Coal deliveries Coal was originally supplied to the station directly from the
deep mines of the neighbouring
Midlothian Coalfield, but these have since been exhausted or closed. Subsequently coal was supplied from
open cast mines in the Lothians,
Fife,
Ayrshire and
Lanarkshire. Russian coal was used latterly as it has a low sulfur content which helped reduce sulfur oxide (SOx) emissions to the atmosphere. The power station was the first to use the "merry-go-round" system of coal deliveries by
rail. This system uses hopper wagons which carry around 914 tonnes of coal per train. Coal was also delivered by lorries.
Coal handling plant Coal was delivered to the station's coal plant, which has the capacity to hold up to 900,000 tonnes of coal on a storage bing. The coal plant and storage bing were situated on the opposite side of B1348 road between
Prestonpans and
Cockenzie and Port Seton, and the main station. The coal, known as 'raw coal' at this stage was weighed, sampled and screened for metal and stones before being transported to the main station and stored in bunkers. Coal was transported from the coal plant to storage bunkers in the main station by a
conveyor belt.
Milling plant There were six
pulverising mills per unit which ground down the raw coal until it had the consistency of sand. The ground coal is called 'pulverised fuel' (PF). PF burns more efficiently than large lumps of coal, which reduces waste. The PF was then blown into the furnace along with preheated air by six large
mechanical fans called Primary Air (PA) Fans. At full load each unit burned around 100 tonnes of coal per hour.
Draught plant Each unit had two large Forced Draft (FD) Fans. For efficiency these fans drew warm air from an intake at the top of the station. This combustion air was passed through the Air Heater which increased its temperature. Dampers were used to control the quantity of air admitted to the furnace and direct some of the air to the Primary Air (PA) Fans. There were also two large Induced Draft (ID) Fans on each unit. These drew the hot gases from the Boiler, through the Air Heater where the heat is transferred to the incoming combustion air. The gases were then exhausted up the chimney. The exhaust flow of these fans was also controlled by dampers in the ducting. Working in tandem the Draught plant ensured the boiler was always under a slight vacuum. This created a draw of combustion air into the boiler and an exhaust to the chimney. The exhaust gases could not be allowed to cool below a certain temperature, as there was a risk of the sulfur and nitrogen oxides in the flue gases condensing and forming acids which could have damaged the ID Fans.
Water use The water used in the station's boilers was taken from the local water supply, known as 'towns water'. This is the same as the
drinking water used to supply households. This water was used as it had already been screened and purified by
Scottish Water.
Demineralisation plant The station's water treatment plant further demineralised the town’s water and removed any impurities. Although safe to drink water still contains dissolved
silica (sand) and salt. Silica particles leave
scale deposits on the boiler pipes which acts as an insulator, reducing heat transfer from the furnace to the water inside. This reduces the efficiency of the station and leads to increased running costs. Salt encourages
rust which weakens the walls of the boiler pipes and can cause them to fracture and burst, known as a boiler tube leak. A serious tube leak can lead to reduced generation or loss of the unit until repairs are carried out.
Hydrazine was added and used as a reducing agent to remove excess oxygen from the water. Free oxygen atoms in the water also encourage rust to form inside the boiler pipes.
Sodium hydroxide was also added to 'scour' the inside of the boiler tubes and remove any silica particles. The demineralised water was then stored in large tanks inside the main station, ready to be used in the boilers.
Feedheating plant Before the
feedwater was introduced to the boiler it was heated up in stages. There were seven
feedwater heaters on each unit which gradually increased the pressure and temperature of the water, until it reached a final feed temperature of around 210 °C. A steam driven
Main Boiler Feed Pump (MBFP) pumped the water through the boiler
Economiser and into the boiler Drum.
Boiler The boilers were conventional
water-tube boilers. The Boiler Drum was a high tensile steel pressure vessel where water and steam were separated. The water here was pressurised to 170 bar and heated further to 360 °C. On the bottom of each Drum were six large bore pipes known as Downcomers. These directed the water into the boiler water pipes where it was heated by the furnace. The water was then directed back into the Drum where it flashed off into
saturated steam. The steam was then further heated by passing through Primary and Secondary Superheaters until it reached 565 °C. The
superheated steam was then piped to the high-pressure turbine, back to the boiler for reheat, and then back to the intermediate and low-pressure turbines in series.
Turbine There was one turbine and one alternator per unit. Each turbine had a High Pressure (HP) stage, an Intermediate Pressure (IP) stage and two Low Pressure (LP) stages all connected in tandem to the same shaft. The superheated steam entered the HP turbine at a temperature of 566 °C and a pressure of 162 bar. The exhaust steam from the HP turbine travelled back through the boiler Reheater and entered the IP turbine at the same temperature but at a lower pressure of 43.5 bar. The exhaust steam from the IP turbine then entered the LP turbines. The steam was used to drive the turbines, causing the shaft to rotate at 3,000 rpm. This speed drove the
alternator and gave a
frequency of 50 cycles per second (Hz) and allowed connection to the
National Grid. Electricity was generated at 17
kilovolts (kV).
Condenser After use, the steam was condensed back into water, by passing it through the
condenser.
Seawater from the Firth of Forth was used as a cooling medium. Over 500,000 litres per minute of water were used for cooling. The seawater was then discharged back into the Firth of Forth. Controls ensured the discharged seawater was kept close to the temperature of the sea, to avoid creating a 'tropical' environment and upsetting the local ecosystem.
Ash removal and use The burning of coal in power stations generates ash and dust. The station's
electrostatic precipitators captured
fly ash from the flue gases, preventing it from entering the atmosphere.
Bottom ash was also produced by the station. Ash from the station was sold through the ScotAsh company, a joint venture between Scottish Power and
Blue Circle. It was used in the construction industry and in products such as
grout and
cement. Any remaining ash was piped to the large lagoons in the nearby town of
Musselburgh, where it was capped and planted, and used as a
nature reserve.
Electricity distribution The electricity was initially generated at 17 kV. This was stepped up via a transformer to 275 kV for distribution on the
National Grid. The electricity was distributed to Scotland, and England too, which it is connected to via a double circuit overhead line, operating at 275 kV and 400 kV, to
Stella near
Newcastle upon Tyne. ==Post-privatisation and future==