1 Additional Guidance to Section 2 (Definitions)
of the Introduction
Definitions used in the figure above
MDHT Mean Daily High Temperature
MDAT Mean Daily Average Temperature
MDLT Mean Daily Low Temperature
Guidance instructions for determining MDLT:
1 Determine the daily low temperature for each day for a
10 year period.
2 Determine the average of the values over the 10 year
period for each day.
3 Plot the daily averages over the year.
4 Take the lowest of the averages for the season of
operation.
2 Additional Guidance to Chapter 1
(General)
1 Limitations for operating in ice
1.1 Limitations for operation in ice can be determined
using systems, tools or analysis that evaluate the risks posed by the anticipated
ice conditions to the ship, taking into account factors such as its ice class,
seasonal changing of ice strength, icebreaker support, ice type, thickness and
concentration. The ship's structural capacity to resist ice load and the ship's
planned operations should be considered. The limitations should be incorporated into
an ice operational decision support system.
1.2 Limitations for operating in ice should be
determined using an appropriate methodology, such methodologies exist, have been in
use for a number of years and have been validated with service experience. Existing
methodologies and other systems may be acceptable to the Administration.
1.3 Operation in ice should take into account any
operational limitations of the ship; extended information on the ice operational
methodology contained in the PWOM; the condition of the ship and ship's systems,
historical weather/ice data and weather/ice forecasts for the intended area of
operation, current conditions including visual ice observations, sea state,
visibility and the judgment of qualified personnel.
2 Operational assessment
2.1 This guidance is intended to support
shipowners carrying out, and Administrations reviewing, the assessment required in
part I-A, section 1.5, for operational limitations and procedures for the Polar Ship
Certificate.
2.2 Steps for an operational assessment:
-
.1 identify relevant hazards from section 3
of the Introduction and other hazards based on a review of the intended
operations;
-
.2 develop a modelfootnote to analyse risks considering:
- .1 development of
accident scenarios;
- .2 probability of events
in each accident scenario; and
- .3 consequence of end
states in each scenario;
-
.3 assess risks and determine
acceptability:
- .1 estimate risk levels in
accordance with the selected modelling approach; and
- .2 assess whether risk
levels are acceptable; and
-
.4 in the event that risk levels determined
in steps 1 to 3 are considered to be too high, identify current or
develop new risk control options that aim to achieve one or more of the
following:
- .1 reduce the frequency
of failures through better design, procedures, training, etc.;
- .2 mitigate the effect of
failures in order to prevent accidents;
- .3 limit the
circumstances in which failures may occur; or
- .4 mitigate consequences
of accidents; and
- .5 incorporate risk
control options for design, procedures, training and limitations, as
applicable.
3 Performance standards
A system previously accepted based on manufacturer certifications, classification
society certifications and/or satisfactory service of existing systems may be
acceptable for installation on new and existing ships if no performance or testing
standards are accepted by the Organization.
3 Additional Guidance to Chapter 2 (Polar Water
Operational Manual (Pwom))
3.1 Recommendation on the content of the Polar Water
Operational Manual
The Polar Water Operational Manual (PWOM) is intended to address all aspects of
operations addressed by chapter 2 of part I-A. When appropriate information,
procedures or plans exist elsewhere in a ship's documentation, the PWOM itself does
not need to replicate this material, but may instead cross-reference the relevant
reference document.
A model Table of Contents is found in appendix 2.
The model follows the general structure of chapter 2. Not every section outlined
below will be applicable to every polar ship. Many category C ships that undertake
occasional or limit polar voyages will not need to have procedures for situations
with a very low probability of occurrence. However, it may still be advisable to
retain a common structure for the PWOM as a reminder that if assumptions change then
the contents of the manual may also need to be updated. Noting an aspect as "not
applicable" also indicates to the Administration that this aspect has been
considered and not merely omitted.
3.2 Guidance on navigation with icebreaker
assistance
With respect to navigation with icebreaker assistance, the following
should be considered:
-
.1 while approaching the starting point of
the ice convoy to follow an icebreaker/icebreakers or in the case of
escorting by icebreaker of one ship to the point of meeting with the
icebreaker, ships should establish radio communication on the VHF
channel 16 and act in compliance with the icebreaker's instructions;
-
.2 the icebreaker rendering the icebreaker
assistance of ship ice convoy should command ships in the ice
convoy;
-
.3 position of a ship in the ice convoy
should be determined by the icebreaker rendering the assistance;
-
.4 ship within the ice convoy, in accordance
with the instructions of the icebreaker rendering the assistance, should
establish communication with the icebreaker by VHF channel indicated by
the icebreaker;
-
.5 the ship, while navigating in the ice
convoy, should ensure compliance with the instructions of the
icebreaker;
-
.6 position in the ice convoy, speed and
distance to a ship ahead should be as instructed by the icebreaker;
-
.7 the ship should immediately notify the
icebreaker of any difficulties to maintain the position within the ice
convoy, speed and/or distance to any other ship in the ice convoy;
and
-
.8 the ship should immediately report to the
icebreaker of any damage
3.3 Guidance on the development of contingency
plans
In developing the ship's contingency plans ships should consider damage control
measures arrangements for emergency transfer of liquids and access to tanks and
spaces during salvage operations.
See also additional guidance to chapter 9.
4 Additional Guidance to Chapter 3 (Ship
Structure)
Method for determining equivalent ice class
1 The guidance presented below is intended
to assist in determining equivalency with standards acceptable to the Organization,
as referenced in chapters 3 and 6 of the Code. The methodology is consistent with
guidance developed by the Organizationfootnote while allowing for the use of a simplified
approach.
2 The basic approach for considering
equivalency for categories A and B ships can be the same for both new and existing
ships. It involves comparing other ice classes to the IACS Polar Classes. For ice
classes under category C, additional information on comparisons of strengthening
levels is available for the guidance of owners and Administrations.footnote The responsibility for generating the equivalency
request and supporting information required should rest with the owner/operator.
Review/approval of any equivalency request should be undertaken by the flag State
Administration, or by a recognized organization acting on its behalf under the
provisions of the Code for Recognized Organizations (RO Code). Several
classification societies have developed easy-to-use tools for determination of
compliance with the IACS Polar Class structural requirements, as have some
Administrations and other third parties.
3 The scope of a simplified equivalency assessment
(referring to paragraphs 6.1 to 6.3 below) is expected to be limited to materials
selection, structural strength of the hull and propulsion machinery.
4 If there is not full and direct compliance, then an
equivalent level of risk can be accepted in accordance with guidance provided by the
Organization. An increase in the probability of an event can be balanced by a
reduction in its consequences. Alternatively, a reduction in probability could
potentially allow acceptance of more serious consequences. Using a hull area
example, a local shortfall in strength level or material grade could be accepted if
the internal compartment is a void space, for which local damage will not put the
overall safety of the ship at risk or lead to any release of pollutants.
5 For existing ships, service experience can assist in
risk assessment. As an example, for an existing ship with a record of polar ice
operations a shortfall in the extent of the ice belt (hull areas) may be acceptable
if there is no record of damage to the deficient area; i.e. a ship that would
generally meet PC 5 requirements but in limited areas is only PC 7 could still be
considered as a category A, PC 5 ship. In all such cases, the ship's documentation
should make clear the nature and scope of any deficiencies.
6 The process includes the following stages
of assessment:
-
.1 select the target Polar Class for
equivalency;
-
.2 compare materials used in the design with
minimum requirements under the IACS Polar Class URs; identify any
shortfalls; and
-
.3 compare strength levels of hull and
machinery components design with requirements under the IACS Polar Class
URs; quantify levels of compliance.
7 Where gaps in compliance are identified in
steps 1 to 3, additional steps should be necessary to demonstrate equivalency, as
outlined below:
-
.4 identify any risk mitigation measures
incorporated in the design of the ship (over and above the requirements
of the Code and IACS URs);
-
.5 where applicable, provide documentation
of service experience of existing ships, in conditions relevant to the
target ice class for equivalency; and
-
.6 undertake an assessment, taking into
account information from steps 1 to 5, as applicable, and on the
principles outlined in paragraphs 2 to 6 above.
8 Documentation provided with an application for
equivalency should identify each stage that has been undertaken, and sufficient
supporting information to validate assessments.
9 Where a ship in categories A or B is provided with an
equivalency for ice class by its flag State, this should be noted in its Polar Ship
Certificate.
5 Additional Guidance to Chapter 4 (Subdivision
And Stability)
No additional guidance
6 Additional Guidance to Chapter 5 (Watertight
And Weathertight Integrity)
No additional guidance.
7 Additional Guidance to Chapter 6 (Machinery
Installations)
Refer to additional guidance to chapter 3.
8 Additional Guidance to Chapter 7 (Fire
Safety/Protection)
No additional guidance.
9 Additional Guidance to Chapter 8 (Life-Saving
Appliances And Arrangements)
9.1 Sample personal survival equipment
When considering resources to be included with the personal survival equipment, the
following should be taken into account:
| Suggested Equipment
|
| Protective clothing (hat, gloves,
socks, face and neck protection, etc.)
|
| Skin protection cream
|
| Thermal protective aid
|
| Sunglasses
|
| Whistle
|
| Drinking mug
|
| Penknife
|
| Polar survival guidance
|
| Emergency food
|
| Carrying bag
|
9.2 Sample group survival equipment
When considering resources to be included in the group survival equipment, the
following should be taken into account:
| Suggested Equipment
|
| Shelter – tents or storm shelters or equivalent – sufficient
for maximum number of persons
|
| Thermal protective aids or similar – sufficient for maximum
number of persons
|
| Sleeping bags – sufficient for at least one between two
persons
|
| Foam sleeping mats or similar – sufficient for at least one
between two persons
|
| Shovels – at least 2
|
| Sanitation (e.g. toilet paper)
|
| Stove and fuel – sufficient for maximum number of persons
ashore and maximum anticipated time of rescue
|
| Emergency food – sufficient for maximum number of persons
ashore and maximum anticipated time of rescue
|
| Flashlights – one per shelter
|
| Waterproof and windproof matches – two boxes per
shelter
|
| Whistle
|
| Signal mirror
|
| Water containers & water purification tablets
|
| Spare set of personal survival equipment
|
| Group survival equipment container (waterproof and
floatable)
|
10 Additional Guidance to Chapter 9 (Safety Of
Navigation)
10.1 Radars equipped with enhanced ice detection
capability should be promoted used, in particular, in shallow waters.
10.2 As the chart coverage of polar waters
in many areas may not currently be adequate for coastal navigation, navigational
officers should:
-
.1 exercise care to plan and monitor their
voyage accordingly, taking due account of the information and guidance
in the appropriate nautical publications;
-
.2 be familiar with the status of
hydrographic surveys and the availability and quality of chart
information for the areas in which they intend to operate;
-
.3 be aware of potential chart datum
discrepancies with GNSS positioning; and
-
.4 aim to plan their route through charted
areas and well clear of known shoal depths, following established routes
whenever possible.
10.3 Any deviations from the planned route
should be undertaken with particular caution. For example, and when operating on the
continental shelf:
-
.1 the echo-sounder should be working and
monitored to detect any sign of unexpected depth variation, especially
when the chart is not based on a full search of the sea floor; and
-
.2 independent cross-checking of positioning
information (e.g. visual and radar fixing and GNSS) should be undertaken
at every opportunity. Mariners should ensure to report to the relevant
charting authority (Hydrographic Office) any information that might
contribute to improving the nautical charts and publications.
10.4 Ships should be fitted with:
-
.1 a suitable means to de-ice sufficient
conning position windows to provide unimpaired forward and astern vision
from conning positions; and
-
.2 an efficient means of clearing melted
ice, freezing rain, snow, mist and spray from outside and accumulated
condensation from inside. A mechanical means to clear moisture from the
outside face of a window should have operating mechanisms protected from
freezing or the accumulation of ice that would impair effective
operation.
11 Additional Guidance to Chapter 10
(Communication)
11.1
Limitations of communication systems in high latitude
11.1.1 Current maritime digital communication systems
were not designed to cover polar waters.
11.1.2 VHF is still largely used for communication at
sea, but only over short distances (line of sight) and normally only for voice
communication. HF and MF are also used for emergency situations. Digital VHF, mobile
phone systems and other types of wireless technology offer enough digital capacity
for many maritime applications, but only to ships within sight of shore-based
stations, and are, therefore, not generally available in polar waters. AIS could
also be used for low data-rate communication, but there are very few base stations,
and the satellite-based AIS system is designed for data reception only.
11.1.3 The theoretical limit of coverage for GEO systems
is 81.3° north or south, but instability and signal dropouts can occur at latitudes
as low as 70° north or south under certain conditions. Many factors influence the
quality of service offered by GEO systems, and they have different effects depending
on the system design.
11.1.4 Non-GMDSS systems may be available and may be
effective for communication in polar waters.
11.2 Advice for the operation of multiple alerting
and communication devices in the event of an incident
A procedure should be developed to ensure that when survival craft are
in close proximity, not more than two alerting or locating devices are activated (as
required by regulation 10.3.2) at the same time. This is to:
-
.1 preserve battery life;
-
.2 enable extended periods of time for the
transmission of alerting or locating signals; and
-
.3 avoid potential interference.
11.3 For satellite distress beacons, although multiple beacon
transmissions can be detected successfully by the satellite system, it is not
recommended to activate multiple beacons, unless the survival craft operating the
beacons are widely dispersed, as this can cause interference on direction-finding
equipment.
11.4
Advice on location and communication equipment to be carried by rescue boats and
survival craft
In determining the equipment to be carried for transmitting signals for location, the
capabilities of the search and rescue resources likely to respond should be borne in
mind. Responding ships and aircraft may not be able to home to 406/121.5 MHz, in
which case other locating devices (e.g. AIS-SART) should be considered.
12 Additional Guidance to Chapter 11 (Voyage
Planning)
In developing and executing a voyage plan ships should consider the
following:
-
.1 in the event that marine mammals are
encountered, any existing best practices should be considered to
minimize unnecessary disturbance; and
-
.2 planning to minimize the impact of the
ship's voyage where ships are trafficking near areas of cultural
heritage and cultural significance.
See also additional guidance to chapter 9.
13 Additional Guidance to Chapter 12 (Manning And
Training)
No additional guidance