The Battleship Texas was built between 1911-14 by Newport News and Dry-Dock Co. At this time in our history the Panama Canal was completed, the Titanic sank on her maiden voyage and the Wright brothers had flown for the first time ten years earlier. Seems like a very long time ago yet the USS Texas is still with us today.
Our Navy first began using steam engines during the Civil War. Although there were several different types of Ironclad’s built during the war most remember the USS Monitor and the CSS Merrimack. These two ships both claimed victory in their battle but one thing was certain it was a revolution in Naval ship architecture.
The first American, steam powered ship for commercial use was the Clermont. The Clermont was a 133-foot. passenger ship that traveled on the Hudson River in 1807. It had a one-cylinder steam engine that drove paddlewheels on either side and had a top speed of 5 knots.
The application of steam engines had proven itself in the 1850’s but it wasn’t until the late 19th century before a drastic reduction in the size of the power plants, together with huge increases in their efficiency, was developed. This was thanks to the new types of boilers and compound cylinder engines operating at previously impossible temperatures and pressures.
A surprise came when an English engineer named Charles Parson demonstrated to the Royal Navy a steam driven turbine engine in 1897. The steam driven turbine soon became the engine of choice for naval ships beginning in the U.S. Navy with the USS North Dakota BB-29 commissioned in 1910.
HMS Dreadnought was built in 1906 and became the new standard in battleships that year due to her size (22,194 tons) which was in some instances twice the size of previously built battleships. The Dreadnought used ten 12- inch guns mounted in five turrets, the all big gun design. The Dreadnought incorporated the steam driven turbines for her engines that gave her a top speed of 21.6 knots.
An example of ship sizes built during the same time frame was the German battleship Deutschland which was launched in 1904 was 13,993 tons and a top speed of 18 knots. The Deutschland had four 11- inch main guns in two turrets and fourteen 6.7- inch guns.
The USS Texas BB-35 was built when the steam driven turbines of the time were replacing the steam reciprocating engines. The Navy had installed turbine engines in battleships from USS North Dakota BB-29 up until the USS New York BB34 and the USS Texas BB-35. USS Nevada BB-36 went back to a turbine engine. The USS Oklahoma BB-37 was the last battleship to have the steam reciprocating engine installed (smaller than the ones installed in the USS New York and USS Texas). The reasoning for going back to a reciprocating engine at that time was due to improved design resulting in better fuel efficiency and reliability. In 1935 (ten years after her retrofit) of the fifteen battleships in the navy’s inventory the USS Texas ranked sixth in fuel efficiency at 5 knots. But at 10 knots she was thirteenth out of fifteen and at 20 knots she was still thirteenth. The USS Oklahoma and the USS Arkansas consumed more fuel.
The Texas had her boilers replaced in a 1925-27 retrofit from a coal burning to the three drum express boilers which burned fuel oil. A 1923 drawing showed turbines to be installed during the retrofit but this did not take place and another drawing showed the installation of a turbo-electric drive, neither of which were installed. The engines of the USS Texas from what I have researched were not modified or updated during her entire career. There were of course many parts replaced or repaired but never upgraded. The engines had 629,000 nautical miles on them from 1913-46.
The drawing of the engine of the USS Texas (above) shows four views of the engine starting with the top view, you are looking down at the top of the engine. The engine is referred to as “Triple expansion double action reciprocating steam engine”. There are three different sizes of pistons in four cylinders. The steam first enters the 39-inch diameter High Pressure cylinder. From there it travels to the Intermediate Pressure cylinder which is 63- inch in diameter, and then last it is split in two for the forward and aft cylinder which are the largest cylinders, these are the Low Pressure 83- inch in diameter. The term “double action” is due to the fact that the pistons are pushed down by steam pressure and then are pushed up by steam pressure. So for those of you familiar with your car engine they are a four strokes, where this is a one stroke. Each stroke is powered.
The three different piston sizes is designed so that when the engine pistons use the steam pressure (energy) the steam expands in each cylinder, reducing its pressure as volume increases. This develops mechanical power to turn the crankshaft. At each stage its increased volume requires a larger cylinder to contain it. This is achieved by increasing the diameters successively. This prevents the uneven loads on the crankshaft. The steam enters the engine at 295 psi and exits at minus 14 psi, this vacuum helps to purge the engine of any steam.
The engine piston/rods have a throw of 48-inch. In other words the rods that connect the pistons to the crankshaft travel four feet down and up to make one rotation of the crankshaft. To obtain the ship’s maximum speed of 21 knots the ship’s engine needs to put out 129 rotations per minute.
Yes, two revolutions per second. That would be an impressive sight to see. There are no reduction gears or transmissions on the Texas. The crankshaft is connected via a thrust bearing directly to the propeller shaft so you have a one for one rotation. The shaft horse power is 28,100 from both engines or 14,050 from each.
When the engines are cold it would take 1.5 to 2 hours to warm the engine to the point when you could get it underway safely. This info is from the Instructions for Operation and Maintenance of Main Propelling Machinery –Section III—Reciprocating Steam Engines. Dated 1941 United State Navy Department. The reason for this amount of time was to ensure the engine and other systems had warmed up to operating temperatures evenly so as to prevent cracking of the pipes or engine components.
When the steam is exhausted from the low-pressure cylinders at minus 14 psi, the steam is converted to water in the condenser located against the outboard bulkhead of each Engine Room. The converted water is pumped into the main feed tank. From there it is pumped forward to the boilers and the process starts over again to steam.
One last item for thought, to give you an idea what it takes to get this engine underway the following steps are taken from the Navy’s Operations manual previously mentioned dated 1941.
The following are steps taken in preparing reciprocating engines for getting under way:
bullet Inspect engine and auxiliaries for security of holding down bolts, tie rod nuts, keepers, set screws, split pins, and oiling gear, etc.
bullet Remove bearing gaskets and temporary covers. Clean piston and valve rods of all oil and dirt.
bullet Jack engine at least one complete turn. (this was done by a 15 horse power electric motor attached to a gear and later removed prior to starting).
bullet Disconnect Jacking gear.
bullet Open main injection and discharge valves.
bullet Start independently driven main circulating and air pumps.
bullet If these auxiliaries are direct connected, start the auxiliary means of circulating water and pumping channel ways.
bullet Crack air cocks on the condenser to insure against its becoming air bound.
bullet When sufficient vacuum is formed, turn auxiliary exhaust not being used elsewhere and drains not needed for feed heating into the main condenser.
bullet Open full and then close main and maneuvering throttles and by-pass valves.
bullet Drain main steam separators.
bullet Open main line stop from upper station.
bullet Open main engine cylinder, valve chest, throttle, and jacket drains.
bullet Start warming up main engine by one of the methods previously described. As the steam pressure rises, manipulate the throttle and by-pass valves so as to prevent too much pressure in the engine.
bullet Open steam and exhaust root valves to reversing engine.
bullet Warm up and drain reversing engine and throw the links over every few minutes.
bullet If so fitted, try out hand-reversing gear.
bullet Turn steam on throttle balance if so fitted.
bullet Put pressure on water service.
bullet See circulating water on water-cooled surfaces such as guides, thrust, and main bearings, and inspect for leaks.
bullet Run links out to maximum cut-off.
bullet Slack stern glands enough to allow a trickle of water to come through.
bullet With gravity lubrication, remove oil cup covers and blow out oil lines with steam or air, fill oil manifolds and inspect the wicks. (the main bearing on the USS Texas engine used a pressurized oil lubrication system).
bullet With forced lubrication system, test out the system by starting lubricating and cooling pumps and inspect to see that there are no leaks or closed valves and that all the bearings are getting oil at the proper pressure. Shift and clean the basket strainers several times before getting underway.
bullet See that the splash casing and oil deflectors are in place and secured.
bullet Assemble hand oiling gear, including rod swabs.
bullet Assemble emergency tools and wrenches.
bullet See that all tools and loose gear are secure for sea.
bullet Close by-pass valves.
bullet Rock engines, with the links and throttle to work out water.
bullet About 15 minutes before the time set for getting underway get permission from the engineer officer of the deck to try the engines.
bullet With gravity lubrication, hand oil all around.
bullet Try engines, making not more than two turns each way before reversing so as to get no way on the ship. While turning over slowly see that all moving parts operate properly .
bullet Turn steam on gland seals and see that the drains are open.
bullet Build up vacuum, minus 14 psi.
Report ready to get underway………
If you have not come aboard the Battleship Texas located just outside of Houston Texas then you should. These Engines were designated a National Engineering Historical Landmark in 1973.