised into posts.
Plates, mortised into the sides of the  posts, space the bents and carry the intermediate 2nd floor joists.

Here is a post with its joist and the pegs that hold the tenons of the plates seen from the outside.

Here seen from the inside, are: 2 posts, an intermediate stud; 2nd floor joists, plates and intermediate joists.

We think it was assembled bent by bent, the intermediate plates added one at a time as each bent was set into the sill.

I have measured the first floor - twice The first time it was just too cold. I hurried. I wasn't careful.

The framer used Hudson Valley Dutch framing. The house was clothed in the latest Federal style with possible Shaker influences. Inside it retains the traditional system.  

I need to add more, especially about the Dutch way of framing.
An orthographic perspective would make the frame easier to read.
The frame details deserve a post of their own.
So does the careful cleaning and repair of the frame by Green Mountain Timber Frames.
I want to redraw the front elevation to reflect the frame we saw and measured compared to the plaster and clapboard surfaces I saw and measured in the beginning.

However, it is July, months later.  Time to share!

Sunday, July 24, 2016

The Old First Church Geometry - the Floor Plan - Part 4

 I first wrote about the geometry of the Old First Church in Bennington, Vermont, in September, 2012, focusing on the 2nd floor windows with their round tops.

I will not repeat that post and the ones that followed -  just expand upon it here.

As I studied how the church was designed I saw that the window design was the logical extension of the basic design.

This spring the full window design and then the geometry of the floor plan - which had eluded me - became obvious.

The circle geometry which determined the curves in the half round top also determined the size of the window itself and muntin pattern  in the lower section.
The completed circle of the top half intersects with the circle which begins in the lower sash. The circles divided in 4 determine the size
of the window panes.

The panes themselves are not quite square because of the thickness of the frame.

The pattern in the rounded top is made by 7 intersecting circles. The window itself is 2 intersecting circles.

I have called these 'rolling circles' because visually they seem able to roll one way or the other. Perhaps in a church the circles roll toward each other and meet..
It would be fitting symbolism for Old First Church whose covenant says the members hope to " ... become a people whom the Lord hath bound up together... "

Here is the floor plan, measured and drawn in the 1930's by Denison Bingham Hull, the architect who supervised the church's restoration.

I superimposed a circle with its rectangle marked in red which  matches the circles that define the east interior elevation and the exterior front elevation.

This is what I had not seen before -  how the geometry of the floor layout uses the same forms as the windows. Both are 2 intersecting circles.

The rectangles laid out by the circles determine the size of the sanctuary. The diamond shape where the 2 circles cross, the center of the church,  is the  location of the dome -an acoustic device - a technological tour-de-force in 1805. The narthex fills and over flows the lower quarter of the circle. The depth and width of the front bay is determined by the arc of the circle's perimeter.

Expanding the circles in the way that the window design    'roll'  I saw that Lavius Fillmore, the master builder, did not need divide his circles into daisy wheels to locate columns and determine proportions.

This relationship of one circle to another in a linear (up and down, side to side) pattern rather than relating one circle to the next by moving around the perimeter is seen in all the elevations and plans for the Old First Church.

In the drawing to the left I have added small circles at the intersections of the arcs which mark the lines of the columns, the corners of the front bay and intersect with the perimeters of the circles at the 4 major columns - the black squares - which run from  piers in the basement through the sanctuary into the attic to anchor the trusses which carry the roof and the trusses from which the dome is suspended.

Fillmore need not have drawn a daisy wheel with its 6 petals to refine his design.
He might just have rolled his circles.

In many ways these different approaches to 'basic geometry' - as Asher Benjamin calls it - cross-reference each other. The daisy wheel and the rolling circles are variations of the same proportions.
My 'aha' moment is when I find for one way of working that is clean, simple and 'obvious'.


Saturday, June 25, 2016

The Persistence of the Salt Box Plan, Part 2

The original owners of these houses in Bennington County, Vermont, have ancestors who lived on the New England seacoast. 

Why is that useful information? 

Settlers built what they knew. 
We have seen this in the houses the Dutch built in New Amsterdam, in the Victorian era houses in Oregon which look like the 1840's houses on the East Coast their owners had left behind, in the houses in Ohio's Western Reserve which copy those their owners knew in their home towns on the Connecticut River. 

House-wrights in new settlements built what they had been taught 'back home'.  They might have seen a pattern book; but those guides showed the Classic Orders, complex roof details, stairs and railing, mantles and entrances: decoration - not basic post and beam framing systems. A house-wright learned his craft by apprenticing to a master-builder: hands-on. He built what he had been taught and had seen.

Bennington County house-wrights copied the saltbox plans they knew.

Here are two examples.

Samuel Safford came with his family to Bennington, VT, in 1761. The next year he built the town's first corn mill and a saw mill. In 1769, he built this house for his family, 2 stories with a tight front stair against the center chimney, a large room on either side, a long narrow kitchen behind with small service rooms on either end - the salt box plan. The Safford family had lived in Hardwick. MA. Their parents had lived in Ipswich, MA. Houses with this floor plan, pre-dating this one in Bennington, can easily be found in both towns.

The Safford Mills Inn is now a B&B and a restaurant, open to the public.

The house where Robert Frost wrote 'Stopping by Woods on a Snowy Evening" is also open to the public. It is a museum in Shaftsbury, VT.

Built by Amaziah Martin in 1769 it uses the salt box floor plan with a variation, a center hall. The chimneys were located on the end walls which are stone.
Martin was part of a group of Baptists who came to Shaftsbury about the same time that Bennington was being settled.
The Baptist families came from Dover Plains, NY. Their parents had come to Dover Plains from the area around Smithfield, RI, where there are many salt box houses. 

Both of these houses were dramatically updated several times in the last 240 years. For an architectural historian - me - they are fascinating to visit.

I have researched the family lines for the Saffords and the Martins. I think it adds little to my thesis to include those genealogies here. 

Thursday, June 9, 2016

Geometry as Design

At the PTN Workshops last summer I tried to teach geometry in construction. I assumed most people had an understanding of geometry and facility with a compass. 
I was wrong.

This year I have been 'practice teaching' with students as my guides.

This year I taught children, teenagers and adults how to use a compass. 
How it opens, how it twirls, how to keep it steady.

Everyone needed these basic skills before I could begin to help them understand the science and art of geometry, never mind how it was used to frame a building.

I thought people knew this, like the ABC's. I thought it was taught in schools, but I had teachers practicing and asking for help along with the students.

Kids and adults responded in the same way, with awe and amazement, joy and laughter - with lots of  enthusiasm.

When the children realized they could make a star by connecting the 6 points on the perimeter of the circle, they had to show me how! tell me what I should connect next!

They had magnetic tessellation blocks for exploring.

With teenagers and adults real building elevations worked best. Most of my students know the Bennington Old First Church. Since good measured drawings of the church exist, used those.

I began by asking the students to draw in the floor line, right at the bottom of the doors. This would have been where the framer began his layout, but I didn't tell them. I have found that interesting knowledge is - at this point - extraneous information.

I asked them to draw diagonals across the main body of the church - from the floor to the eaves. We noticed that the lines run up the sides of the roof over the main door and cross at its ridge. 

Then with a compass we found the radius and drew the circle.  This could take some time with people who were not familiar with compasses, radii, or circles. The discovery made the effort worthwhile.

I pointed out that if the roof lines extended through the steeple those lines would meet at the top of the circle  - the ridge of the roof.
 If time permitted we found the top and bottom points on the circle with the compass. We divided the circle beginning with a horizontal diameter to find  6 more points along the perimeter and saw how the facade of the church was laid out.
We added circles, as many as we had time for. Everyone kept their diagrams.

I am pleased with the interactions. All the students knew what they had drawn. Some could explore farther on their own. Even those who couldn't be rigorous had fun.

The adults had basic tools for real conversations about the use of geometry in design and construction.