It is important to regulate noise levels on ships. The goal of the International Maritime Organization (IMO) noise level code on board ships, which became mandatory for new ships in July 2014, is to protect mariners against hearing loss, improve comfort levels and make aware the need to communicate with colleagues and hear alarms. The level and duration of noise and the length of sailing time have a significant influence and are taken into account when calculating the noise limits according to the regulations. The IMO code recognizes the need to establish different noise level limits for machinery spaces, control rooms, workshops, and accommodation areas on ships; you don’t want sailors to have to wear hearing protection while sitting in a dining room, recreation room or sleeping compartment.
Mariners are affected by a variety of mechanical, aerodynamic and hydro-acoustic noise. The main sources of ship noise are the main propulsion engines and the generators. In addition, auxiliary engines, pumps, turbochargers, compressors, fans, piping, and heating and air conditioning systems all generate noise, as do propellers, thrusters and exhaust systems.
Professor Shuri, who currently works at Tokai University in Japan, has more than 34 years of experience working for two shipbuilding companies: Hitachi Zosen Corporation and the Universal Shipbuilding Corporation. His roles have included senior researcher and laboratory chief, developing noise prediction programmes for ships and offshore structures, and studying noise control technologies.
It is difficult to limit ship noise because the vibration from the sources propagate through the steel structure, which has very little damping and, for example, the structure near residential cabins can radiate sound.
The IMO noise level code for ships includes:
All shipowners have to meet the new noise regulations for new ships with a gross tonnage of 1,600 and over. If the noise level exceeds the regulations, shipbuilders can’t deliver the ships. Usually the noise level limits of cabins and working spaces are described in the ship construction contract between shipbuilders and owners.
To comply with the noise level limits, shipbuilders:
Finally, shipbuilders and shipowners confirm that the measurements satisfy the noise level limits. The noise limits are designed so that within each day or 24-hour period the equivalent continuous noise exposure for a seafarer does not exceed 80 dB.
To understand the current situation, the noise levels of 39 existing ships (mostly bulk carriers and oil tankers) were measured during sea trials. For ships of 150,000 GT, the average noise level in cabins or hospitals was around 55 dB and for ships of 5,000 GT, the average noise level was greater than 65 dB. These results indicate that noise levels in cabins are generally greater for smaller ships and that it is necessary to reduce the noise levels more than 5 dB in order to satisfy the noise level limits of the IMO noise code.
Daily noise exposure level (Lex,24h) represents the equivalent noise exposure level for a period of 24 hours.
The vibration acceleration levels of a ship’s structure (lower picture) and the noise levels in cabins (upper pixture), calculated by a noise prediction programme.
The IMO noise level code stipulates how to measure noise levels on ships, detailing the requirements for measuring equipment, operational conditions during sea trials, and the measurement procedures.
“The Brüel & Kjær 2250 is popular among ship manufacturers as it measures both noise and vibration acceleration levels and this is very useful in order to investigate noise control measures,” explains Professor Shuri. “The 2250 can also carry out transmission loss measurements of a cabin construction and provide the absorption coefficient measurements in a cabin, which are necessary measurements when investigating noise control.”
Two projects for Japanese shipbuildersRecently, Professor Shuri and Brüel & Kjær have been working together on two projects for the cooperative association of Japanese shipbuilders. The first project started in April 2011 and will finish in April 2016. “The aim of this project is to develop noise prediction programmes for shipbuilding engineers,” explains Professor Shuri. “Our second project, which started in March 2015 and will also finish in April 2016, is about developing noise control technology to effectively reduce noise levels in cabins.”
Noise levels (DB) for ships of 1,600 GT and over
Designing to reduce noise
Shipbuilders are gradually improving ship designs to reduce noise. For example, adding damping materials to steel structures and employing floating floors and high-performance insulation walls to help reduce noise levels in cabins. Advances in engine-mounting systems have also lowered noise and kept it from travelling through a ship’s hull. Sound insulation is also used more effectively in ship machine spaces than in the past, to reduce the airborne sound from machines.
Engineers working for shipbuilders are increasingly using noise prediction programmes to improve ship designs, predicting cabin noise levels early in the design process. And they are also developing noise control measures in cooperation with material manufacturers to effectively reduce noise levels in cabins.
“To effectively reduce noise, engineers need precise noise predictions, which can be made early in the design process, along with the proper implementation of noise control measures and the accurate measurement of noise and vibration,” says Professor Shuri. “There is a need to continuously improve noise control materials, and develop new technologies in cooperation with engineers, according to the requirements of shipbuilders.”
Stricter regulations to come
These projects are still ongoing but it is clear that precise noise and vibration measurements, involving both the right equipment and the right methods, are essential for the shipbuilding industry. Brüel & Kjær continue to help shipbuilders achieve greater accuracy, to better meet the noise regulations. “I believe that the requirements for reducing noise levels will increase and noise level limits will become even stricter in the future,” says Professor Shuri.
Looking to the future, Professor Shuri believes that noise source identification technology is one of the most effective methods to reduce noise on ships: “To provide an effective method for engineers, I hope to develop practical usage rules for noise source identification in ship cabins during sea trials, in cooperation with engineers from Brüel & Kjær Japan,” concludes Professor Shuri.
Professor Hideyuki Shuri
Professor Hideyuki Shuri’s work includes developing noise prediction programmes for ships:
April 1974 to August 2002: Worked for the Hitachi Zosen Corporation
September 2002 to March 2008: Worked for the Universal Shipbuilding Corporation
April 2008 – present: Professor at the Department of Navigation and Ocean Engineering, School of Marine Science and Technology, Tokai University, Japan.