CH1 Medical Gases and Storage equp book.pdf

Full Transcript

1
Medical Gases: Storage and Supply
S. NINI MALAYAMAN | GEORGE MYCHASKIW II | JAMES M. BERRY |
JAN EHRENWERTH

CHAPTER OUTLINE Changes in technology and institutional organization have
relieved the anesthesiologist of most of these responsibilities.
Overview However, this should not excuse anesthesia providers from
Medical Gas Cylinders and Their Use understanding the basic facts and safety principles associated with
Oxygen Tanks the use of medical gases for anesthesia. Invariably, other health
Nitrous Oxide Tanks care providers and administrators have little knowledge regarding
Air Tanks these systems and look to anesthesia professionals for guidance in
the use and handling of these gases in the hospital or clinic setting.
Characteristics of Gas Cylinders
With few exceptions, the only medical gases encountered by
Size
practicing anesthesiologists today are oxygen (O2), nitrous oxide
Color Coding
(N2O), and medical air. For safety reasons, flammable agents are
Cylinder Markings
rarely, if ever, used in operating rooms (ORs) today. Nitrogen
Pressure Relief Valves
is used almost exclusively to power gas-­ driven equipment.
Connectors
Helium, carbon dioxide, and premixed combinations of oxygen
Gas Cylinder Safety Issues and carbon dioxide are generally no longer used. In certain
Prevention of Incorrect Gas Cylinder Connections uncommon clinical situations, other gases may be used. Helium
Securing Cylinders Against Damage is occasionally used as an adjunct in the ventilation of patients
Transfilling undergoing laryngeal surgery because of its low density and
Cylinder Hazards flow-­enhancing characteristics when flow is turbulent. Carbon
Guidelines for Use of Medical Gas Cylinders dioxide is infrequently used in the management of anesthesia for
Supply repair of selected congenital heart defects. Finally, nitric oxide
Storage (NO) is currently available for use as a pulmonary vasodilator.
Transport and Installation Anesthesiologists who use these gases should be fully versed in
their characteristics and safe handling. For detailed information
Medical Gas Pipeline Systems and numerous references relating to the handling and use of these
Medical Gas Central Supply Systems and other unusual medical gases, along with a wealth of general
Oxygen information about medical gas cylinders, the reader is directed
Oxygen Concentrators to publications from the Compressed Gas Association (CGA).1,2
Medical Air Medical gas manufacturers are subject to more stringent
Nitrous Oxide government and industry regulations and inspections than they
Helium have been in the past. This has helped to markedly reduce the
Nitric Oxide number of accidents related to medical gases. For these reasons,
Nitrogen anesthesia training programs may not emphasize instruction in
Central Vacuum Systems the various aspects of storing and using medical gases.
Medical Gas Pipelines In addition, increased concern regarding the safety of
Planning anesthetized patients has helped reduce the number of gas-­related
Additions to Existing Systems injuries. Inspired oxygen monitors with lower concentration limit
Installation and Testing alarms provide the anesthesia practitioner with an early warning
when the oxygen supply becomes inadequate or is contaminated
Hazards of Medical Gas Delivery Systems with another gas. Mixed-­gas monitoring and analysis is common
Procedures and provides the practitioner with an important way to quickly
detect contaminants or unusual gas mixtures before the patient is
injured. If the oxygen monitor fails, pulse oximetry can alert the
Overview anesthesiologist to problems with patient oxygenation related to
inadequate oxygen supply.
Anesthesia providers were once expected to know a great deal
about the storage and supply of medical gases. In both large
and small institutions, anesthesiologists often had to rely on
Medical Gas Cylinders and Their Use
their own knowledge and skill in this area to manage the many Medical gases are stored either in metal cylinders or in the
aspects of medical gases, from purchasing to troubleshooting. reservoirs of bulk gas storage and supply systems. The cylinders
3

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
4 PART 1 Gases and Ventilation

are almost always attached to the anesthesia gas machine. Bulk the critical pressure, which must be applied at this temperature
supply systems use pipelines and connections to transport to keep oxygen liquid, is 737 psia. Because room temperature is
medical gases from bulk storage to the anesthesia machine. usually 20°C (far in excess of the critical temperature), oxygen
Virtually all facilities in which anesthesia is administered can exist only as a gas at room temperature.
are equipped with central gas supply systems. Anesthesia E-­cylinders of oxygen are filled to approximately 1900 pounds
practice is currently undergoing change in this regard, and per square inch gauge (psig) pressure at room temperature: 1
many anesthetics are administered outside the OR, and even atmosphere (atm) is 760 mm Hg, which equals 0 psig or 14.7 psia.
outside the hospital, where a central gas supply system may be At high pressures, psig and psia are virtually the same. When
unavailable. The current emphasis on providing care away from full, the cylinders contain a fixed number of gas molecules, the
the hospital—such as in dental clinics, mobile lithotripsy units, so-­called fixed mass of that gas. These gas molecules obey Boyle’s
and mobile magnetic resonance imaging facilities—will only law, which states that pressure times volume equals a constant
increase the demands on the anesthesia provider to ensure a safe (P1V1 = P2V2), provided temperature does not change. A full
and continuous gas supply. E-­cylinders are sometimes the only E-­cylinder of oxygen with an internal volume of 5 L (V1) and
source of medical gas for anesthesia machines in these settings. a pressure of 1900 psia (P1) will therefore evolve approximately
If an anesthetic is being administered using only E-­cylinders, 660 L (V2) of gaseous oxygen at atmospheric pressure (P2, or
then both the anesthesiologist and related support personnel 14.7 psia). Thus, Boyle’s law gives the approximate value:
must first ensure that an adequate supply of reserve cylinders is
V2 = P1 × V1 / P2 = 1900 × 5 / 14.7 = 660 L
available. In addition, the amount of gas in the cylinders being
used must be continually monitored, and the cylinders must be If the oxygen tank’s pressure gauge reads 1000 psig, the tank is
replaced before they are completely emptied. The importance of approximately 50% full (1000 ÷ 1900) and contains only 330 L
this cannot be overemphasized. Many anesthesia practitioners (660 × 50%) of oxygen (Fig. 1.1). If such a tank were to be used
today have not been confronted with the possibility of running at an oxygen flow rate of 6 L/min, it would empty in just under
out of oxygen and having to change a tank while administering an an hour (330 ÷ 6 = 55 minutes). Likewise, a full (2200 psig)
anesthetic—but the evolving nature of anesthesia practice away H-­cylinder will evolve 6900 L of oxygen at atmospheric pressure.
from traditional facilities is likely to make this a more common It is important to understand these principles when oxygen
occurrence. If an anesthesiologist anticipates this situation, it is tanks are being used to supply the machine or a ventilator or to
imperative that the anesthesia machine be equipped with two transport a patient. Because oxygen exists only as a gas at room
oxygen cylinder yokes so that oxygen delivery can continue temperature, the tank’s pressure gauge can be used to determine
while the empty tank is changed. how much gas remains in the cylinder. Clearly, if a machine is
Anesthesia practitioners should be familiar with two sizes equipped with two E-­cylinders of oxygen, only one should ever
of gas cylinders. The cylinder most often used by anesthesia be open at any time to ensure that both tanks are not emptied
providers is the E-­cylinder, which is approximately 2 feet (61 cm) simultaneously.
long and 4 inches (10 cm) in diameter. E-­c ylinders are also
routinely used as portable oxygen sources, such as when a NITROUS OXIDE TANKS
patient is transported between the OR and an intensive care unit
(ICU). H-­cylinders are larger, approximately 4 feet (122 cm) Nitrous oxide has a molecular weight of 44 and a boiling point
long and 9 inches (23 cm) in diameter, and are generally used as of −88°C at 760 mm Hg. Because it has a critical temperature of
a source of gas for small or infrequently used pipeline systems.
They may be used as an intermediate or long-­term source of gas
at the patient’s bedside. Almost all hospitals store H-­cylinders of
Volume
oxygen in bulk as a back-­up source in case the pipeline oxygen 660 L 330 L 165 L 0L
fails or is depleted. H-­cylinders of nitrogen are often used to Pressure
power gas-­driven medical equipment. H-­cylinders that contain 1900 psig 950 psig 475 psig 0 psig
oxygen, nitrous oxide, or air have occasionally been used in ORs
and are connected to the anesthesia machine via special reducing
valves and hoses. Such uncommon configurations are not only
potentially hazardous, they also defeat certain safeguards. Any
practitioner who uses such a system must become thoroughly
familiar with it and must be certain it complies with applicable
regulations and guidelines.1–5

OXYGEN TANKS
Oxygen has a molecular weight of 32 and a boiling point of
−183°C at an atmospheric pressure of 760 mm Hg (14.7 pounds
per square inch in absolute pressure [psia]). The boiling point
of a gas—that is, the temperature at which it changes from Full 50% Full 25% Full Empty
liquid to gas—is related to ambient pressure in such a way that Fig. 1.1 Oxygen remains a gas under high pressure. The pressure falls
as pressure increases, so does the boiling point. However, a linearly as the gas flows from the cylinder; thus, in contrast to nitrous
oxide, the pressure remaining always reflects the amount of gas remain-
certain critical temperature is reached, above which it boils into ing in the cylinder. (Modified from Bowie E, Huffman LM: The anesthe-
its gaseous form no matter how much pressure is applied in the sia machine: essentials for understanding, 1985. With permission from
liquid phase. The critical temperature for oxygen is −118°C, and GE-Datex-­Ohmeda, Madison, WI.)

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
 1 Medical Gases: Storage and Supply 5

Volume L [(400 ÷ 745) × 253] of nitrous oxide gas. However, nitrous
1590 L ? ? 215
L
oxide vapor does not behave like an ideal gas and does not
Pressure obey Boyle’s law. In fact, the tank contains a greater fraction
745 psig 745 psig 745 psig 400 psig of nitrous oxide. This is because a vapor that is so close to its
saturation point is more compressible than an ideal gas. In fact,
almost one-­quarter of the full tank remains when the last drop
of liquid nitrous oxide has just evaporated. Therefore, when the
N2O gas
pressure in the cylinder begins to fall, approximately 400 L are
left to be evolved. Now, when the pressure in the tank decreases
to 400 psig, there is about 215 L of nitrous oxide remaining
(400 ÷ 745 × 400).
N2O liquid
While anesthesia is being administered, it is not practical to
remove the nitrous oxide cylinder from the anesthesia machine
and weigh it accurately enough to determine how much nitrous
oxide is left. When the nitrous oxide is being used rapidly, the
latent heat of vaporization causes the cylinder itself to become
Full cold. If humidity is sufficient in the surrounding atmosphere,
Fig. 1.2 At ambient temperature (20°C), nitrous oxide liquefies under some moisture (or even frost) may collect on the outside surface
high pressure, and the pressure of the gas above the liquid remains of the cylinder over the portion that is filled with liquid nitrous
constant independent of how much liquid remains in the cylinder. Only oxide. The moisture line, or frost line, which may drop as the gas
when all the liquid has evaporated does the pressure start to fall, and is used, can provide an indication of when the nitrous oxide will
then it does so rapidly as the residual gas flows from the cylinder. (From
Bowie E, Huffman LM: The anesthesia machine: essentials for under-
run out. A number of tapes and devices are available to mark
standing, 1985. With permission from GE-Datex-­Ohmeda, Madison, WI.) the cylinders for this purpose, but their reliability has not been
tested. If nitrous oxide is to be used as an anesthetic, it is best to
begin with a full cylinder because the length of time the cylinder
36.5°C and critical pressure of 1054 psig, nitrous oxide can exist will last can be calculated. For example, a full E-­cylinder of
as a liquid at room temperature (20°C). E-­cylinders of nitrous nitrous oxide used at a flow rate of 3 L/min will last about 9
oxide are filled to 90%–95% of their capacity with liquid nitrous hours (3 × 60 × 9 = 1620 L).
oxide. Above the liquid in the tank is nitrous oxide vapor, that
is, gaseous nitrous oxide. Because the liquid nitrous oxide is in
AIR TANKS
equilibrium with its vapor phase, the pressure exerted by the
nitrous oxide vapor is its saturated vapor pressure (SVP) at the Medical air is most commonly provided in E-­size cylinders
ambient temperature. which are color coded yellow. A full cylinder has a pressure of
A full E-­cylinder of nitrous oxide will evolve approximately 1900 psig and contains about 625 L (Table 1.1). The air in the
1590 L of gaseous nitrous oxide at 1 atm (14.7 psia). As long cylinder exists as a gas and will obey Boyle’s law (see previous
as some liquid nitrous oxide remains in the tank and the discussion of oxygen tanks). The air tank has a unique pin
temperature remains constant (20°C), the pressure in the tank index and can only be installed on the air hanger yoke of the
will be 745 psig, or the SVP of nitrous oxide at 20°C (Fig. 1.2). anesthesia workstation.
It should be clear that, unlike oxygen, the content of a tank of
nitrous oxide cannot be determined from the pressure gauge. It
can, however, be determined by removing the tank, weighing Characteristics of Gas Cylinders
it, and subtracting the empty weight stamped on each tank
SIZE
(tare weight); the difference is the weight of the contained
nitrous oxide. Avogadro’s formula for volume states that 1 g Table 1.1 gives a list of the sizes, weights, and volumes of the
molecular weight of any gas or vapor occupies 22.4 L at standard common cylinders that contain various medical gases. As
temperature and pressure. Thus, 44 g of nitrous oxide occupies noted, the anesthesia provider will most often encounter
22.4 L at 0°C and 760 mm Hg pressure. At 20°C this volume oxygen and nitrous oxide in E-­ cylinders and a variety of
increases to 24 L (22.4 × 293 ÷ 273); thus, each gram of nitrous gases in H-­cylinders. Although other gas cylinders are found
oxide is equivalent to 0.55 L of gas at 20°C. in the OR—such as those used for gas-­powered equipment,
Only when all the liquid nitrous oxide in the tank has been laparoscopy equipment, and lasers—these are not likely to be in
used up and the tank contains only gaseous nitrous oxide, one the domain of anesthesia personnel.
might expect that Boyle’s law could be applied. Thus, when the
tank pressure (P1) is 745 psig from gas only and the internal
COLOR CODING
volume (V1) of the E-­cylinder is approximately 5 L, the volume
(V2) of nitrous oxide gas that would be evolved at atmospheric Table 1.2 lists the color markings used to identify medical gas
pressure (P2) is represented by the following equation: cylinders. Although the internationally accepted color for oxygen
is white, green is used in the United States, primarily for reasons
V2 = (P1 × V1 ) / P2 of tradition; in addition, yellow is used to identify compressed air,
(745 × 5) / 14.7 = 253.4 L which represents another exception to international standards.
Anesthesiologists working in countries other than the United
At this point the tank appears to be 16% full (253 ÷ 1590). A States should be aware of these differences. Because nitric oxide
tank showing a pressure of 400 psig at 20°C should evolve 136 cylinders are not standardized in color and are frequently supplied

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
6 PART 1 Gases and Ventilation

TABLE
1.1 Typical Volume and Weight of Available Contents of Medical Gas Cylindersa
MIXTURES OF
OXYGEN
Cylinder Style Nominal Unit of
and Dimensions Volume (in3/L) Measure Air CO2 Cyclopropane He N2 N2O O2 He CO2
B 87/1.43 psig 838 75 1900
3.5 × 13 in L 370 375 200
8.89 × 33 cm lb-­oz 1–8 1–7.25 –
kg 0.68 0.66 –
D 176/2.88 psig 1900 838 75 1600 1900 745 1900 b b

4.25 × 17 in L 375 940 870 300 370 940 400 300 400
10.8 × 43 cm lb-­oz – 3–13 3–5.5 – – 3–13 – b b

kg 1.73 1.51 – – 1.73 – b b

E 293/4.80 psig 1900 838 1600 1900 745 1900 b b

4.25 × 26 in L 625 1590 500 610 1590 660 500 660
10.8 × 66 cm lb-­oz – 6–7 – – 6–7 – b b

kg 2.92 – – 2.92 – b b

M 1337/21.9 psig 1900 838 1600 2200 7.45 2200 b b

7 × 43 in L 2850 7570 2260 3200 7570 3450 2260 3000
17.8 × 109 cm lb-­oz – 30–10 – – 30–10 122 cu ft b b

kg 13.9 – – 13.9 – b b

G 2370/38.8 psig 1900 838 1600 745 b b

8.5 × 51 in L 5050 12300 4000 13800 4000 5330
17.8 × 109 cm lb-­oz – 50–0 – 56–0 b b

kg 22.7 – – 25.4 b b

H or K 2660/43.6 psig 2200 2200 2200 745 2200c
L 6550 6000 6400 15800 6900
lb-­oz – – – 64 244 cu ft
kg – – – 29.1 –
aComputed contents are based on normal cylinder volumes at 70°F (21.1°C), rounded to no greater than 1% variance.
bThe pressure and weight of mixed gases vary according to the composition of the mixture.
c275 cu ft/7800 L cylinders at 2490 psig are available on request.

Modified from Compressed Gas Association: Characteristics and safe handling of medical gases, publication P-­2, ed 7. Arlington, VA, 1989,
Compressed Gas Association.

TABLE
1.2 Color Marking of Compressed Gas Containers Intended for Medical Use
Gas U.S. Color Canadian Color
Oxygen Green Whitea
Carbon dioxide Gray Gray
Nitrous oxide Blue Blue
Cyclopropane Orange Orange
Helium Brown Brown
Nitrogen Black Black
Air Yellowa Black and white
Mixture other than oxygen and nitrogen A combination of colors corresponding to
each component gas
MIXTURE OF OXYGEN AND NITROGEN
Oxygen 19.5%–23.5% Yellowa Black and white
All other oxygen concentrations Black and green Pink
aHistorically,
vacuum systems have been identified by white in the United States and yellow in Canada. Therefore it is recommended that white
not be used in the United States and yellow not be used in Canada as markings to identify containers for use with any medical gas.
psig, Pounds per square inch.
Modified from Compressed Gas Association: Standard color marking of compressed gas containers intended for medical use, publication C-­9,
ed 3. Arlington, VA, 1988, Compressed Gas Association.

as bare aluminum, it is important to check the label and not solely (Fig. 1.3). The service pressure (in psig) is stamped on each
rely on color coding to identify a compressed gas. cylinder and should never be exceeded. Each cylinder is also
given its own serial number and commercial designation; the
final code stamped on the cylinder is usually the date of the last
CYLINDER MARKINGS
inspection and the inspector’s mark. Medical gas cylinders must
Certain codes are stamped near the neck on all medical gas be inspected at least once every 10 years, at which time they
cylinders. The U.S. Department of Transportation (DOT), should also be tested for structural integrity; this is done by filling
which has extensive regulations concerning the marking and the cylinder to 1.66 times the normal service pressure. The date
shipping of medical gas cylinders, requires a code to indicate that of this inspection is often circled with a black marker to indicate
the cylinder was manufactured according to its specifications that the cylinder has been checked by the supplier (Fig. 1.4).

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
 1 Medical Gases: Storage and Supply 7

PRESSURE RELIEF VALVES
All medical gas cylinders must incorporate a mechanism to
vent the cylinder’s contents before explosion from excessive
pressure.6 Explosion can result from exposure to extreme heat,
such as in the event of a fire, or from accidental overfilling. These
mechanisms are of three basic types—the fusible plug, frangible
disk assembly, and safety relief valve—and are incorporated into
the cylinder; as such, they cannot be inspected by the user. The
fusible plug, made of a metal alloy with a low melting point, will
melt in a fire and allow the gas to escape. With certain gases,
such as oxygen or nitrous oxide, this can aggravate the fire
because oxygen and nitrous oxide are both strong oxidizers. The
frangible disk assembly contains a metal disk designed to break
when a certain pressure is exceeded and thereby allow the gas to
escape through a discharge vent. Finally, the safety relief valve is
a spring-­loaded mechanism that closes a discharge vent. If the
Fig. 1.3 Some of the cylinder markings on an E-­cylinder. DOT indi- pressure increases, the valve opens and remains open until the
cates that the cylinder was manufactured according to the specifications
of the United States DOT; 3AL indicates the tank is aluminum. 2015 in-
pressure decreases below the valve’s opening threshold. Some
dicates the maximum filling pressure of the cylinder in psig, the num- cylinders have combination devices that incorporate a fusible
ber to the right is the cylinder serial number, and ALL GASS is the tank metal plug with one of the other two mechanisms.
owner’s name. DOT, Department of Transportation; psig, pounds per
square inch gauge.
CONNECTORS
Fig. 1.5 illustrates the tops of typical valves for both of the
most common small (E) and large (H) cylinders. As previously
mentioned, large cylinders have valve outlets that are coded
and are unique to the gas content of the cylinder. The coding
is based on the threads and diameter of the outlet port orifice.4
Regulators to reduce and control the pressure of the gas, also
specific for each type of gas, are attached to these threaded valve
ports. It is highly unsafe to use a regulator for one type of gas on
a valve port of a cylinder of another type of gas.
Small cylinders have cylindrical ports or holes in their
valves to receive the yoke, either on an anesthesia machine
or free standing, from which the gas will flow. A washer
(Bodok seal), usually made of Teflon, is necessary to make
this connection gas tight. Care must be taken to ensure that
the retaining screw that holds the cylinder in the yoke is not
placed into the safety relief device instead of in its intended
location in the conical depression opposite the valve port
(Fig. 1.5A). The connection between cylinder valve and yoke
is made gas specific by the pin index safety system for small
Fig. 1.4 An E-­cylinder of oxygen. The inspection date, August 2008,
has been painted white to indicate the cylinder was checked at the time cylinder connections.
it was delivered to the facility. All cylinders must be checked for leaks
and structural integrity with an overpressure test at least once every 10
years. Gas Cylinder Safety Issues
PREVENTION OF INCORRECT GAS CYLINDER
CONNECTIONS
All medical gas cylinders should come from the supplier
accompanied by a tag with three perforated sections, each In the past, cylinders containing the wrong gas—for example,
designating a different stage of use: empty, in use, and full. nitrous oxide instead of oxygen—were sometimes connected to
The portion of the tag marked “full” should be removed anesthesia gas delivery systems, with disastrous results. This led
when a cylinder is put into service. This is not usually critical, to the development of systems designed to help ensure use of
however, because it is generally obvious when a cylinder is in the correct cylinder. Most of the gas tanks used for anesthesia
use; making use of the tag marker becomes important when are E-­cylinders or other small cylinders, for which the pin index
an empty cylinder is removed from the machine. If the tag is safety system was developed in 1952. The pin index system4
not used correctly at the outset, the problem is compounded relies on two 5-­mm stainless steel pins on the cylinder yoke
with each successive stage of the cylinder’s use, and the final connector just below the fitting for the valve outlet port. Seven
result is storage of an empty cylinder as a full one. Although a different pin positions are possible depending on the type of
discrepancy in weight may alert a user to an incorrectly labeled gas in the cylinder (Fig. 1.6). The yoke connector for an oxygen
cylinder, this error may be easily overlooked in an emergency cylinder, for example, has pins at positions 2 and 5 (Fig. 1.7). Pin
situation. positions for the various gases are listed in Table 1.3. These pins

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
8 PART 1 Gases and Ventilation

On/off valve spindle

Packing nut

Conical Outlet port
depression
Valve seating

Safety relief Holes for
device pin index system
Left Right

6
1

2 5

3 7 4

A

Hand wheel

Nut

Stem

Fig. 1.6 Pin index safety system pin location is shown, looking at the
Outlet port placement of holes in the tank. Pins are placed precisely complemen-
tary in the tank yoke. Two pins are used to identify each type of gas. Pin
Safety relief configurations are listed in Table 1.3.
device

roughly, the person changing the cylinder must make certain
that both pins are intact.

SECURING CYLINDERS AGAINST DAMAGE
Gas cylinders should always be secured when placed in an
upright position. If left freestanding, a cylinder can easily
fall over in such a way that it would fracture at the neck (Fig.
B 1.9). The cylinder’s highly pressurized gas would be suddenly
Fig. 1.5 Typical cylinder valves. (A) A small cylinder packed valve, such released, and the cylinder would become an unguided missile
as would be found on an E-­cylinder. Note that the female-­type port is of tremendous force; in fact, the cylinder can generate enough
not unique to the gas type. (B) A large cylinder packed valve, such as force to penetrate a cinder-­block wall several feet thick. The
would be seen on an H-­cylinder. Note that the male type of outlet port potential danger of such an occurrence is obvious. Therefore,
has a unique diameter and threads as a safety feature intended to help
ensure correct connections. (Modified from Davis PD, Parbrook EO, Par- all gas cylinders must be secured when they are upright. If that
brook GD: Basic physics and measurement in anesthesia, ed 3. Oxford, is not possible, the cylinder can be laid on its side. Individual
UK, 1984, Butterworth-­Heinemann.) E-­cylinders may be placed in a broad-­based wheeled carriage
for support when in use.

fit exactly into the corresponding holes in the cylinder valve
TRANSFILLING
(Fig. 1.8). This system provides an additional safety feature and,
along with color coding, is designed to ensure that the correct Anesthesia personnel should never attempt to refill small
gas is connected to its corresponding cylinder yoke. Obviously, cylinders from larger ones. Even if gas-­tight connections were
connectors with either damaged or missing index pins are unsafe possible, the risk of explosion from the heat of compression in
and should not be used under any circumstances. Because a the small cylinder would still be serious. In addition, there is
pin can easily be lost or damaged when a cylinder is handled always the possibility that the wrong gas would be placed in the

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
 1 Medical Gases: Storage and Supply 9

A B
Fig. 1.7 (A) Cylinder yoke on the anesthesia machine. Note the two pins for the pin index system at the bottom of the yoke (bottom arrow) and
the hole (top arrow; not gas specific) that aligns with the outlet port of the tank. (B) Oxygen yoke with the tank removed and the nitrous oxide tank
in place.

TABLE
1.3 Pin Index Safety System
MIXTURES OF OXYGEN
Air Cyclopropane N2 N2O O2 He CO2
Pin positions 1–5 3–6 1–4 3–5 2–5 2–4 1–6
The pin index system relies on two 5-­mm stainless steel pins on the cylinder yoke connector just below the fitting for the valve outlet port. Seven
different pin positions are possible depending on the type of gas in the cylinder (the seventh pin position is for a gas not used in the United
States). See Figs. 1.6 and 1.7 for pin locations.

be dangerously overfilled to near-­bursting pressures, and six
cylinders of compressed air were found to be contaminated with
volatile hydrocarbons. Thirty cylinders were unlabeled, and the
labels of many others were illegible, having been painted over.
Another four cylinders were incorrectly color coded, five large
cylinders were fitted with incorrect valve outlet ports (especially
dangerous because an oxygen valve on an air cylinder enables air
to be fed into an oxygen outlet), 14 valve assemblies were found
to be loose, and four valve assemblies were inoperable. On a
large number of cylinders, the current inspection date was either
absent or had been painted over so as to be illegible. Numerous
examples were cited of cylinders being improperly stored or
secured. The results of this study serve to remind anesthesia
practitioners of the danger of assuming that gas supplies are
perfectly safe. All facilities should have an established system to
ensure that each cylinder of medical gas is inspected and tested
Fig. 1.8 Cylinder valve at the top of an E-­cylinder shows the two holes
for the pin index system and the outlet port with an attached washer upon delivery to the facility.
(arrow).
Guidelines for Use of Medical Gas
cylinder. The practice of transfilling is also forbidden. Medical
Cylinders
gases must be obtained only from a reputable commercial Numerous rules govern the safe handling of cylinders that
supplier. contain medical gases.1,2 Summarized here are practical points
that anesthesia practitioners must consider on a routine basis.
CYLINDER HAZARDS
SUPPLY
A study of 14,500 medical gas cylinders consecutively delivered
from supposedly reputable suppliers found 120 (0.83%) with As noted above, medical gases should be purchased only from
potentially dangerous irregularities.7 Forty cylinders were a reputable commercial supplier. Outside metropolitan areas,
delivered either empty or partially filled, three were found to the only supplier of any type of compressed gas may be the

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
10 PART 1 Gases and Ventilation

A B C

D
Fig. 1.9 (A) Gas cylinders must never be left standing upright and unsecured. They are vulnerable to being knocked over easily, such as by opening
a door. Cylinders that fall directly to the floor, and especially cylinders that fall so that the top hits a wall (B), are at great risk for breaking at the cylin-
der neck. This creates a dangerous “unguided missile,” in which the high-­pressure gas escapes out the narrow neck and rockets the cylinder forward
with enough force to penetrate a brick wall. (C) Lightweight aluminum oxygen cylinders are now available that are filled to a maximum pressure of
3000 psig and can evolve 1000 L of oxygen at 1 atm of pressure (Linde North America, Norcross, GA). These would present an even greater hazard if
ruptured. The valve on this tank does not incorporate a pin index safety system connector because it is not designed to be placed in a hanger yoke.
The tank has a nipple for delivery of O2 at 0.25–25 L/min at low pressures to an Ambu bag, nasal cannula, etc. The cylinder also incorporates a DISS
oxygen connector that can be used to connect the tank to the machine’s oxygen pipeline inlet connector (see Fig. 2.6). (D) If upright, individual cylin-
ders should be secured in some type of holder, such as a rolling stand for E-­sized cylinders. atm, Atmosphere; DISS, Diameter Index Safety System;
psig, pounds per square inch gauge.

local welding company. Purchasing medical gases from such
TRANSPORT AND INSTALLATION
a source can be appropriate once it has been established that
this supplier meets all safety requirements and standards for Medical gas cylinders must be handled with care. As previously
the manufacture and supply of medical gases. Such verification mentioned, a broken cylinder can have serious consequences,
should be incorporated into a quality system to promote as can valve assemblies damaged by rough handling. Cylinders
maximum safety. should undergo a final inspection just before they are used. If
questions arise concerning the safety or content of a cylinder,
STORAGE it should not be used; instead, an investigation should be
undertaken before returning the cylinder to the supplier.
Specific regulations and standards govern the storage of Before a small E-­cylinder is installed in the hanger yoke, the
medical gas cylinders.2,3 For example, full cylinders and empty plastic wrapping surrounding the cylinder valve outlet must
cylinders must be stored separately, each in its own “tank room” be completely removed. If this is not done, the plastic wrapper
if possible. Small cylinders should be placed in nonflammable will prevent the gas from entering the inlet in the hanger yoke.
racks, and large cylinders should be chained to a wall. At least Furthermore, cylinders should always be opened slowly to
one anesthesiologist in each facility should be aware of these prevent dramatic heating of the suddenly pressurized piping.
requirements and how they are being implemented. Anesthesia If an abnormal odor is detected when the cylinder is opened,
caregivers should also assume responsibility for all aspects of gas should be collected from the tank and analyzed by gas
medical gas supplies. chromatography to detect hydrocarbon contamination.8 Once

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
 1 Medical Gases: Storage and Supply 11

of a medical facility is governed by standards, and the procedures
required for operating a medical gas system must be followed by
the plant engineering and maintenance departments. Problems
in the construction of gas pipelines have led to anesthesia
deaths; anesthesia providers should therefore be aware of these
standards and the gas delivery system at their facility.10 The
Medical Gas Professional Healthcare Organization (MGPHO)
was founded in 1998 as an organization that is dedicated
to advancing the safe design, manufacture, installation,
maintenance, and inspection/verification of medical gas and
vacuum systems through education. The organization is actively
involved in identifying, understanding, and maintaining state
and federal standards as well as improving the techniques used
in testing and verification.11

Fig. 1.10 Proper method for attaching an E-­cylinder to the yoke of an Medical Gas Central Supply Systems
anesthesia machine. The tank is first supported on the anesthesiologist’s
foot while the holes on the tank are aligned with the pins in the yoke. The central supply (bulk storage) system is the source of medical
The tank is then slid into place on the yoke, and the T-­handle is tight- gases distributed throughout the pipeline system. For oxygen,
ened to make a gas-­tight seal. the central supply can be a series of standard cylinders connected
by a manifold system or, for larger installations, pressure vessels
a problem is confirmed, the cylinder in question should be of liquid oxygen with accompanying vaporizers. For medical
sequestered, not returned to the supplier, and the appropriate air, the supply can be cylinders of compressed air, cylinders of
local and federal authorities contacted. oxygen and nitrogen with the gases mixed by a regulator, or air
Connections between gas cylinders and anesthesia machines compressors. In general, for nitrous oxide or nitrogen, a series of
must be tight. Fig. 1.10 illustrates the proper method for cylinders, or liquid Dewar tanks, with a manifold system is used.
balancing the tank when securing it to or removing it from the
yoke. Washers (Bodok seals) are necessary for small cylinder
OXYGEN
yokes and occasionally need replacement; the old washer must
be removed before placing a new washer. Having two washers Central supply systems that carry oxygen are both the most
in place simultaneously will create a leak and may also defeat common and the most important supply systems; as such, they
the pin index system. If a hissing noise is heard when a cylinder have received considerable attention. Standards for bulk systems
is opened, a leak is present. Tightness can always be checked that involve the storage of oxygen as a liquid are contained in
by dripping soapy water onto the connection and inspecting it NFPA Publication 55.12 Oxygen systems are extensively covered
for bubbles. A connection should never be overtightened in an in NFPA Publication 9913 and in the CSA Standard Z305.1.14
attempt to compensate for a leak; doing so may damage or even Very small systems have a total storage capacity of less than
crack the cylinder valve. As in all aspects of anesthesia practice, 2000 cubic feet (cu ft) of gas (a single H-­cylinder of oxygen
brute force is almost never appropriate. contains 244 cu ft, or 6900 L) and have additional standards
Once a new cylinder is in place, the pressure must be checked when based in nonhospital facilities. Systems in very small
on the applicable gauge. Correct pressures for full cylinders are hospitals may store oxygen in a series of standard H-­cylinders
listed in Table 1.1. Overpressurized cylinders are dangerous and connected by a manifold or high-­pressure header system. These
must be removed at once and reported to the supplier. systems typically do not have reserve supplies. In Figs. 1.11
and 1.12, note that there are two banks of cylinders; all central
Medical Gas Pipeline Systems supply systems for medical gases must be present in duplicate,
with two identical sources able to provide the needed medical
Medical gas pipeline systems consist of three main components: gas interchangeably. These are often referred to as the primary
(1) a central supply of gas, (2) pipelines to transport gases to and secondary supplies (not to be confused with the entirely
points of use, and (3) connectors at these points that connect separate reserve system).
to the equipment that delivers the medical gas. Anesthesia The larger the oxygen demand of the facility, the more
caregivers are primarily concerned with piped oxygen and complex the supply system. Most hospitals store their bulk
nitrous oxide; however, ORs may have two other medical oxygen in liquid form (Fig. 1.13), which enables the hospital to
gas supply pipelines: one for compressed air and another for maintain a large reservoir of oxygen in a relatively small space.
nitrogen to power gas-­driven equipment. One cubic foot of oxygen stored at a temperature of −297°F
Detailed standards and guidelines exist for the use of medical (−183°C) expands to 860 cu ft of oxygen at 70°F (21°C).15
gas delivery systems. In North America, these are published Because 1 cu ft is equal to 28.3 L, this amount of liquid oxygen
by the American National Standards Institute (ANSI), the provides 24,338 L at room temperature and pressure, the
American Society of Mechanical Engineers (ASME), the CGA, equivalent of 3.5 H-­cylinders of oxygen.
the National Fire Protection Association (NFPA), the Canadian Liquid oxygen is stored in a special container and kept under
Standards Association (CSA), and the American Hospital pressure. This container has an inner and outer layer separated
Association (AHA).9 In the United States, a hospital must meet by layers of insulation and a near vacuum. This construction is
the NFPA standards to be accredited by The Joint Commission similar to that of a thermos bottle and keeps the liquid oxygen
(TJC) and often to obtain insurance coverage. The construction cold by inhibiting the entry of external heat (Fig. 1.14).

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
12 PART 1 Gases and Ventilation

Line Relief Emergency
pressure valve alarm switch
regulator

Vent to outside
of building

Piping system
Main shut-off valve

Vent to outside
of building

Relief
valve
Operating
alarm switch

Operating Operating
pressure Check valve pressure
regulator regulator
Shut-off valve
High-pressure header High-pressure header

Check valve

Cylinder valve

Safety relief device

Cylinders Cylinders
(bank 1) (bank 2)
Fig. 1.11 Typical cylinder (H-­size) supply system, as would be seen in a small hospital or a freestanding facility. There is no reserve supply. (From CSA
Standard Z305.1-­1975, Nonflammable medical-­gas piping systems. Toronto, 1975, Canadian Standards Association.)

To pipeline

2200 psig 50 psig 2200 psig
Fig. 1.12 A simplified version of
Fig. 1.11. The oxygen is supplied in H-­ Primary Secondary
cylinders from both a primary and a sec-
ondary supply. The tanks are connected
by a manifold; when the tanks are full, the
pressure is 2200 psig. A changeover valve
automatically switches to the secondary
supply once the primary supply has been
exhausted. A reducing valve decreases
the pressure to 50 psig before the oxygen
enters the hospital pipeline. psig, Pounds
per square inch gauge. (Modified from
Davis PD, Parbrook EO, Parbrook GD: Ba-
sic physics and measurement in anesthe-
sia, ed 3. Oxford, UK, 1984, Butterworth- Changeover
Heinemann.) valve

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
 1 Medical Gases: Storage and Supply 13

Liquid oxygen systems must be in constant use to be cost severe burns if they come in contact with liquid oxygen or an
effective. If the system goes unused for a period of time, the uninsulated pipe carrying liquid oxygen.
pressure increases as some of the liquid oxygen boils. The Small hospitals typically require central supply systems that
oxygen is then vented to the atmosphere. The liquid oxygen store oxygen in replaceable liquid oxygen cylinders and a reserve
system contains vaporizers that heat the liquid and convert it of oxygen stored in high-­pressure H-­cylinders. The reserve
to a gas before it is piped into the hospital. Environmental and system is automatically activated when the main supply, with its
mechanical heat sources can be used to aid in vaporization. component primary and secondary storage, fails or is depleted
Liquid oxygen can be extremely hazardous, and fires are (Fig. 1.15). Hospitals of average size may store liquid oxygen
an ever-­ present danger. In addition, personnel can receive in bulk pressure vessels rather than in liquid oxygen cylinders.
The storage vessel is filled from a liquid oxygen supply truck
through a cryogenic hose designed to function at extremely low
temperatures. In such a system, the size of the reserve system
depends on the rate of oxygen use because the reserve must
constitute at least an average supply for 1 day, but preferably
2–3 days. This supply may be stored in a series of high-­pressure
H-­cylinders. However, large hospitals are required to have
a second liquid oxygen storage vessel as the reserve system
because of the impracticality of storing and connecting enough
cylinders to provide an average day’s reserve supply of oxygen
(Fig. 1.16).
Built into all these central supply systems for oxygen are a
variety of mandatory safety devices. Pressure relief valves are
designed to open if pressure in the system exceeds the normal
level by 50%. This prevents the rupture of vessels or pipes
from the excessive pressure generated by a frozen valve or a
malfunctioning pressure regulator. Alarm systems indicate
when the supply in the main storage vessel is low and when
the reserve supply has been accessed. An oxygen alarm should
activate a rehearsed protocol within the hospital that results in
contact with the oxygen supplier and subsequent verification
that an oxygen delivery is on the way.16 Pressure alarms built
into the main supply line sound when the line pressure varies by
20% in either direction from the normal operating pressure of
approximately 55 psig. Pressure alarms should also be located in
various areas in the pipeline to detect oxygen supply problems
beyond the main connection (Fig. 1.17).
All these alarm systems must sound in two different locations:
the hospital maintenance or plant engineering department
and an area occupied 24 hours a day, such as the telephone
Fig. 1.13 A typical bulk-­storage vessel for liquid oxygen. switchboard. These alarms should be periodically tested as

~85 psig
Safety
relief valve ~50 psig

Pressure
regulator
Fig. 1.14 Diagram of a liquid oxygen supply
system. The vessel resembles a giant vacuum
bottle. The liquid oxygen is at approximately
To pipeline −256°F (−160°C). Pressure inside the vessel is
Temperature Superheater maintained at approximately 85 psig. When
approximately oxygen is used from the top of the vessel, it first
256 F passes through a superheater and then through
(160 C) the pressure regulator to keep the pipeline
pressure at 50 psig. During times of rapid use,
the temperature in the tank may fall, along with
Vacuum Control the vapor pressure. The control valve causes
valve liquid oxygen to pass through the vaporizer,
which adds heat and thus maintains the pres-
Vaporizer sure in the tank. psig, Pounds per square inch
gauge. (Modified from Davis PD, Parbrook
EO, Parbrook GD: Basic physics and measure-
ment in anesthesia, ed 3. Oxford, UK, 1984,
Butterworth-­Heinemann.)

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
14 PART 1 Gases and Ventilation

Relief Reserve supply
valve operating alarm switch

Vent to outside
of building
Piping system

Operating Check Check
control unit valve valve Emergency
alarm switch
Reserve
Operating supply pressure
Secondary regulator
bank pressure pressure regulator
regulator Shut-off Main shut-off valve
Secondary supply valve
Bleeder valve operating alarm
switch Vent to outside
Operating selector of building
Shut-off valve
Check valves Relief
Pressure valve
relief Cylinder valves
device
Safety relief Line pressure
device regulator

Primary supply Secondary supply Reserve supply
(liquid cylinders) (liquid cylinders) (high-pressure cylinders)

Operating supply may
consist of one or more
supply units on each bank.
Fig. 1.15 Typical cryogenic cylinder supply system for liquid oxygen with a high-­pressure cylinder reserve supply, as would be seen in a small hospi-
tal. The redundant primary and secondary liquid cylinders are intended to be the continuous oxygen source; there is an automatic switchover to the
other bank when one is depleted and ready for replacement. The reserve supply is automatically activated when both banks of cylinders are depleted
or fail. (From CSA Standard Z305.1–92, Nonflammable medical gas piping systems. Toronto, 1992, Canadian Standards Association.)

part of a regular maintenance program because failure of such by concentrators is approximately 90%–96%, with the balance
alarms has led to crisis situations. Testing the various alarms made up mostly of argon.18,19
can be difficult but is possible if the system is properly designed. Oxygen concentrators are commonly used in remote
Another critical safety feature is the T-­fitting located at the locations and developing countries, but in some cases they
point where the central supply system joins the hospital piping have been configured to supplement a hospital’s existing liquid
system. This fitting allows delivery of an emergency supply of oxygen system as a reserve or a secondary supply.18 Oxygen
oxygen from a mobile source in the event of extended failure, concentration may vary with gas flow, and concentrators are
extensive repair, or modification of the hospital’s central supply. most effective at delivering oxygen at flows of less than 4 L/
The location and housing of oxygen central supply systems min to anesthesia machines.19 Accumulation of argon may
are governed by strict standards.12 A bulk oxygen storage occur, however, in low-­flow conditions, so the use of an oxygen
unit should be located away from public areas and flammable monitor is essential.20 As the current emphasis on cost cutting
materials. in medical care continues, along with cost increases of supplied
liquid and gaseous oxygen, oxygen concentrators are likely to
come into wider use.
OXYGEN CONCENTRATORS
The use of oxygen concentrators to deliver oxygen to the MEDICAL AIR
anesthesia circuit has gained attention recently. Oxygen is
generated by the selective adsorption of the components of air The central supply of medical air can come from three sources:
with molecular sieve technology. These sieves consist of rigid (1) cylinders of compressed air that have been cleaned to
structures of silica and aluminum, with additional calcium or medical quality by filtration distillation; (2) a proportioning
sodium as cations.17 Air is forced through the sieves under system (relatively uncommon) that receives oxygen and
pressure, and oxygen and nitrogen are generated. The oxygen nitrogen from central sources, mixes them in a proportion of
is then used clinically, and the nitrogen is vented to the 21% oxygen to 79% nitrogen, and delivers this mixture to the
atmosphere. The maximum oxygen concentration produced medical air pipeline (these systems usually have compressed air

Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
 3

A

B
3
24
19
20
23 2 Fig. 1.16 Typical bulk supply system for
24 oxygen, as would be seen in a large hospital.
4 Very large hospitals may require more than
23
one system of this magnitude. (A) Main liquid
1
4 oxygen reservoir; (B) reserve liquid oxygen
7 3 reservoir. 1, Connection to supply vehicle;
2, top and bottom fill lines; 3, reservoir pres-
5 5
3 sure relief valves; 4, “economizer” circuit; 5,
6 6 7 gas regulator in pressure-­building circuit; 6,
pressure-­building vaporizer; 7, liquid regula-
17 tor in pressure-­building circuit; 8, cryogenic
liquid-­control valves; 9, liquid vaporizers; 10,
10 downstream valves for isolation of vaporiz-
ers; 11, primary line pressure regulator; 11a,
9 8 secondary line pressure regulator; 11b, valves
to isolate regulators for repair; 12, pressure
18 relief valve for main pipeline; 13, reserve
system liquid vaporizer; 14, reserve system
9 8 line pressure regulator; 15, gas flow check
valves; 16, reserve system “economizer” line;
13 17, reserve system fill line; 18, valve control-
10 12 ling flow to reserve system from main cylin-
14 15 der; 19, low liquid level alarm; 20, reserve in
use alarm; 21, main line pressure alarm; 22,
11a main shut-­ off valve and T-­ fitting; 23, liquid
11b 11b level indicators; 24, vapor or “head” pressure
gauges. In normal operation, liquid oxygen
11 21 flows from the lower left of the main vessel (A)
16
via a cryogenic pipe through valves (8) and to
the vaporizer (9), where the liquid becomes
gaseous oxygen. It then flows through pres-
sure regulators (11) and hence into the supply
22 pipeline to the hospital. (From Bancroft ML,
du Moulin GC, Hedley-­Whyte J: Hazards of
bulk oxygen delivery systems. Anesthesiol-
To hospital ogy 1980;52:504-­510.)

A B
Fig. 1.17 (A) Bank of pressure gauges that monitor the gases in one zone of the operating room. These gauges are for oxygen, air, and vacuum.
Note that the rooms being monitored are identified on the top of the panel. (B) A second gas monitoring panel for nitrous oxide, nitrogen, carbon
dioxide, and waste gases. Note that colored lights indicate whether the line pressures are in the normal range; alarms are triggered for high or low
pressures.
Downloaded for Vicente Gonzalez ([email protected]) at Florida International University from ClinicalKey.com by Elsevier on
September 05, 2024. For personal use only. No other uses without permission. Copyright ©2024. Elsevier Inc. All rights reserved.
16 PART 1 Gases and Ventilation

cylinders or an air compressor as a reserve system); and (3) air The condensed water is then properly disposed of to eliminate
compressors (Fig. 1.18), the most common source of medical air potential breeding grounds for bacteria, such as those that
in hospitals. The compressor works by compressing ambient air cause Legionnaires’ disease. Valves, pressure regulators, and
and then delivering the pressurized air to a reservoir or holding alarms analogous to those in oxygen supply systems are needed.
tank.15 The medical air is then fed to the pressure regulator and In addition, the piping should not be exposed to subfreezing
travels from there to the hospital piping system. temperatures.
Air compressor systems are subject to rigorous standards.13,14
As with other systems (i.e., vacuum or electric generators), NITROUS OXIDE
redundancy is important. Duplicate compressors are necessary,
each with the capacity to meet the entire hospital’s medical Specific standards exist for nitrous oxide systems, and certain
air needs if the other fails. The system must be used only for portions of the more general standards of the NFPA and CSA
the medical air pipeline and not for the purpose of powering are applicable as well.21 A nitrous oxide central supply system
equipment. If air is to be used for powering equipment, a separate may be warranted, depending