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Recently some dear friends of mine completed a lovely video they made about me, my work and my company. This work was done by Burton Stein, his daughter Autumn Layne Stein, and Autumn's fiance, Matt Goodwin. I am very grateful to them for this work.
Here it is!
I decided to make a concrete driveway at my property in Alfred, NY. It gets very muddy here, so a concrete driveway will be very helpful. I need the driveway to be strong enough to accomodate heavy trucks. It is 8 inches thick, with #3 (3/8 inch diameter) basaltic fiber reinforced polymer rebar, arranged every foot on center. I'm using 4,500 psi concrete, and doing pattern stamping with a "European fan" pattern, finished with coloring and finally sealed.
I realized that I had to build a garage at the end of this driveway, beginning at the end. In the past month or so I assembled this prototype, in a simultaneous attempt at several new experiments.
The garage is 12 ft. wide, 20 ft. deep, and 8 ft. tall at opening. FRP rebar is located every 8 inches, in walls and arch.
I recently finished the second coat of paint on the living room of a building I'm currently completing. Since it is clean and empty, I thought this might be a good time to briefly discuss the room's acoustics.
My dear father left me a pair of Klipschorn speakers, something of a 'classic' pair of loudspeakers, designed and made by Paul Klipsch. These are a pair of vintage speakers, renowned for their efficiency and warm sound.
Knowing that I wanted to place these speakers in this room, I consulted the Klipsch website to find out what the optimal design and proportions of the room should be. "Klipschorn speakers typically perform best when positioned in the corners on the long wall of a rectangular room. If the room is very narrow and long with corners farther apart than 18 to 20 feet, the stereo image may not be optimal. A room with a length to width ratio of 1.00 to .618 is preferred." The same ratio is applied to the height of the wall, so that the ratio of the width of the room to its height is 1.00 to .618. These ratios resulted in the room having the dimensions of 30 ft. 8 in. long, by 19 ft. wide, by 11 ft. 8 in. tall. The arched ceiling goes to a top center height of 16 ft.
The ratio of 1.00 to .618 may sound familiar to any mathematically inclined people. This is the ratio provided by the Fibonacci sequence. These ratios are ideally reflected in al three axes: x,y and z. Thus the proportions of the room are those of a 'golden cube.' These same ratios are found in the Greek Parthenon. It is both visually appealing and acoustically beneficial. Some say that these ratios help prevent constructive or destructive interference of certain frequencies; this idea seems to be disputed by others.
The only other suggestion offered by Klipsch is to include an arched ceiling, for more resonance and a fuller sound. This room has an arched roof, it's the focus of my work.
The stereo sounds great, it really rocks out: whether it's Beethoven or Jimi Hendrix.
In designing and assembling a masonry building, the engineering work can provide helpful insight which is simple and powerful.
For example, if we consider the masonry building I'm currently completing, it's insightful to ask: where is the highest stress in the building? Where is the highest compressive force, squeezing together? Where is the highest tensile force, pulling apart?
The engineering for this building was done by Cheng-Ning Jong, PE. He has some familiarity with my company's masonry system, since he helped compose, file and prosecute all of our patents. We've worked together for several years and have a good rapport, a comfortable back-and-forth as we discuss, develop and fully articulate ideas.
Mr. Jong's most critical role, in my opinion, is the detailing of the reinforcement and the size of the concrete footer from which the stem wall is laid. A 'footer' is the base of the building, typically located in an excavated trench. Here's a picture of the footer, with the first few block being arranged for the stem wall:
A stem wall is the bottom section of all the vertical walls buried below the ground, sitting on the footer. Here is a completed stem wall for a room:
This building has arched masonry roofs, domes, half-domes, flying buttresses, arches meeting at intersections; there is a lot of structural configuration, rebar, weight, stress and so on within the building structure. Here are some architectural drawings, showing some of this detail. Our architect for this building was Robert Ferry, AIA, RDP.
I've just finished a closet in a masonry building I'm making. A closet allows me to try certain steps, before committing such steps to the entire building.
How will the drywall work? Test it in the closet.
How will the paint look? Try the closet.
I awoke to a beautiful 15 inches of fresh powder. I took a few pictures of these masonry buildings covered in snow. The domes, arches, catenary forms: all seem to create interesting topological snow surfaces.
Sometimes people will ask about how appropriate a masonry roof is for big snow loads? They only get stronger with more weight, and the snow also helps insulate even more. These buildings can handle extreme snow loads.
