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Any stone used as decorative facing material that is not meant to be load bearing.

Contents

HistoryEdit

Thin stone veneer was first developed in the late 19th century, but there were materials developed much earlier that foreshadowed the use of stone veneer. Parts of the Roman Coliseum were made out of marble veneer that can no longer be seen.[1]:27 The holes in structure of the Coliseum are from the anchors of the veneer panels. Structures throughout the Roman Empire were made in part out of stone blocks, including the Segovia aqueduct in Spain, which was made out of granite blocks. People in the Roman Empire also developed concrete (out of cement and rubblestone), which helped builders expand structures greater than before. Stone was used as a part of the facings of these new concrete structures in the Roman Empire, as seen in the Coliseum.[2]

Modern stone veneer first made its appearance in the late 1800s. The oldest of modern stone veneer product is now disintegrating. It was cut into thick portions and then hand tooled into the appropriate panels; the stones that were used were “granite, marble, travertine, limestone, and slate.” Early in its development, thin stone veneer only had the capabilities to be utilized in areas such as the inside of buildings, street-level facades and storefronts.[1]:28

In the Late 19th and early 20th centuries non-load-Bearing stone veneers were regularly affixed to load-bearing walls behind. As buildings began to grow taller with the advent of skeletal steel framing, it became necessary diminish the thickness and weight of masonry walls in order to withstand the dead weight of the building. Without steel supports, load bearing walls could grow several meters thick on their lowest stories. A solution employed in the construction of early skyscrapers was the use of a steel structural frame that supported exterior stone walls at every floor, thereby distributing the load into the frame. This avoided a gradual buildup of weight that resulted in inconveniently thick lower walls.[3] The Empire State Building uses this method, having two steel beams for attaching stone veneer on each floor; one inside to bear weight, and one acting as a shelf outside to support the building's limestone veneer.[4] One-and-½ inches became the common thickness of stone veneer in the 1930s. The utilization of thin stone veneer for complete facades of buildings popped up in the 1940s. Stone veneer construction became much of what we see today in the 1950s. Transportation improved, so stone veneer was transported more efficiently and at lower costs than ever before. Methods to attach veneer to steel were developed; diamond-bladed tools became popular for developing thin stone veneer, while elastomeric sealant began to replace mortar techniques in the construction process. Thin stone veneer in the 1960s became more of a standardized look – in fact, standard education on stone veneer became available in The Marble Engineering Handbook and Marble-Faced Precast Panels, which were published by the Marble Institute of America and National Association of Marble Producers.[1]:28

As stone veneer panels got thinner in the 1960s, the properties of the stone used became more important in order to compensate (as did safety considerations). Concrete as an aid to stone veneer continued to develop, as “in order to eliminate bowing, cracking, and staining of the veneer.”[5]

“Diamond-studded cables” were used to cut Italian marble into the necessary slabs as a part of an era of specialization in the 1970s.[1]:28 A 1976 patent shows that the stone material of composite stone veneer could be finished and developed in such a fashion that “it does not have the appearance of being a part of a composite stone veneered product.”[6]

The stone veneer was able to be cut to a thickness of 18 inch (3.2 mm) in the 1980s because of improvements in technology. The thickness of typical thin stone veneer was three centimeters by the early 2000s. Anchors of support were provided by a specific type of stainless steel or “of aluminum with a non-corroding material separator between the metal and stone.” These anchors are attached to the back of the panels with a rod.[1]:28

SystemsEdit

There are a variety of systems for attaching stone veneers to facades including dowel, kerf, and undercut anchoring systems as well as direct fixing.

The direct or adhered fixing system relies on a mortar or cement bonding between the substrate wall and the backside of the stone veneer. This application is generally used indoors as exterior weathering and temperature extremes cause the veneer to crack and spall. The complete connection between the veneer and substrate does not account for differing rates of thermal expansion between materials, causing them to bind under pressure.[7]

Most exterior veneer systems hang stone from a support wall by pins and anchors allowing air space between, essentially using stone as a rain screen. Anchorage systems are superior for exterior use because they permit any water that permeates the veneer to escape, while air space allows the materials of the supporting substrate wall to expand and contract at different rates to those of the veneer.[8] The dowel anchorage system is one such method of hanging veneer. The system relies on holes drilled into the edges of stone panels in which metal dowels are inserted. The dowels are connected to an angle bracket that is in turn connected by anchor bolts to the building's load-bearing wall or steel frame. Kerf anchorage systems operate in much the same way with different metal hardware. The kerf system uses grooves cut into the edges of stone veneer panels in which kerf plates or cleats are inserted, those plates are mounted to the wall behind and act much like a shelf on which the stone panel rests. Both the dowel and Kerf anchorage systems can be attached to the top, bottom and sides of each panel ensuring a secure hold and binding the panels together to make a complete veneer.[9]

A fourth and somewhat less common anchoring system is the Undercut anchoring system which uses an expansion ring on the end of a bolt to lock into an undercut hole in the back of a veneer panel. Pressure from tightening the bolt causes the expansion ring to flare out, filling the undercut hole. The bolt is then affixed to anchorage system connected to the supporting wall behind.[10]

MaterialsEdit

Stone veneer can be made from natural stone as well as manufactured stone. Natural stone veneer is made from real stone that is either collected, i.e. fieldstone, or quarried. The stone is cut to a consistent thickness and weight for use as a veneer.

Manufactured productsEdit

Manufactured stone veneer is fabricated by pouring a lightweight concrete mix into rubber forms and painted with a coloring process which makes it resemble real stone. The stone veneer produced is then attached to walls with special mortars.

Flexible stone veneer is fabricated by pulling a thin layer of stone from a slab of slate, sandstone, or mica schist. It is backed by a composite material.

See alsoEdit

ReferencesEdit

  1. ^ a b c d e Scheffler, Michael J. (2001). "Thin-Stone Veneer Building Facades: Evolution and Preservation". APT Bulletin. 32 (1). JSTOR 1504690.
  2. ^ Chacon, Mark A. (1999). Architectural Stone: Fabrication, Installation and Selection. Canada: John Wiley & Sons. p. 7. Retrieved 30 November 2011.
  3. ^ https://books.google.com/books/about/Historic_building_fa%C3%A7ades.html?id=j-tSAAAAMAAJ | Historic Building Facades | William G. Foulks | Preservation Press.
  4. ^ https://books.google.com/books/about/Historic_building_fa%C3%A7ades.html?id=j-tSAAAAMAAJ | Historic Building Facades | William G. Foulks | Preservation Press.
  5. ^ Donaldson, B. (1988). New Stone Technology, Design and Structure for Exterior Wall Systems. Baltimore: American Society for Testing and Materials. p. 89. Retrieved 20 October 2011.
  6. ^ US 3950202, Hodges, William E., "Method of making a composite natural stone veneer product", published 13 April 1976 
  7. ^ Stone Cladding Engineering | Rui de Camposinhos | Springer.
  8. ^ Stone Cladding Engineering | Rui de Camposinhos | Springer.
  9. ^ Stone Cladding Engineering | Rui de Camposinhos | Springer.
  10. ^ Stone Cladding Engineering | Rui de Camposinhos | Springer.