Dominus Winery Case Study
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Transcript of Dominus Winery Case Study
THE DOMINUS WINERY:A Case Study of an Alternate Masonry System
Building Technology GSD6204Professor Mark Mulligan
David Choi, Madeleine Le, Wilson LeeJanuary 14, 2000
Situated in the heart of Northern California’s Napa Valley, the Dominus
Winery is located near the small town of Yountville, 50 miles north of San
Francisco. It is a 50,000 square foot agricultural shed monumentalized by a
reinterpretation of traditional masonry construction. For the Swiss firm Herzog &
De Meuron Architects, their first American commission was an important debut
of their work to American colleagues. In this essay on the strangeness of seeming
simplicity, the architects have transformed a utilitarian structure into a monument.
“As in all their work, Herzog & De Meuron eschews the Modernist delight in
clarity in favor of the beauty of the blur, where both one thing and its opposite are
constructed in the same place…Like all good monuments, it builds memory: it
encapsulates the site and awakens half-remembered images within us.”1 The
design began in 1995, and the building was completed in 1997
Clients
Christian Moueix and Cherise Chen-Moueix are descendants of a well-established wine making family near Bordeaux. In respect for their
heritage, the clients wanted a building that would be reminiscent of the French Landscape and the architecture of Chateau Petrus. From the
1 Betsky, Aaron, “Dominus Winery,” Domus 1998 April, Dominus 1998 April, no. 803, p. 10
beginning of the commission, the architects were faced with the dilemma of converting a purely functional building type into architecture of high
artistic merit. As Cherise stated: “St. Emillion’s Petrus is one the grandest of all Grand Crus…People are always disappointed when they come to
visit, because there is nothing to see. It is just an old farm building."2 Since the clients view wine making as the highest form of agriculture, they
both desired an architecture that would be a monument to wine making, an architecture that understands the art of winery. The clients are more
than farmers; they are also serious art collectors. Before deciding upon Herzog & De Meuron, they had spoken to world-famed architects such as
Christian de Portzamparc and I.M. Pei. Although their firm was less mature, Herzog & De Meuron’s personal affinity to art and wine was the
critical factor that won them the commission; Herzog is an oenophile and Cherise believed that his office most thoroughly understood
contemporary art.
Site
Herzog & De Meuron situated the building, at the intersection of
the slightly sloped terrain and the foothills of the Mayacama Hills to the
west. Long and rectangular in plan, the building spans 300 feet and is 80
feet wide. It becomes a boundary between two different types of vineyards;
the monolithic form thus marks the transition from the lot designated for
less expensive grapes to the upper slopes that produce grapes for the more
preciousGrands Crus. Standing in the middle of a valley, the building is
2 Betsky, Aaron, “Dominus Winery,” Domus 1998 April, Dominus 1998 April, no. 803, p. 12
relatively flat compare to the rolling landscape beyond. Perpendicular to the natural line in the landscape, the wide arch openings are the gateways
to the vineyard and the mountains.
Its abstract form does not resemble vernacular building types; yet upon closer examination, the stone wall references the stone barns
common to the Napa Valley. Its strangeness is contradicted by this likeness to the more traditional agrarian structure of the region. By heightening
this tension between contextualism and abstraction, the architects elevated the shed into an art form. From a distance the singularity of the form is
seen as an interruption in the natural landscape. This obtrusiveness makes the building a monument, yet it is ambiguous as a statement because of
its abstractness. The winery exists somewhere between a factory and a monument. It is an invention born out of the tension between two
contradictory typologies. The construction of the wall conveys this blurring of the boundary.
Two archways cut through the form each at approximately one-third points of the span. The opening that is closer to the northern side of
the span functions as aporte cochere. This gate frames a view of the upper vineyards as well as the hills beyond. A second cutout to the south is
used primarily as access for pickup and delivery. Traditionally, the Chateaux of Bordeaux have two distinct sides of entry separating the
ceremonial front entry from the service entry of the backside. The architects of the Dominus Winery contested this traditional scheme by placing
both types of entry on the same side, blurring the distinction between service and front entry. Furthermore, The assignment of different functions
to each of the voids breaks the formal symmetry.
Program
The winery’s function as both a container and a marker is most evident in the construction of the exterior stone wall. From a distance the
stone wall’s monolithic appearance fulfills the need for a monumental gesture. Behind the mesh of rocks are glass-and-steel curtain wall system
on the second level, and a tilt-up concrete wall on the ground level. The wine tanks are buried inside a concrete bunker, while the offices above
receive filtered light through the glass. The relative
thinness of the 25m width in comparison to its 140m
length helps preserve a maximum amount of land for
growing grapes. Had the architects propose a less
elongated shape, the building would have lost all the
advantages of its site. The elongated form also allows
for a loose fitting of function within the box. From the
outside, one cannot sense the interior wine making
processes. From within, the building evokes the
atmosphere of old European wine cellars in an
unorthodox way. The loosely held stones remind the
visitors of a cavernous experience of cellars hidden
underneath ground level.
With the creation a self-supporting stone
blanket, the architects were able to build a box inside
the box. The program is divided into two parts: offices
and tasting rooms on the upper floor, and the wine
tanks, cask rooms, and storage rooms on the ground level. The autonomous tilt-up concrete structure inside the southern two-thirds of the building
houses the fermentation rooms and tank storage areas. Openings inside most spaces allow visitors to look out through the gaps between the stones
onto the Napa Valley landscape. The barrel and tasting rooms are contained in a similar one-story structure at the north end of the building. An
open suite of administrative offices sheathed in structural glass sits above this northern section. A concrete-paved balcony surrounds the offices,
turning the space between the glass walls and the stone curtain into a pergola shaded by the rocks.
Although the Winery building does not resemble a specific vernacular building type, and appears as a strange new invention by avant-
garde architects, the layout of the program references the long tradition of French wine making. In the tasting room, a warehouse becomes a
treasure house. A Spartan wine-tasting room overlooks rows of barrels in storage room. The heart of the building is the tasting room which is
accessible from theporte cocherethrough a set of green glass doors that
part to reveal a monastic concrete room, adorned only by a single
wooden table. Flip a switch and a sea of light bulbs hovering from
above illuminates the barrel room that stretches north beyond a partially
frosted glass wall. There, the wine ages in row after row of French oak
casks. Viewing this treasury of viniculture from the minimal tasting
room is a revelation for all extraneous influences have been edited away
to focus one's attention on the wine. The contrast between this dark
heart and the translucent stone skin of the Dominus Winery could not
be any stronger.
Design Concept
The “box-within-box” concept proposes an inner structural box containing different programs and an outer masonry skin as a thermal
regulator for the functions within. One of the chief design ideas was the emphasis on controlling the building’s response to climate and thermal
changes. Herzog and De Meuron tried to take advantage of night cooling in the Napa Valley as a more ecological way of design. The concept of
the self-supporting stonewall was conceived from the very beginning. During schematic design conventional curtain wall systems or steel and
glass structure were ruled out. Their gabion system fulfilled their three main design objectives: 1) ecological integration of the building with the
surrounding vineyard environment, 2) making use of the climate for efficient thermal system and 3) economical use of materials by eliminating
mechanical systems. The climate in Napa Valley can be very hot during day and very cool at night. The gabion stonewall has the thermal ability
to trap and retain cool air during the night and that air is used to regulate the hot temperature present during the day. Additional fans were also
used to help circulate the air.
A crucial part of the process of installing a passive thermal control system as opposed to a modern and machine-controlled system was
proving the validity and feasibility of “free-cooling” and “energy-saving” to the clients. On the design end, both aesthetic and technical measures
came together subtly in an otherwise a monumental object. Herzog & De Meuron pursued the smart skin wall system that would regulate light,
transparency, and ventilation and simultaneously retain the sensibilities of a traditional masonry wall construction. The solution was simple yet
inventive, aesthetically rewarding yet practical.
The wall construction at Dominus contradicts traditional methods of construction. Traditionally, a freestanding dry stone wall
construction had been used as a device for division or a marker of boundary. Each stone is held in place by weight and friction against one
another. This system of construction allowed earth and small plants
to exist within the joints. Both construction and maintenance are
simple. Typically, a battered wall is composed with stones that are
generally very flat and square, and its height is equal to that of its
width. Masons also recommend that the largest stones be on the base
and the foundation course. “Even in severe frost areas, dry walls are
built on very shallow foundations. Since the wall is flexible, frost
heaves tend to dislodge only a few stones, which can be easily
replaced. Each individual stone must be shaped to fit. The process of
trimming a stone requires a chisel and a stonemason’s hammer.
Score a line completely around the stone, then drive the chisel against
to work with the natural fissures in the stone, and always wear safety
glasses.3 The needs of the gabion wall, however, dictated the
negation of flat and square stones during selection. In addition,
smaller -not-larger- stones were used in the construction of the base
for pest prevention.
3 Scott Fitzgerrell,Basic Masonry Illustrated(Menlo Park, California: Lane Publishing Co.), 1981, 54.
Materials
The composition of different stone grades on the facade was designed to manipulate transparency of light as well as ventilation according
to the program and functionality within the building. Since the largest and least densely packed stones were permeable to light and ventilation,
they composed the walls of covered outdoor areas and the tank room where “the fermentation tanks themselves are insulated and fitted with
sophisticated temperature controls.”4 The closely packed smaller grade of stones shielded the more sensitive areas such as the cask cellar and
warehouse where opacity to light and sun and a stronger barrier against temperature changes were crucial to the wine aging process.
The basalt was chosen for its
indigenous existence in the Napa
Valley and for its dark-hue that
melded gently into the agricultural
setting. The quarry site was about
ten miles away and trucks
transported the stones directly onto
the site. During the mock-up process
in Switzerland different stones were
used. While most articles on the
4Annette Lucuyer, “Steel, Stone, and Sky,”Architectural Review1998 October, v. 205, no. 1220, 44.
project report that three grades of stone were used, an interview with Jean Frederic Lusher, the project manager for Dominus Winery, revealed that
only two grades were used. Type A, the larger grade (8”-14”in diameter) created a more porous condition when stacked. Type B, the smaller and
more densely compacted of the two (4”-8” in diameter) was distributed in areas that required more shading, thermal protection, and enclosure.
Thus it was place in areas where the program called for more exposure to wind and light such as in the tank room where Lusher had mentioned
that there was a desire for natural ventilation. According to Lusher, no extensive formal testing was done on the thermal performance of the
gabion stone wall. However, engineers did confirm that the sure mass of the stones would provide adequate energy absorption.
The sizing and thickness of the gabion cages were calculated with consideration to structural feasibility, light penetration, and aesthetics.
Although the architects had many options for the size of the gabion grid, the final dimension of 7.5cm was the result of testing with tomatoes. “A
10cm grid was considered but the 7.5cm was considered more aesthetically pleasing,” said Lusher. Before actual construction occurred, the
architects built two mock-ups, one small scale and one partial full scale. The cages were manufactured in Switzerland and exported flat-packed to
the U.S. Although the wall would have been structurally sound with a
depth of 10 inches, the 14 inches thickness was chosen to accommodate
thermal and visual benefits of the largest stones, 14 inches diameter.
Due to the use of sulfite in agricultural processes, the acidity in the
Napa Valley soil tends to be stronger than most other environments. The
architects were concerned that heightened carbonization would facilitate the
premature aging and rusting of the wires. Therefore, a special gauge of the
steel wire, the Galfon, was chosen to tie the gabion cages. Galfon, also a
Swiss export, was coated with aluminum zinc to provide resistance, five to
six times longer than the normal galvanize steel wire.
Construction Process
Lusher stated that the most difficult part of working in U.S. for
the first time was learning one another’s cultural standards and method of
working.
The construction initiated with the typical slab-at-grade
processes. In accord with basic construction techniques, the entire area
where the floor would be laid should be covered with washed gravel or
crushed rock in order to reduced the capillary rise of moisture. Then a
membrane strong enough to resist puncture when the concrete is placed
should be placed over the gravel. This membrane serves as a vapor
barrier to prevent moisture from entering the slab from the ground.5
Other considerations include a gap in the floor of the barrel storage room.
This is an ancient traditional French method for the aging of wine. The
exposure of the barrels to the earth is crucial because the bacteria in the
ground are essential for the fermentation process.
5J. Ralph Dalzell and Gilbert Townsend,Masonry Simplified(Alsip, Illinois: American Technical Publishers, Inc.), 1984, 225-226.
Taking the center of the main arch as a reference point, the grade level of the building sloped down eighteen inches on both sides.
Therefore, the cage sizes of the first row had varying heights in order to create a level base. The concrete
base coursing was extended to allow the gabion wall to rest on top to minimize settlement of the wall into
the ground. This method allowed the first row to extend below grade, generating a pleasing aesthetic
solution.
The connection details of the concrete wall and the steel structure to the gabion cages are very
simple and “rough” in character. The concrete panels were poured on site in a method called “tilt-up”
construction. In "tilt-up" construction, wall panels are pre-cast on the floor slab. Then workers use a crane
to tilt them into place and secure them with cast-in-place columns or pilasters.6 Before pouring the concrete
mixture, one-inch diameter steel pipes were attached into the form-work at three feet intervals. Due to the
high incidents of earthquakes in the California region, the architects needed to account for seismic loads in
the design of their wall system. In order to prevent structural damaged caused by differential movements
during an earthquake, the gabion stone wall needed to be secured to the more stable earthquake-proof inner
concrete and steel structure. The horizontal pipe segments extend two inches off the surface of the finish
concrete and are welded to vertical steel pipes. Worker then tied the gabion cages to the vertical pipes with
Galfon steel wires at three loops per cage. In theory, the wires served as the seismic buffer. For lateral
support on the upper portion of the building, the vertical pipes were welded to the steel-framing members on
6 Dalzell and Townsend, 249.
the second floor. Lusher confidently assured us that this construction has proved its durability during two earthquakes since the completion of
construction.
For precision of the courses, two gabion cages, one at each corner, were filled and stacked first as a guides to lead the rest of the coursing
on a perfectly horizontal line. Instead of using mortar as in brick construction to join the next layer of gabion cages, steel wires were twirled
manually to stabilize the wall. Lusher stated that only two gabions were installed at a time. To ensure further precision of the construction, the
masons filled the gabion cage with loose crushed basalt on site. Had the stones been filled individually before construction, the steel cages would
not have maintained their original shape during transportation, thus resulting in irregularity of the units.
Two groups, a total of 15-20 people, worked simultaneously, one starting on west façade, the other on the east. They worked horizontally,
assembling two cages at a time for practical and economical reasons. The process took about three months to complete. The height of the wall,
approximately 17 gabion cages, was determined by the need of the client. A higher wall was technically possible but the resulting potential
settlement of the cages due to excessive weight would have undermined the quality of the construction and design. When asked to point out the
most complicated part of the gabion wall construction process, Lusher immediately described the construction of the entrance. A steel lintel plate
was attached to the structural steel frames to provide support for the gabion cages above.
To compliment the two grades of stone, two sizes of mesh were used. The larger 7.5cm grid mesh surrounded the entire building
envelope. At the base of the walls, a finer mesh was then added to prevent mice, which attracted rattlesnakes, from nesting among the rocks. Each
pair of cages was placed into position and restrained by ties to stainless steel pipes cast into the concrete wall panels. In the areas with steel frame,
brackets were used to anchor the gabion stone wall. Through their use of “a single module of 900x450x450mm for [all gabion cages in the] entire
building,”7 an enormous variety in transparencies was achieved by very frugal means.
Water Drainage
Only from a distance, are we able to see the separation of the skin from the structure as the top row of gabion cages stops short of the roof
revealing the fascia. When we stand very close to the stone wall, however, the fascia disappears behind the 2 feet depth of the wall, setting the
edge of the gabion cage against the sky. This quality was achieved by covering only half of the top row cages with flashing. The resulting detail
permitted water from precipitation to run
directly onto the stones inside the cages as
well as hindered precipitation along the
concrete wall. This economic solution
minimized the cost and number of pipes by
reducing the volume of water flowing from
the roof.
Lusher emphasized the power of the
simple water drainage details to accentuate
the dark hue of the basalt. Gutters for
7 Lecuyer, 44.
drainage would have damaged the overall aesthetics of the wall; any mechanical appendages would interrupt the monolithic quality of
construction. The gravel roof was tenuously sloped 3 degrees with the highest point at the mid-point of the short section to accommodate the flow
of water. According to Lusher, the design team had wished for the water from the roof to run solely onto the stones and into the ground.
However, the mechanical engineer advised that the run off water from the roof would have been too much for the land to handle, perhaps resulting
in soggy ground conditions. Therefore, the architects settled for the placement of drainage pipes within the building. The figure below shows a
copper pipe running vertically behind the glass. Two additional pipes on the roof of each long façade also assisted the drainage of water down into
the ground through a pipe, alleviating the topsoil of excess dampness.
Maintenance
The infestation of mice and other pests from nesting in the rock is a common concern in cavity filled construction in the agricultural
setting of Napa Valley. Once a year, a maintenance crew inspects for mice that would attracted deadly rattlesnakes. Lusher delighted in seeing
the color of the stones deepen after a rainfall and the expressive and organic nature of the visually unpredictable façade. The accumulation of dirt
and vegetation are challenges we foresee in the near future. However, Herzog and De Meuron have confidence in their thoughtful design process
that took great measures in forethought such as the protective base mesh and the Galfon wires. They even suggested that perhaps the best
maintenance for this wall is to let nature run its course.
Conclusion
In both the interior and exterior, the architects use minimal means to create grand effects in response to program and site:
“Principals Jacques Herzog and Pierre De Meuron's odd monuments replace the shards of Deconstructivism as the major mode of expression for the European avant-garde. They use abstraction not as a tool to edit out complexity, but rather as a way of assembling programmatic and siting contradictions into singular and strong forms.By finding a coherent shape that contains, rather than replaces, program and context as well as the architects' own biases, they make buildings that donot refer directly tothe past, the surroundings, or a particular style. [They] shape them into images that seem both familiar and strange at the same time. With cantilevers, contortions, andcamouflage, Herzog & De Meuron frustrates our assumptions that all Modern architecture is clear and clean, instead making something highly elusive.” 8
Not unlike the screen porches of vernacular buildings, the rocks protect the interior from the strong California sun. The wall is
simultaneously transparent and solid, traditional and innovative, contextual and a-contextual. The rocks for the four walls were quarried from
nearby American Canyon. These rubbles are held together by a gabion system, which is a steel-mesh screen used to prevent stones from falling
onto cars following excavation of hillsides during highway construction. Common in both the Swiss Alps and the California Sierras, this steel
mesh has been used for some time in the construction of infrastructures. The architects appropriated and reconfigured this technique to suit their
programmatic needs. By varying the size of the mesh and the stones at different places on the wall, they were able to control levels of light that
would reach the interiors. While appearing to be solid from a distance, it is a diaphanous wall that merely surrounds a secondary wall system.
“They designed a winery that is prisoner to the vines," Christian Moueix says admiringly.9
8 “Herzog & de Meuron: Bodegas en Napa Valley” EL Croquis, 1998, n. 91 pp. 16-359 Ibid
As it regulates practical aspects of human needs such as light, ventilation, and thermal protection with predictable precision, the gabion
stone wall also serves as a monument to the art of wine making. Through the use of ordinary existing construction components, Herzog and de
Meuron have invented an alternate ecological smart-skin that endows traditional masonry construction with new creative solutions.
BIBLIOGRAPHY
Betsky, Aaron, “Dominus Winery,” Domus 1998 April, Dominus 1998 April, no. 803
“Herzog & de Meuron: Bodegas en Napa Valley” EL Croquis, 1998, n. 91
Fitzgerrell, Scott.Basic Masonry Illustrated, Menlo Park, California: Lane Publishing Co., 1981.
J. Ralph Dalzell and Gilbert Townsend,Masonry Simplified, Alsip, Illinois: American Technical Publishers, Inc., 1984.
Lecuyer, Annette. “Steel, Stone, and Sky.”Architectural Review1998 October, v. 205, no. 1220.
PCI.Architectural Precast Concrete, Second Edition. Chicago: PCI Precast/Prestressed Concrete Institute, 1990.