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PERSONAL SAFETY CONSIDERATIONS WITH BROADCAST TRANSMITTERS
INTRODUCTION
Most people are concerned with safety one way or another in our
daily lives and are generally safety conscious. This is particularly
true in the broadcast industry. Yet sometimes safety is taken for
granted. The question of safety gets little or no attention until the
occurrence of a major safety related accident. Much of the responsibil-
ity related to safety rests in the hands of broadcast station engineers.
Personal safety must be a very important consideration in the de-
sign, operation, and maintenance of broadcast transmitter equipment
containing high voltages, currents and large amounts of energy storage.
The equipment should incorporate adequate safety protection against ac-
cidental direct exposure to dangerous potentials. More importantly,
the broadcast engineering staff should be aware of the possible hazards
and follow good electrical safety practices. This is especially impor-
tant in today's highly competitive radio station environment where tech-
nical expertise is depleting at an alarming rate. This paper discusses
the various hazards which may be encountered, the safety requirements
for transmitting equipment including standards and the protective cir-
cuits, devices, and methods used in a typical broadcast transmitter to
achieve the desired safety level.
SAFETY HAZARDS
The safety hazards which are of primary concern to broadcast staff
are described below.
Electrical Shock
Current rather than voltage is the most important parameter which
affects the intensity of electric shock. Three factors that determine
the severity of electric shock are: (1) amount of current flowing
through the body; (2) path of current through the body; and (3) duration
of time the current flows through the body.
The voltage necessary to produce a current dangerous to life is depend-
ent upon the resistance of the body, contact conditions, and the path
through the body [1]. The resistance of the human body varies with the
amount of moisture on the skin, the muscular structure of the body and
the voltage to which it is subjected.
Studies of adult human body resistance have indicated that under
normal dry skin conditions hand-to-hand resistance varied typically from
6,600 ohms to 18,000 ohms and hands-to-feet resistance varied from 1,550
ohms to 13,500 ohms [2]. The body resistances of children were found to
be generally higher. Higher voltages have the capability to breakdown
the outer layers of the skin thereby reducing the resistance. In judg-
ing a product for safety against electric shock, Underwriters Labora-
tories (UL) uses a resistance value of 1,500 ohms under normal dry con-
tact conditions and a resistance value of 500 ohms under wet conditions
[2,3]. Based on research of Charles F. Dalziel, Professor Emeritus,
University of California, Berkeley, the effects of 60 Hz AC (alternating
current) on the human body, are illustrated in Table 1 [4]. The safe
"let-go" currents generally accepted for 0.5 percent of population are
approximately 9 and 6 mA for men and women respectively [5]. The "let-go"
current is the maximum current at which a person is still capable of re-
leasing a live conductor by using muscles directly stimulated by that
current. Currents only slightly in excess of one's let-go current are
said to "freeze" the victim to the circuit. The maximum safe current
specified by the International Electrotechnical Commission (IEC) is 2 mA
DC (direct current) and 0.7 mA peak AC measured in a non-inductive re-
sistor of 2,000 ohms connected between the part containing voltage in
excess of 72 volts peak and ground [6].
Sufficient current passing through any part of the body will cause
severe burns and hemorrhages. However, relatively small current can be
lethal if the path includes a vital part of the body such as the heart
or the lungs. The duration of current flow also affects the severity of
injury. The effects of electrical current and time duration on the
human body is illustrated in Figure 1 [4]. The current range previously
noted in Table 1 which causes "freezing" to the circuit is also illus-
trated. It is obvious from Figure 1 that a 100 mA current flowing for 2
seconds through a human adult body will cause death by electrocution.
Considering a minimum value of hands-to-feet resistance of 1,500 ohms, a
current of 80 mA can flow if both hands are in contact with a 120V AC
source and both feet are grounded. If this condition persists for more
than 2 seconds, it may cause electrocution. The above data provides in-
sight into the hazards of electrical shock.
TABLE 1. THE EFFECTS OF 60 Hz ALTERNATING CURRENT ON THE HUMAN BODY
--------------------------------------------------------------------
1 milliamp or less - No sensation, not felt.
More than 3 mA - Painful shock.
More than 10 mA - Local muscle contractions, sufficient to cause "freezing"
to the circuit for 2.5 percent of the population.
More than 15 mA - Local muscle contractions, sufficient to cause "freezing"
to the circuit for 50 percent of the population.
More than 30 mA - Breathing difficult, can cause unconsciousness.
50 to 100 mA - Possible ventricular fibrillation* of the heart.
100 to 200 mA - Certain ventricular fibrillation* of the heart.
Over 200 mA - Severe burns and muscular contractions; heart more apt to
stop than fibrillate.
Over a few amperes - Irreparable damage to body tissues.
*NOTE:
Ventricular fibrillation is defined as "very rapid uncoordinated
contractions of the ventricles of the heart resulting in loss of
synchronization between heartbeat and pulse beat". Once ventricular
fibrillation occurs, it will continue and death will ensue within a few
minutes. Resuscitation techniques, if applied immediately, may save
the victim.
Electrical and Radio Frequency Burns
Electrical burns are usually of two types, those produced by heat
of the arc which occurs when the body touches a high voltage circuit,
and those caused by passage of high current through the skin and tissue.
In the latter case even the low voltage source(s) containing large
amounts of energy can cause severe arcing or overheating if accidentally
short-circuited with the possibility of injury to personnel and the risk
of fire.
TABLE 1. THE EFFECTS OF 60 Hz ALTERNATING CURRENT ON THE HUMAN BODY
FIGURE 1. THE EFFECTS OF ELECTRICAL CURRENT AND TIME ON THE HUMAN BODY
This can occur when a metal part in contact with the skin such as jewelry
or tool provides path for high short-circuit currents.
Radio Frequency (RF) burns are caused by the flow of RF currents
through the skin when it is exposed to an RF energy source. The energy
is absorbed by the resistance of the skin. The severity of burns will
depend on the area of exposed surface, the amount of current flow, the
voltage level, the frequency and the time duration.
Harmful Radiation
The two types of harmful radiation which may be encountered in and
near the transmitting equipment are: (1) Non-ionizing Radiation and (2)
Ionizing Radiation.
Non-ionizing radiation may exist due to poor shielding of the trans-
mitter equipment operating at high power levels or due to the proximity
of antenna. Exposure to excessive non-ionizing radiation of radio fre-
quency electromagnetic fields in the frequency range from 300 kHz to 100
GHz will cause heating of the body which in turn may have adverse bio-
logical effects. Studies have shown that whole-body-averaged absorption
rates approach maximum values when the long axis of a body is parallel
to the E-field vector and is four tenths of a wavelength of the incident
field. At a frequency near whole-body resonance, which is about 70 MHz
for the Standard Man, the absorption of RF energy is maximum [7]. Under
3 MHz, most of the energy will pass completely through the human body
with little attenuation or heating effect. The dangers of non-ionizing
RF radiation are most severe at UHF and microwave frequencies. Human
eyes are particularly vulnerable to low-energy microwave radiation and
blindness can result from overexposure. Cardiac pacemakers may also be
affected by RF radiation.
Ionizing X-ray radiation may exist near high power tube transmitters
depending on the work-function of the materials that the tube is con-
structed with. Typically X-rays are emitted from the copper anode at
high voltages. As operating voltages increase beyond 15 kilovolts, power
tubes are capable of producing progressively dangerous X-ray radiation
[8]. X-ray levels should be checked at regular intervals for possible
changes due to tube aging. Exposure to excessive ionizing X-ray radiation
may damage human body cells with resultant biological changes due to
dissipation of energy in body tissues. The levels of radiation, the
exposure rate, and the length of time over which exposure occurs are
closely connected with the nature and extent of any damage. The effect
of ionizing radiation on matter is to release charge either by direct
ionization or by the liberation of ionizing particles [9].
High Temperatures and Fire
The transmitting equipment parts may attain high temperatures under
normal conditions. The external surface of power tubes operates at high
temperatures (up to 200 degrees to 300 degrees centigrade).
All hot surfaces may remain hot for an extended time after the trans-
mitter is switched off [8]. Thermal burns may result if the body skin
comes in contact with hot surfaces. Hot water lines used for tube cool-
ing in some transmitters may present a similar hazard. The temperature
rise of some components under fault conditions may be excessive so as to
cause injury to personnel. Staff should keep away from hot surfaces and
should be aware of any possibility of fire or its spread and take neces-
sary precautionary measures.
Other Hazards
Personnel should be aware of components which may cause danger due
to implosion or explosion. These apply to components such as cathode-
ray tubes, vacuum power tubes, electrolytic capacitors or glass fuses.
Accidental breakage of vacuum tube glass envelope can cause an implosion,
which will result in an explosive scattering of flying glass particles
and fragments. This may cause serious personal injury [8].
Beryllium oxide ceramic material (BeO) is used as a thermal link to
dissipate heat away from a tube or transistor. BeO dust or fumes are
highly toxic and breathing them may result in serious injury endangering
the life [8]. Polychlorinated biphenyls (PCBs) used in older oil-filled
power transformers and high voltage capacitors are also hazardous. The
Environmental Protection Agency (EPA) has established regulations (40
CFR Part 761) regarding the use and disposal of electrical components
containing PCBs.
Care should be taken to prevent injury due to contact with moving
mechanical parts such as fans, gears. Sharp projections or edges should
be avoided to protect from cuts or abrasions. Exposure to excessive
noise can cause damage to hearing and to the nervous system.
SAFETY REQUIREMENTS FOR TRANSMITTING EQUIPMENT
Safety Standards
Safety standards related to broadcast transmitter installations are
found in the following publications:
(a) International Electrotechnical Commission (IEC) Publication 215
contains the safety standard for radio transmitting equipment
[6]. This is the only standard which specifically addresses
the safety requirements for transmitting equipment.
(b) The general safety standard used widely for reference purposes
is the Military Standards, "MIL-STD-454K: General Requirements
for Electronic Equipment, Requirement 1, Safety Design Criteria -
Personnel Hazard" [1]. This standard establishes safety design
criteria and provides guidelines for personnel protection.
(c) Safety Standard which deals with permissible levels of human
exposure to RF electromagnetic fields is contained in the
American National Standards Institute document ANSI C95.1-1982
[7].
(d) The National Electrical Code (NEC) is a comprehensive document
that details safety requirements for all types of electrical
installations. The National Electric Code or The National
Electrical Code Handbook is published by the National Fire Pro-
tection Association (NFPA) [10].
(e) Another NFPA publication titled "NFPA 79: Electrical Standard
for Industrial Machinery 1987" provides detailed information
for the application of electrical/electronic equipment, appara-
tus, or systems supplied as part of industrial machinery which
will promote safety to life and property [11].
(f) U.S. Department of Labor, Occupational Safety and Health Admin-
istration (OSHA) Safety and Health Standards 29 CFR 1910 con-
tains design safety standards for electrical systems, safety-
related work practices, safety-related maintenance requirements
and safety requirements for special equipment [12].
Other publications related to safety are given in the reference
section of this paper including the addresses to order any of the pub-
lications listed.
Safety Requirements
The principal design and construction requirements for safety of
personnel during the installation, operation and maintenance of broadcast
transmitters are discussed below. Major differences between existing
standards are also highlighted.
(a) Protection against electrical shock and burns, including RF
skin-burns.
(1) An effective grounding system is essential to prevent the
possibility of electric shock. The equipment grounding
is necessary to insure that all the external metal parts,
surfaces, shields are bonded together and then connected
to a safety ground by a low-impedance conductor of suf-
ficient capacity to carry operating and fault currents.
System grounding is required to connect one of the primary
AC conductor and service equipment to ground, which then
completes the ground-fault loop. Proper grounding also
protects equipment from damage caused by AC line disturb-
ances.
(2) A reliable main power disconnect switch for cutting off
all power to the transmitter should be provided. The
switch should plainly indicate whether it is in the open
(off) or closed (on) position. Live conductors shall be
protected against accidental contact. A fused type dis-
connect is preferred over circuit breakers by some broad-
cast engineers.
(3) Type of protection required to prevent accidental contact
with different voltage levels is given in Table 2. Pro-
tection requirements specified by NFPA 79, MIL-STD-454K,
and IEC 215 are also shown in the table. Voltages in ex-
cess of 30 volts (per MIL-STD-454K and NEC) or 50 volts
(per IEC 215) should not be directly accessible under
normal operating conditions.
(4) A grounding stick with an insulated handle and a rigid
conducting hook connected to ground by means of a flex-
ible stranded copper wire (covered with transparent sle-
eving) should be provided as an additional safety measure.
TABLE - 2
TYPE OF PROTECTION RECOMMENDED TO PREVENT ELECTRICAL SHOCK
-----------------------------------------------------------------------------
VOLTAGE | | | |
RANGE | NFPA - 79 | MIL-STD-454K | IEC - 215 |
(RMS/DC) | | | |
------------------------------------------------------------------------------
0-30 V None None None
------------------------------------------------------------------------------
30-50 V Provide doors or covers to protect from direct accidental
contact under normal operating conditions.
------------------------------------------------------------------------------
Exposed high voltage
circuits and capacitors
should be discharged to
50-70 V Doors permitting 30 volts or less within Protective covers not
access to voltage 2 seconds after dis- removable by hand.
50 volts or more connecting power.
should be inter- -----------------------
70-250 V locked to disconnect Parts exposed to dc, ac
power when opened. or rf voltages should ----------------------
-------------------- be guarded from acci-
250-500V Exposed voltages dental contact with a Current limit in a
should be discharged "CAUTION" sign. 2K ohm test resistor
to 50 volts within Bypassable interlocks connected to ground
one minute after required. is 2mA dc or 0.5mA
disconnecting power. ------------------------ ac.
500-700V Exposed parts should be
completely enclosed ----------------------
with a "DANGER" sign.
Access door or cover
Greater than 700 Volts should be interlocked Exposed parts should
to remove power when be grounded by "fail-
opened. safe" grounding switch
when access door or
cover is opened.
-------------------------------------------------------------------------------
(5) Transmitter output terminals or transmission lines with
RF voltages should be protected from accidental contact
by guards or screens. MIL Standards require protection
against RF voltages in the same manner as for AC voltages
in the 70 to 500 volt range. IEC 215 Standard requires
that RF output connection has provision to drain off any
static charge build up. It should also be protected
against RF voltages pick-up due to coupling from other
transmitters operating on the same site.
(6) Low voltage/high current parts such as tube filament
supplies, large filter capacitors, and high-capacity
batteries should be protected against accidental short-
circuits. This may be accomplished by the use of mechan-
ical guards with warning signs or safety devices. MIL
Standards require protection for all power busses supply-
ing 25 amperes or more.
(b) Protection against harmful radiation.
The transmitter construction should have adequate shielding so
that there is no danger to personnel from any stray or cabinet
radiation.
(1) Non-ionizing radiation at radio frequencies: MIL-STD-454K
specifies the requirements of the American National Stand-
ards Institute (ANSI) C95.1-1982 Standard with respect to
human exposure to RF electromagnetic fields in the fre-
quency range from 300 kHz to 100 GHz. ANSI Standard
recommends specific absorption rate (SAR) below 0.40 watts
per kilogram as averaged over the whole body over any 0.1
hour period. "SAR" is the time rate at which RF energy is
imparted to an element of mass of a biological body.
Radio frequency protection guide for whole-body exposure
of human beings in terms of the equivalent plane-wave free
space power density measured at a distance of 5 cm or
greater from the transmitter part as a function of fre-
quency is illustrated in Figure 2. The limit on the power
density between 30 to 300 MHz is 1 mW/cm2 (milliwatts per
square centimeter). A 10 mW/cm2 per 0.1 hour average
level has been adopted by OSHA as the radiation protection
guide in the frequency range of 10 MHz to 100 GHz [12].
The IEC 215 Standard recommends a power density limit of
10 mW/cm2 over the frequency range 30 MHz to 30 GHz.
MIL-STD-454K requires that shields, covers, doors, which
when opened or removed allow microwave and RF radiation
to exceed the above, should be provided with non-bypas-
sable interlocks.
FIGURE 2.
RADIO FREQUENCY PROTECTION GUIDE FOR WHOLE-BODY EXPOSURE
OF HUMAN BEINGS
(2) Ionizing radiation of X-rays: For X-rays an exposure
that releases a charge of 0.258 coulomb per gram of dry
air is defined as one roentgen. MIL-STD-454K specifies
limit of radiation levels to less than 2 mR (milliroen-
tgens) in any one hour and 100 mR in any consecutive 7
days. Shields, covers, doors which allow X-ray radiation
to exceed the limit when removed should be provided with
non-bypassable interlocks. The IEC 215 Standard speci-
fies a limit of radiation level to less than 0.5 mR per
hour per kilogram.
(c) Protection against high temperatures and fire.
MIL-STD-454K specifies the temperature rise limit to exposed
parts including enclosure of the equipment to 35 C (degrees
centigrade) maximum and those of front panels and controls to
24 C rise at 25 C ambient. The IEC 215 Standard requires that
temperature rise of accessible parts be limited to 30 C under
normal operation and 65 C under fault conditions at 35 C ambi-
ent temperature, to prevent injury to personnel [13].
The electrical insulation or mechanical strength of equipment
parts should not be impaired by the temperature rise. No part
of the equipment shall reach high temperature so as to cause
danger or fire or the release of flammable or toxic gases. The
use of flammable material should be avoided and the possibility
of fire and its spread should also be minimized.
(d) Other Hazards.
Components prone to implosion or explosion under fault condi-
tions should be protected against danger to personnel. The
safety valve of the components such as electrolytic capacitors
should be clearly marked and oriented so as not to endanger the
personnel in the event of its operating.
Moving parts such as blowers, motors, fans, gears should be
adequately guarded to prevent possible injury. Mechanical
design should minimize the possibility of injury from sharp
edges, protruding corners, release of springs or accidental
pulling out of drawers or assemblies. Attention should also
be paid to minimize the generation of acoustic noise.
Permissible noise exposure limit specified by OSHA regulations
in a full work day of 8 hours is 90 dB(A) of sound level when
measured by a precision sound-level meter [14].
PROTECTIVE CIRCUITS, DEVICES, AND METHODS USED IN A TYPICAL RADIO
BROADCAST TRANSMITTER TO ACHIEVE DESIRED SAFETY LEVEL
The protective circuits and safety devices typically used in radio
broadcast transmitters manufactured in the United States will be discus-
sed to illustrate safety design considerations.
Protective Circuits
Incoming AC primary power source should be connected to the trans-
mitter through a fused main disconnect switch so that all power may be
cut off quickly and reliably, either before working on the equipment, or
in case of a fault condition or an accident.
The equipment enclosures, chassis, or frames, including ground ter-
minals of power supplies, are connected to the cabinet or rack ground
strap. Typically, a two-inch wide copper strap is routed inside each
transmitter rack or cabinet. Straps of individual racks are then bolted
together and connected to the ground terminal as shown in Figure 3. The
ground terminal is provided for connection to the station earth ground
and the system ground. The ground strap has sufficient current carrying
capacity and provides a low impedance path for equipment ground fault
currents.
A simplified primary AC control diagram of a Broadcast Electronics
FM transmitter is shown in Figure 4. The primary AC input to the trans-
mitter is distributed to the low voltage and high voltage supplies
through separate properly rated circuit breakers and contactors. The
transmitter design incorporates a safety interlock circuit to disconnect
primary power from contactors when access doors or panels are opened.
Contactor coils are de-energized by specially designed optically coupled
relays (OCR) which are in turn operated by the transmitter controller
logic level commands. The contactors cannot be re-energized to restore
the power without first closing the interlock circuit and then manually
resetting the transmitter turn-on sequence.
FIGURE 3.
TRANSMITTER CABINET GROUND STRAP CONNECTIONS
This feature eliminates the possibility of turning on the transmitter
due to accidental closing of doors during maintenance. An external
interlock circuit such as for a test load or remote control fail-safe
connection is also provided to disable the high voltage supply when
opened. A positive going control voltage of +15 volts DC is required to
complete the interlock circuit in the transmitter controller. This is a
"fail-safe" feature because any ground fault in the interlock circuit
wiring will make the circuit fail in the "safe" condition, thereby elim-
inating the possibility of turning on the high voltage.
Grounding sticks and high voltage shorting switches are also inter-
locked to prevent the transmitter from turning on if these safety devices
are not in the normal operating position. The transmitter control cir-
cuit design allows the blower to run for few minutes after turning off
the filament supply so that the tube may cool down. This safety measure
will help prevent accidental burns, if the tube anode radiator is touched
by maintenance personnel after the cool-down period.
FIGURE 4.
SIMPLIFIED PRIMARY AC CONTROL DIAGRAM OF A
BROADCAST ELECTRONICS FM TRANSMITTER
In addition to personal safety devices, the following additional
circuits are provided to protect the equipment and its parts:
(a) Component stress at power-on is reduced by a step-start cir-
cuit which limits inrush current in the high voltage power
supply.
(b) An air interlock circuit to insure adequate differential air
pressure and flow for the tube before the filament voltage
is applied.
(c) The step/start circuit is interlocked through contacts of
filament contactor to assure that the filament voltage is
applied to the tube before a high-voltage-on sequence can be
initiated.
(d) The RF drive to the tube cannot be applied without turning on
the high voltage.
(e) Any fault condition causing circuit overloads due to high
plate current, screen current, grid current, or high VSWR will
be interrupted to protect the equipment from possible damage.
(f) Solid-state intermediate power amplifiers have built-in tem-
perature sensors to shut down the transmitter when the heat-
sink temperature exceeds the maximum limit.
Protective Devices
(a) Bleeder Resistors.
Bleeder resistors provided in all power supplies function as
the first level of protection against dangerous voltages. The
bleeder resistors discharge residual voltages from all com-
ponents with stored energy when the primary power is switched
off. The rate at which the voltage discharges depends upon
the nominal voltage and the R-C time constant of the power
supply. The resistor values should be chosen to allow the
voltages to decay to a safe level within the specified time
interval after turning off the power. The voltage drops to
0.37 times the initial or nominal voltage in one time constant
interval (RC seconds, where R is in ohms and C is in farads).
This is shown in Figure 5.
(b) Safety Interlock Switches.
Safety interlock switches typically used in broadcast trans-
mitters and their construction are shown in Figure 6. Figure
6A shows switches with an activating lever which closes the
interlock contacts when the grounding stick is properly se-
cured. This type of switch is also used to insure that the
high voltage shorting switch remains in the open state when
the access door to the RF enclosure is closed.
FIGURE 5.
CAPACITOR VOLTAGE DISCHARGE WITH TIME
FIGURE 6A FIGURE 6B
SAFETY INTERLOCK SWITCHES
The switch shown in Figure 6B is used extensively to interlock
cabinet doors, enclosure access doors, panels, or covers. The
switch is designed in accordance with the "fail-safe" principle
to keep the contacts open when the mechanical spring is ex-
panded in its natural state.
(c) High Voltage Shorting Switches.
High voltage shorting switches provide a back-up system to the
safety interlock switches described in "(b)" above. This
philosophy provides two independent safety systems to protect
personnel from accidental exposure to high voltages.
A high voltage shorting switch design based on the "fail-safe"
principle, is shown in Figure 7. The insulated rod with a
built-in spring mechanism and the block for mounting contact
plates are all integral parts of the switch which remain in or
go to a "safe" condition to provide protection to personnel in
the event of a fault within the device. These positive acting,
highly reliable devices are actuated by mechanical release when
the door is opened. High voltage is short-circuited to ground
due to the closure of contact plates. The insulating rod and
housing material has been chosen such as to allow smooth, un-
restricted movement from "safe" to "unsafe" position or vice
versa. The switch cannot be bypassed without deliberate action
violating the safety rules. The high voltage shorting switch
shown in the above-mentioned figure is used for short-circuit-
ing the high voltage when the RF enclosure access door is
opened. The built-in interlock switch contacts open first to
remove primary power just before grounding the high voltage.
The switch is designed such as to prevent any corona discharge
under normal operating conditions and to withstand breakdown
voltage at least twice the nominal high voltage level.
FIGURE 7.
HIGH VOLTAGE SHORTING SWITCH
(d) Fail-Safe Solenoid.
The fail-safe solenoid shorts the high voltage circuits to
ground and provides a back-up system to the safety interlock
switches described in "(b)-" above. This philosophy provides
two independent safety systems to protect personnel from
accidental exposure to high voltages.
A fail-safe solenoid is shown in Figure 8. This safety device
is actuated by an electrical solenoid such that the plunger
drops to short the high voltage terminal to ground when the
transmitter cabinet door is opened. In addition, this device
will short the high voltage circuits whenever power is removed
from the blower and cabinet flushing fans.
The solenoid design, as the name implies, is based on the
"fail-safe" principle. It will remain in or go to a condition
which provides protection to personnel in the event of a fault
within the device. As soon as the door is opened, the power
to the solenoid coil is interrupted and the plunger will drop
due to its weight and the mechanical release of spring, thereby
shorting the high voltage. This device cannot be disabled
without deliberately violating the safety rules. The spacing
between the contacts is selected to eliminate possibility of
any corona discharge or dielectric breakdown.
FIGURE 8.
FAIL-SAFE SOLENOID (WITHOUT COVER)
(e) Grounding Sticks.
The purpose of a grounding stick is to remove residual voltages
from exposed parts of the transmitter before working on it. It
is essential to discharge voltages remaining in the equipment
after turning off the transmitter, because residual voltages in
the energy storage components may be dangerous to personnel
safety, particularly if the other safety devices did not func-
tion properly. The grounding stick is a mandatory safety de-
vice in all transmitters containing dangerous voltages.
A typical grounding stick is shown in Figure 9. It consists of
an insulated handle appropriate for the voltages in the equip-
ment, with a rigid metal hook at one end. A flexible stranded
copper wire of adequate size connects the hook to the cabinet
ground strap. A transparent sleeving is used as an insulation
for the wire to allow visual verification of the ground wire
integrity. The grounding stick is permanently secured in the
transmitter to make it readily visible and accessible by means
of either a ground stick hanger or a pair of clamps with built-
in interlock switch to insure its correct placement as shown in
Figures 9 and 10.
FIGURE 9.
GROUNDING STICK
FIGURE 10.
GROUNDING STICK
AND BLOWER SAFETY SHIELD
(f) Protective Covers, Guards, Shields and Markings.
All contacts, terminals, and conducting parts having voltages
higher than 50 volts (per IEC 215 Standard) and 70 volts (per
MIL Standards) with respect to ground when exposed and exhibit
safety hazard are guarded from accidental contact by personnel.
A guard for an AC terminal block is shown in Figure 11. High
voltages are guarded by protective insulator or metal shields
as shown in Figure 12. Low voltage components with large
amounts of stored energy and conductors carrying high currents
are also guarded where necessary by protective covers with
proper markings. An example is shown in Figure 13.
FIGURE 11. GUARD FOR AC TERMINAL FIGURE 12. HIGH VOLTAGE METAL
BLOCK SHIELD
FIGURE 13. PROTECTIVE GUARD FOR FIGURE 14. PROTECTIVE SHIELD FOR
CAPACITOR TERMINALS FANS WITH WARNING LABELS
Protective shields with warning signs are also provided to
prevent contact with moving mechanical parts such as fans and
blowers. Figure 14 shows a protective shield for fans with
warning labels. Blower safety shield can be seen in Figure 10
mentioned above. The cabinet doors are provided with appro-
priate markings as shown in Figure 15.
FIGURE 15.
CABINET DOOR WARNING LABEL
Safety protection against RF radiation is provided by proper
shielding to reduce RF leakage from doors, vent holes, air in-
let and exhaust openings. Conductive finger stock and special
aluminum shield cell honeycomb panels are used to provide ade-
quate shielding as shown in Figures 16 and 17. An instrument
for measuring the RF radiation levels to OSHA recommended
limits is available from Holaday Industries, Inc. Broadcast
Electronics uses this instrument to insure that the residual RF
leakage from the transmitter is below the safe limit.
FIGURE 16.
CONDUCTIVE FINGER STOCK TO REDUCE RF RADIATION
FIGURE 17.
ALUMINUM SHIELD CELL HONEYCOMB TO REDUCE RF RADIATION
(g) Circuit Breakers, Fuses and Contactors.
Main primary circuit breakers used in the transmitters are
equipped with a thermal as well as magnetic trip elements in
each pole. Smaller size breakers have magnetic trip elements.
The breakers used conform to applicable UL, National Electrical
Manufacturers Association (NEMA), and IEC Standards. The cir-
cuit breakers have adequate making and breaking capacity and
are selected to protect the equipment against excessive steady-
state or instantaneous (less than one cycle) fault currents.
The thermal trip protects against high temperature rise.
Circuits or assemblies which do not have individual breakers
are protected by properly rated enclosed fuse elements. A
fusible link in the center tap of the filament transformer
secondary provides overload and safety protection for the fila-
ment supply wiring if a short-circuit to ground develops in
either leg of the filament supply.
Contactors rated for maximum load and which have adequate
making and breaking capacity are used for primary AC control
of the transmitter in conjunction with the interlock circuits
and the controller unit. The contactors remove the power from
accessible areas when the interlock circuit is broken due to
opening of doors, panels, or covers.
(h) Smoke Detectors, Fire Alarms, and Fire Extinguishers.
These devices are not part of the transmitter equipment and
will not be discussed here. However, it seems prudent to note
the following:
Appropriate type and number of smoke detecting devices and
associated fire alarm circuits should be installed in the
transmitting station. A reliable fire extinguishing system
should also be provided to protect the personnel and equipment
from fire hazards. Halon 1301 based systems are very effective
and will not damage electronic equipment [16]. Automatic fire
extinguisher systems should be interlocked with the transmitter
control system to turn off the transmitter when the fire alarm
system is activated.
Protective Methods
(a) Safety Protection Levels.
Protective methods used to provide different degrees of safety
levels can be summed up as follows:
(1) Primary safety level is accomplished by providing doors,
panels, and covers with warning signs or labels to avoid
direct access to dangerous voltages. In addition, bleeder
resistors are provided to discharge residual voltages from
energy storage components such as capacitors which may be
hazardous to safety even after the equipment is switched
off.
(2) Secondary safety level is established by providing contac-
tors together with mechanical and/or electrical interlock
systems to insure that the primary power is removed when
access doors, panels, or covers are opened without switch-
ing off the equipment.
(3) A third safety level is insured by providing shorting
switches to short high voltages to ground when the door
is opened and also by providing shields and guards which
require tools for their removal.
(4) Ultimate safety level is achieved by providing good ground-
ing system, by removing primary power from the equipment
with a main disconnect switch, and by using a grounding
stick to short out all residual voltages. An external
voltage measuring instrument may be used to verify the
absence of voltage. When the transmitter is equipped with
primary AC metering, it may also be used for this purpose.
(b) Safety Protective Methods.
(1) Safety Program.
A good safety policy should be established by the station
management and a comprehensive safety program should be
developed and implemented as part of the regular business
activity to insure that the facility is operating safely.
Safety standards, rules, and guidelines should be devel-
oped and enforced. Safety hazards should be identified
and necessary precautionary measures taken to eliminate or
control them. All the broadcast staff and particularly
those staff who have access to the transmitter facility
should be properly trained in safety practices, including
cardiopulmonary resuscitation (CPR) techniques and in the
use of personal protective equipment if required. An
adequate first aid kit with training should also be pro-
vided.
The United States Department of Labor, Occupational Safety
and Health Administration (OSHA) regulations and guide-
lines contain safety requirements. Necessary information
can be obtained from OSHA to start a safety program or to
seek the services of a consultant [15].
(2) Safety Practices.
Basic electrical safety practices are described in various
standards, regulations and other publications which are
listed in the reference section of this paper. Some key
personal safety precautions to be considered are high-
lighted below:
- Thinking safety and ensuring that the transmitter in-
stallation is safe in accordance with the OSHA regula-
tions or National Electric Code.
- Taking time to be careful and using common sense.
- Turning off all power circuits before touching anything
inside the transmitter.
- Eliminating the possibility of someone else turning on
the equipment (by local or remote control methods) while
working on equipment.
- Discharging all the voltages to ground, particularly
from energy storage components.
- Avoiding bodily contact with any grounded object when
working on the transmitter.
- Avoiding unnecessary exposure to RF radiation.
- Using safety tools and equipment.
- Ensuring that all the safety circuits and devices func-
tion correctly.
- Avoid working alone or when tired.
CONCLUSION
Safety is an important factor in the design and development of
broadcast transmitters. However, it is not uncommon to find safety taken
for granted in today's highly commercial broadcast station environment
with fewer trained and experienced technical staff. The management and
staff in the broadcasting business should give a high priority to the
matter of personal safety because it concerns with the protection of
personnel against injuries which may endanger the life. The cost of
failure to recognize this fact may far exceed the small initial invest-
ment required in implementing a sound safety program.
Various hazards as well as the industry standards and the safety
requirements related to transmitting equipment have been reviewed. De-
sign considerations for numerous types of protective circuits, devices,
and methods used in broadcast transmitters to achieve the desired safety
level have also been discussed.
It is hoped that this paper will serve to stimulate greater aware-
ness of personnel safety among broadcasters, equipment manufacturers, as
well as equipment users at large and provide motivation to implement one
or more positive action plans to make the broadcast station environment
a "safer" place to be.
ACKNOWLEDGEMENT
The author is grateful to Mr. Geoffrey N. Mendenhall for his helpful
suggestions and encouragement, as well as for his help in editing this
paper.
The author wishes to thank Jim Shennick, Rick Brose, Rick Carpenter
and Ed Anthony for their comments. The author is also grateful to John
Stevenson of Underwriters Laboratories for providing some of the research
data.
Special thanks to Kathy Glore for typing the draft, Charlotte
Steffen for word processing, Eric Power for illustrations and Larry Foster
for photos and formatting this paper.
AUTHOR
Mukunda B. Shrestha earned his MSEE degree from the Southern Illinois
University at Carbondale, Illinois. He also has a Master of Science de-
gree in radio broadcasting and communication engineering from the Moscow
Electrical Communications Institute, Moscow, USSR.
Mr. Shrestha is Manager of RF Engineering for Broadcast Electronics
Inc. in Quincy, Illinois. He was the Project Engineer for the development
of Broadcast Electronics FM-20 20 kW FM transmitter. He has made major
design contributions to the development and support of the entire line of
Broadcast Electronics "A" and "B" series FM transmitters.
Mr. Shrestha's practical experience involved engineering, operations,
and management work as director of engineering for the National Radio
Broadcasting Network of Nepal. His earlier experience includes several
years of engineering and management work in broadcasting, as well as
aeronautical communications and navigational aid equipment.
The author holds an U.S. Patent for electronic design utilized in
broadcast equipment and is a member of the Institute of Electrical and
Electronics Engineers. He is also a member of Tau Beta Pi and Phi Kappa
Phi honor societies.
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