Wärtsilä Vasa is an engine series built by Finnish diesel engine manufacturer Wärtsilä. It was released in 1977 and remained in production until 2010. These medium speed diesels were produced in and named after Vasa, Finland. The lead designer of the first engine was Wilmer Wahlstedt.[1] The series comprises three models, the Vasa 22, 32, and 46, with the number denoting the bore size of the engine.[1]
Wärtsilä discontinued production of the series in 2010 to focus on newer technology. The Vasa series acted as a precursor to the newer 32 D and E series which have a higher power output.
Models
Vasa 14
W16
Wartsila Vasa 20
Wärtsilä Vasa 22
Vasa 24
Wartsila Vasa 26
Wärtsilä Vasa 32
Wärtsilä Vasa 46
Technical data
The engines were designed for both shipboard and power plant applications. The engine could be ordered with a 220, 320, and 460 mm bore in both V and inline configurations. The inline style was available with up to 9 cylinders and V could support up to 18. The VASA32LN engine was redesigned with a longer stroke to increase horsepower.
Vasa engines are turbocharged, non-reversible, and utilize a direct fuel injection system. They were designed to continuously run on heavy fuel oil (HFO), provided that the fuel is pre-heated and at the correct viscosity at the time of injection.[1]
Model
375 kW/cyl
bhp
410 kW/cyl
bhp
4R32LN
1500
2040
1640
2230
6R32LN
2250
3060
2460
3340
8R32LN
3000
4080
3280
4460
9R32LN
3375
4590
3690
5020
12V32LN
4500
6120
4920
6690
16V32LN
6000
8160
6560
8920
18V32LN
6750
9170
7380
10030
This is the power rating table generated for the Vasa 32LN engine. Engine power ratings are determined by how the engine is being used. The Vasa engines offer 375 kW/cyl and 410 kW/cyl. As the number of cylinders increase, the power increases. The size of the engine depends on the application it is being used for.[1]
Lubrication
Vasa engines utilize a circulating oil system for lubrication, complete with a main, pre-lubricating pump, and an oil cooler. Smaller Vasa engines use gear type pumps for lubrication where the larger engines use wheel type pumps.[3]
Starting mechanism
Air is utilized to start the engines.[4] Each cylinder head is equipped with a start air valve that delivers high-pressure air to the cylinder upon startup. This provides the engine the initial rotation force needed to achieve combustion.
Fresh water cooling
Treated fresh water is used for cooling of the cylinder, charge air, turbocharger, and oil. Freshwater cooling is divided into two systems the HT (High Temperature) cooling the cylinders and turbocharger and the LT (Low Temperature) cooling the oil and charge air. The freshwater temperature is closely regulated with a thermostatic valve to achieve optimum efficiency. At low engine loads, the charge can be too cold, which can cause incomplete combustion. To counteract this heat rejected to the lubrication oil can be used to heat the freshwater, which in turn heats the charge air enough to ensure complete combustion.[4][clarification needed]
Control systems
Vasa engines can start remotely away from the engine or manually by manipulating the valves on the start air system. Upon startup engine speed is controlled by a governor, which mechanically adjusts fuel delivery to match the load demanded of the engine.[4]
Conditions are also in place to protect the engine. During operation, an engine will automatically cease injection if all preset conditions are not met.[3]
Applications
These engines are primarily used for power generation and diesel-electric propulsion plants. Since they are non-reversible, they are not widely used as propulsion engines. The engines were used to provide electrical power for both propulsion and auxiliary services. Due to their ability to run on heavy fuel oil (HFO) or MDO (Marine Diesel Oil), many ships were equipped with the Vasa series engines.
In the power generation industry, these engines are used as auxiliary generators or as backup power generators.[5]
^ abKapulainen, M., Ronkainen, H., Hokkanen, A., Stuns, I., Varjus, S., Nyyssönen, S., . . . Halme, J. (2014). Fibre Optic Sensors for Long-Term Monitoring of Oil Film Pressure in Diesel Engine Main Bearing. Tribology Letters, 56(1), 47-54.