also be due to the geographical location of shore-based,
ammunition-handling facilities. For example, an
aircraft carrier may be docked in Norfolk, Virginia, and
the activity receiving or issuing the ammunition maybe
located in Charleston, South Carolina. In this situation,
the most practical method would be to locate the aircraft
carrier at a designated explosive anchorage (commonly
called whiskey anchorage) and transport the ordnance
by lighters and/or barges. The transfer of ammunition
between the ship and the lighters/barges is normally
accomplished by the use of a floating crane.
Even though a ship is located at an explosive
anchorage, transferring ammunition is restricted to
daylight hours. Normally, the ship remains at anchorage
until the entire evolution is completed, which may vary
from 1 to 5 days.
TRANSFER OF AMMUNITION AT SEA.— The
transfer of ammunition at sea (underway) presents
problems not met by pier-side or anchorage operations.
Normally, replenishment at sea involves the transfer of
fuel, supplies, stores, and ammunition simultaneously.
Obviously, available deck space, available handling
equipment, and manpower are used to the maximum
efficiency. Every detail of the entire operation is
preplanned and coordinated between the departments
involved within the ship and the individuals within the
departments.
The transfer of ammunition at sea is accomplished
by conventional replenishment (CONREP) and/or
vertical replenishment (VERTREP) methods. The
CONREP method consists basically of a steel cable
rigged between the supply ship and the receiving ship at
the hangar-decklevel. These points of contact are called
“conning stations,” and there may be more than one
conning station in operation at the same time. Cargo is
attached to the cable by using approved handling
equipment and conveyed from one ship to the other. The
AO is only responsible for ammunition items. You
position each ammunition load at the conning station for
transfer. As the ammunition loads are received at the
conning station, you move the load to a designated
staging area until it is struck below. The operation of
conning equipment is normally performed by the ship’s
deck department.
In the VERTREP method, helicopters using slings
and/or cargo nets transfer the ammunition to or from the
supply ship. VERTREP operations are conducted on the
flight deck. Aviation ordnancemen are responsible for
handling all ammunition and preparing and positioning
empty slings and ammunition details for transfer to the
supply ship. Ammunition is transferred from the flight
deck to the hangar deck by a designated aircraft elevator.
This elevator is normally on the port side when
CONREP and VERTREP operations are being
conducted simultaneously.
Q1.
Q2.
Q3.
Q4.
REVIEW NUMBER 4
The weapons staging area on the flight deck,
located between the island and the starboard
catwalks, is known as the
.
Under what conditions is a pier-side weapons
movement of ammunition loaded onto an
aircraft carrier?
List the methods used to transfer ammunition at
sea.
When VERTREP is being used to transfer
ammunition between ships, transfer is
accomplished by
.
HAZARDS OF ELECTROMAGNETIC
RADIATION TO ORDNANCE
(HERO)
LEARNING OBJECTIVE: Recognize HERO
classification standards. Identify HERO
hazards. Identify the uses of the emission
control (EMCON) bill.
The functional characteristics of electrically
initiated ordnance cause hazards of electromagnetic
radiation to ordnance (HERO). Ordnance that presents
a HERO problem include cartridges, cartridge-actuated
devices, and 20-mm ammunition. The ordnance
electroexplosive devices (EEDs) may be accidentally
initiated or their performance degraded by exposure to
radio frequency (RF) environments. Ordnance is more
susceptible to RF environments during assembly,
disassembly, handling, loading, and unloading
operations.
The term RADHAZ (radiation hazards) applies to
radio frequency (RF) electromagnetic fields of
sufficient intensity to
produce harmful biological effects in humans,
and/or
cause spark ignition of volatile combustibles or
actuate electroexplosive devices.
Although the effects of RADHAZ are important, this
chapter limits discussion to HERO hazards.
11-31
