The Design Of Modern Ship Masts

Masts have had an evolving meaning in the context of ships. Earlier, during the olden-day sail ships were characterised by large flapping sails, which served as modes of propulsion with the wind as power. These were supported by wooden supports known as masts. These were as high as the sails and sturdily built to support both wind loads and motions from the ships and rough weather conditions.

Slowly, these sail ships went from seas to the pages of history, and masts started to have a different meaning altogether. Thanks to the advent of technology and communications, these masts now have a different kind of importance in almost all modern sea-going vessels.

Ship Masts

These masts now serve various kinds of purposes:

Acting as stands for light signals and beacons, also sound signals like horns.
As radio transmission and telecommunication systems for capturing radio signals and acting as the communication tower for the vessels
They are intrinsic parts of the navigation unit where the radar gives the exact real-time position of the vessel and geographical coordinates of nearby landmasses or traffic across hundreds of nautical miles range.
They also help in defence ultra-modern detection and search purposes for defence vessels.

Ship mast

The masts have evolved from simple mechanical supports to complicated electrical, electronic, and communication units for the safety and navigation of vessels during their voyage.

The detailed description of a modern-day ship mast is beyond the scope of this article, but the crux of design and the basic components can be briefly explained.

The mast broadly consists of the following components:

The truss structure: It is the main steel structure on which all forms of equipment are housed. They are larger and heavier in defence vessels. They usually have a central structure which is tubular, cylindrical or tapering in shape depending on the size and complexity. They are mounted and attached to the topmost deck of the vessel above the superstructure/deckhouse, like the bridge deck or the wheelhouse top. They house the main powering and transmission lines as well. From the main steel structure, secondary branchlike structures emanate. Depending on the system’s complexity, one or multiple levels of such branches can exist. The antennas, lights and sound systems are often mounted on these branches.

Main Mast

The antenna: The antenna is the most crucial part of any radio transmission system, which on the one hand, sends out electrical signals or waves from the location as well as receives signals coming from external sources. For all practical purposes, this antenna is usually situated on these outward branches of the truss structure.
Radar: After the age of compasses, radars are now the primary sources of navigation for any sea-going vessel. The radar electronically transmits the signals to the navigation bridge regarding the location of the vessel. The radar system is usually located at the highest point on the vessel. Superior forms of radars, like Very-high frequency or VHF, are employed on military vessels that have very high detection capabilities. In most modern ships, the radars are either X-band or S-band frequency radars. From a technical point of view, the radar system is electronically integrated with the ship’s navigation and detection system composed of radios, charts, sonars and other specialised underwater systems, emergency systems like SART, satellite communications, and GPS units.

Fwd Mast

Cables and power lines: The interior of the mast is a complicated network of cables and power lines that supply power to the various systems on it as well as transmit electronic signals to and fro. Most of these lines are connected to the navigation bridge.

While we have briefly discussed the parts of the rudder, let us now look at the main aspects of its design from a structural point of view.

The philosophy of design encompassing a radar system usually takes the following aspects into consideration:

Strength and durability: As it is always exposed and is subject to various weather phenomena as well as ship-induced motions, it has to be structurally sound. High grades of steel are usually used to build the truss structure. Aluminium and high-grade composites are also used in many designs. A finite element analysis is mostly carried out for the structure prior to fabrication and installation aboard.
Vibration: This is also a very important aspect as the structural frequency to the expected loads and electrical frequency due to high voltage supplies need to be assessed against the natural frequencies of the ship structure to avoid resonance. Vortex-induced vibration is also taken into consideration these days as well.
Fatigue: As the mast structure is expected to be throughout the service life of the vessel, the fatigue strength is also another critical aspect and needs to be checked for the ‘life’ in terms of fatigue against the oncoming loads.
Attachments and connections: This is a highly important part of the design process as the overall structure is heavy, houses many systems and equipment, and is attached or instead welded directly to the deck. So, the connections are checked at every point of attachment, ensuring that it can sustain all types of worst-case loads without faltering at the ends.
Checking for localised hotspot stresses at joints, welded points, and intersections
Corrosive effects due to continuous exposure to external weather.

Radars also have high-grade insulation systems to protect against lightning strikes, which are very common in vast stretches of the open sea, especially during inclement weather. These insulation systems take care of all the critical systems enclosed within the radar mast and are connected to the vessel’s grounding system.

The electrical wiring and cables are also suitably designed and adequately insulated to prevent burnouts and short circuits that may lead to massive onboard fires, especially during rainy seasons.

The radars are usually fitted on ships after the entire construction, and most electrical installations are completed. From a design point of view, radars comprise outfitting items. Most of the equipment/systems/devices present in the mast are classified for reliability under the COLREG or LSS (light sound and signal) guidelines mandated by classification societies and IMO.

You might also like to read-

Do you have info to share with us ? Suggest a correction

About Author

Subhodeep is a Naval Architecture and Ocean Engineering graduate. Interested in the intricacies of marine structures and goal-based design aspects, he is dedicated to sharing and propagation of common technical knowledge within this sector, which, at this very moment, requires a turnabout to flourish back to its old glory.