A prime example of computerization is the ordering-and-materials-control system. NNS cannot afford a huge inventory of steel plate and other materials sitting around rusting in the humid Tidewater climate. There is only limited space for storage and construction, and every bit must stay busy for NNS to turn a profit. To minimize this potential waste, NNS has installed a computerized "just-in-time" ordering-and-materials-control system. The many components and raw materials (steel plate, coatings, etc.) that go into a Nimitz-class carrier arrive exactly when they are needed. No earlier, and no later. In this way NNS's investment capital is not needlessly tied up, and the final cost to taxpayers is reduced by millions of dollars. The NNS work-force has also become more efficient, since fewer items need to be stored, protected, hauled from place to place, and inventoried.
The actual start of construction begins some months prior to the official date of the ceremonial keel-laying. At that time, the Dry Dock 12 cofferdam is placed so that about 1,100 feet/335.3 meters of room are opened at the rear of the dock. This leaves 900 feet/274.3 meters at the river-gate end of the dock for construction of tankers or other projects. NNS workers then begin to lay out the wooden and concrete structural blocks that the carrier will be built upon. Building a ship that displaces over 95,000 tons/86,100 metric tons on wood and concrete blocks may sound like building a skyscraper on a foundation of paper, but NNS uses lots of these blocks to spread the load around. This very old technique is also used when ships are brought into dry dock for deep maintenance. Some things just work, and cannot be improved upon.
The close tolerances in the construction of a Nimitz-class carrier demand absolute precision from the start. Exact placement of the first keel blocks is critical, as they represent the three-dimensional "zero" points upon which everything else is built. This preliminary work goes on for four to six months, until the keel-laying ceremony draws near. At the same time, some initial assemblies are welded together and stored on the floor of the dry dock, since storage space in the main construction yard is tight. At the ceremonial laying of the keel on a Nimitz-class vessel, the guests include the Secretary of the Navy, the Chief of Naval Operations, and hundreds of other dignitaries. By tradition, the ship's "sponsor" (a sort of nautical godmother) is appointed-usually the wife of a high-ranking Administration official or politician whose favor is being sought by the Navy. Then a ceremonial weld is made in the first "keel" member (a steel box girder built up along the centerline of the lowest part of the hull), and the carrier's construction is officially under way.
Now a thirty-three-month countdown clock starts. From this day forward to the launch date, the construction process is a race to determine the milestone bonuses and resulting profits for NNS stockholders. Meanwhile, Navy officials plan dates for commissioning and first deployments, select the "plankowner" officers and crew who will first man the new carrier, and assemble the "pre-commissioning unit" (PCU). These are the sailors who will report on board the ship while it is still under construction, in order to learn every detail of maintenance and operation.
Back at Dry Dock 12, the thirty-three-month construction moves forward rapidly. The secret to staying on schedule is "modular construction," a technique originally pioneered by Litton-Ingalls Shipbuilding in Mississippi. Rather than constructing a ship like a building, from the bottom up, the ship's designers break the design down into a series of modules. Each module is completed alongside the construction dock, with piping, fixtures, and heavy equipment already installed. Then it is lifted into place and "stacked" with other modules to form the hull. When that is done, the modules are "joined" (welded together). Pipes, ducts, and electric wiring bundles are connected into a mostly finished configuration, and the ship is "floated" out of the dock (or launched), with final work done alongside a "fitting-out" dock elsewhere in the yard. This mode of construction has many advantages. For one thing, the ship can be launched at a more advanced stage of construction than used to be the custom, which reduces costs considerably. Work that takes an hour to do in an NNS workshop usually takes three hours out in the yard, or eight hours in the ship once it is floating in the water. So anything that can be built in the shops or installed in the yard before it is assembled reduces costs; it is money in the bank.
Though modular military shipbuilding was pioneered by Litton-Ingalls, the scale at NNS is far greater. At NNS, they call this the "Superlift" concept. By way of comparison, Litton's largest module weighs around 500 tons/ 453.6 metric tons, while NNS utilizes modules up to 900 tons/816.6 metric tons lugged in place by the huge bridge crane. NNS can build a Nimitz-class carrier with about a hundred "Superlift" modules. Two dozen "Superlifts" make up a Nimitz-class carrier's flight deck, while the bow bulb and island structure are individual Superlifts.
A Superlift starts as a small mountain of steel plates, brought by rail and truck to NNS. Flame-cut to exact tolerances in the shops just south of Dry Dock 12, the plates are tack welded together by spot welds, then permanently joined by robotic welders along a pair of side-by-side production lines. These are then linked into the structural assemblies that form each Superlift. Once the basic structure is completed, cranes move it to the large assembly area next to Dry Dock 12. Then NNS yard workers crawl over and inside it to "stuff" electrical, steam, fuel, sewage, and other lines, fittings, and gear into place. Sometimes Superlifts are turned upside down, to make "stuffing" easier. When a Superlift is ready for joining, the nine-hundred-ton bridge crane is moved into position overhead, the lift cables are fastened, and the assembly in Dry Dock 12 made ready. Despite a Superlift's gigantic size and weight, this is a precision operation, with tolerances frequently dictated by the relative temperatures of the ship assembly and the Superlift. Depending on temperature, the metal structure of a Superlift can easily expand or contract over an inch during a given day on the Tidewater.
Around the assembly yard, several dozen Superlifts are in various stages of preparation at any given time. Some interior and exterior painting is done on Superlifts, to make this nasty and environmentally sensitive job a little safer. Because power, water, and air-conditioning can be installed in a Superlift while it is being assembled, the construction process is considerably facilitated. This is particularly helpful in the hot, muggy summers and cold, wet winters of the Tidewater region. There is a particular order to how Superlifts are stacked. The initial Superlifts-including the double bottom, reactors, steam power plants, ammunition magazines, and heavy machinery-are laid around the keel structure. In general, these items (making up the bottom of the middle third of the carrier) are the heaviest and most deeply buried components, and cannot be accessed or installed easily later on. They take some four months to assemble.