Class 3_Storage and Distribution Pt 1_BB_F 2024.pptx

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Storage and Distribution of
Medical Gases

Hess Chapter 13
 Infection Control: Review
Questions

You are treating a patient with well-controlled asthma. What level of precautions should
a respiratory therapist observe?

A. Airborne
B. Contact
C. Standard
D. Universal
E. None since asthma is a non-infectious disease.
 Infection Control: Review
Questions

A respiratory therapist is about to enter the room of a patient who has MRSA. What
personal protective equipment should the therapist put on first?

A. Gloves
B. Goggles
C. Gown
D. Mask
 Infection Control: Review
Questions

A 10-year-old boy has been brought into the hospital with measles. To avoid airborne
transmission of the disease to other children on the ward, where should the patient be
placed?

A. In an airborne infection isolation room
B. In a private room
C. In a multi-patient ward
D. In quarantine at home
 Infection Control: Review
Questions

According to the Centers for Disease Control and Prevention, how often should ventilator
circuits be changed?

A. Daily
B. After a week
C. Every 2 weeks
D. Once a month
E. When there is visual or known contamination
 Infection Control: Review
Questions

All of the following are common routes of disease transmission, except:

A. Walking and talking.
B. Droplet and airborne.
C. Vehicle and indirect.
D. Vector and direct.
 Infection Control: Review
Questions

Airborne transmission occurs by the spread of evaporated droplet nuclei smaller than:

A. 0.5 µm.
B. 5 µm.
C. 1 µm.
D. 3 µm.
What do
you think
this is?
 Storage and Distribution

As a respiratory care practitioner, you
will be expected to know how to safely
utilize the various medical gas supply
systems available in your institution.

With the main focus on Oxygen
Delivery Systems.
 Storage and Distribution

When used appropriately, these
systems are safe and effective.

If mishandled, they can be potentially
lethal.
 Storage and Distribution

These supply systems include medical
gas cylinders, medical gas piping
systems, liquid systems, and oxygen
concentrators.
 MEDICAL GAS
CYLINDERS

Cylinders manufactured for the
transport of medical gases are
constructed in accordance with
regulations specifically established by
the Department of Transportation
(D.O.T.).
 MEDICAL GAS
CYLINDERS
Medical Gas Cylinders are generally
constructed from seamless steel meeting
chemical and physical requirements.

Cylinders are constructed by either spinning
or stamping a flat sheet into the proper
shape. Following construction, cylinders are
heat treated to retain the steel’s tensile
strength.
 Cylinder Markings
To be in compliance with D.O.T. regulations,
all gas cylinders are required to have
specific markings permanently stamped
onto the upper shoulder of the tank/cylinder.

The first marking stamped on the shoulder
of a medical gas cylinder is “DOT 3AA.” This
indicates that the cylinder meets the D.O.T.
standards for 3AA-type compressed gas
cylinders.
 Markings and
Identification

The letters DOT (or ICC if prior to 1968)
are followed by the cylinder
classification and the normal filling
pressure in pounds per square inch.

Information about the original safety
test and subsequent test.
 Markings and
Identification

Safety test must occur every 5 to 10
years according to DOT Regulations

During safety test, Cylinders are
pressurized to 5/3’s of their service
pressure.
 Markings and
Identification

EE followed by a number indicates the
cylinder’s elastic expansion in cubic meters
under the 5/3’s test condition.

The star symbol next to the test date
indicates DOT approval for 10-year testing
and approved for filling 10% above service
pressure of 2015 psi.
Markings
and
Identificatio
n
 Common Medical Gas
Cylinder Sizes
The two most common medical gas cylinder
sizes encountered in the clinical setting are
the “E” and “H.”

Size E through AA are referred to as small
cylinders.

Sizes G and above are large Cylinders.
CYLINDER SIZES

H

E

H
COLOR CODES
Table 37 -2
 Compressed Gas
Cylinders
For gas-filled cylinders, the volume of gas in
the cylinder is directly proportional to its
pressure at a constant temperature.

If a cylinder is full at 2200 psig, it will be half
full when the pressure drops to 1100 psig.
Thus, in order to know how much gas is
contained in a compressed gas cylinder, you
need only measure its pressure.
 Pressurized Cylinders

Temperature of 70F or 21.11C
H cylinder 244 cubic ft., 6,900 liters,

weight of O2 20lbs. 2200psig
E cylinder 22 cubic ft., 622 liters, weight

of O2 2 lbs. 2200psig (pressure square
 Liquid Gas Cylinders
The measured pressure is the vapor
pressure above the liquid. This
pressure bears no relationship to the
amount of liquid remaining in the
cylinder.

The only accurate method to determine
the contents of a liquid-filled cylinder is
to weigh it.
 Liquid Oxygen
Systems
1 cubic foot of liquid oxygen equals 860
cubic feet of gas, enabling liquid oxygen
systems to store large quantities of oxygen
in small spaces.

To keep oxygen in liquid form, it is stored in
large stand tanks at relatively low pressure
(less than 250 psig). These stand tanks are
like a giant thermos bottle, consisting of
inner and outer steel shells separated by
an insulated vacuum chamber.
Liquid O2
Storage
Tanks
Liquid Oxygen Systems
Liquid O2
System for Home
Use
 Liquid Oxygen Systems
Liquid oxygen must continually be stored
below -181.1 F or -118.8 C

When the liquid oxygen flows through
vaporizer coils exposed to ambient
temperature, it quickly converts back to a
gas to the standard working pressure of 50
psi by a pressure reducing valves.

A safety vent allows vaporized liquid oxygen
to escape
 Cylinder Valves and
Cylinder Valve Safety
Systems
Due to the high pressure
contained in a medical gas
cylinder, a device is required to
contain the gas and to provide
a point of attachment for
equipment.

These devices are termed
cylinder valves. The cylinder
valves are located at the top of
the cylinder and are of two
types: direct-acting or
diaphragm.
Cylinder Valves
 Safety Systems
In a closed cylinder, any rise in gas
temperature will increase gas pressure.

Should the temperature increase too much
(as in a fire), the high gas pressure could
rupture and explode the cylinder

To prevent this type of accident, all cylinders
incorporate high-pressure relief valves.
 Relief Valves
There are three basic designs: frangible
disk, fusible plug, and spring loaded.
 Relief Valves
The fusible plug is made from a metal
with a low melting point.

If the temperature rises beyond the
melting point of the metal plug, the
plug melts and releases the pressure in
the cylinder.
Intentionally Left
Blank
 Safety System
One of the greatest risks in medical gas
therapy is giving the wrong gas to a patient.
Careful reading of cylinder or outlet labels is
the best way to avoid these accidents.

A safety system was designed by the
Compressed Gas Association to prevent the
interchange of cylinders and possibly
delivering the wrong gas.
 Safety System

There are two safety systems designed
to prevent the interchange of cylinders
containing different gases: one for
large cylinders and one for “E”
cylinders and other small cylinder
sizes.
 Safety System
This system was formally adopted by
the American Standards Association
and called American Standard
Indexing, or American Standard Safety
System (ASSS)
 ASSS

American
Safety
Standard
System
 Safety System Large
Cylinders
The large cylinder safety system consists of
different thread sizes and pitches and both
internal and external threading.

In addition to the safety system described
above, large medical gas cylinders have a
protective cap that covers the cylinder valve.
This cap is threaded and matches threads on
the cylinder shoulder just below the valve.
 Safety System Small
Cylinders
Small cylinders valves utilize a yoke
connection rather than a threaded
connection for equipment attachment.

The face of the cylinder valve has two holes
drilled in two of six specific positions.

This system is commonly known as the Pin
Index Safety System (PISS).
 Safety Indexed
Connector Systems

Three basic indexed safety systems
involved in the delivery and regulation
of medical gases:
(1) American Safety Standard System - ASSS for
short;
(2) Pin-Index Safety System (PISS);
(3) Diameter-Index Safety System (DISS)
 Diameter Index Safety
System
The PISS and ASSS systems are designed for use on
high-pressure cylinders. In contrast, the Diameter
Index Safety System (DISS) was designed by the
CGA for low-pressure (0 - 200 psig) connections and
fittings. (CGA = Compressed Gas Association).

DISS utilizes specific diameter-threaded male outlets
that mate with a corresponding female nut and nipple.

Different diameters, thread pitch, and nipple
configurations are assigned to various gases and gas
mixtures.
Diameter-Index Safety
System (DISS)
Oxygen –
Always
Green.

Air –
Always
Yellow.
Pin-Index Safety System
(PISS)
If it has
threads it is
ASSS

ASSS
Flow Meter
with a 50
psig
Outlet.
 Obtaining the Cylinder
from Storage

Large medical gas cylinders are stored
along a wall where, for optimal safety,
chains or straps are provided to secure the
cylinders to the wall.

The safety chains will prevent the cylinders
from accidentally falling from the upright
position
 Maneuvering Large
Medical Gas Cylinders
An oxygen “H” cylinder weighs
approximately 126 pounds when full.

Care must be exercised when handling this
much weight concentrated in a relatively
small package.

Besides the weight factor, the pressure in a
full cylinder, if mistreated, could cause
serious injury.
 Transporting the
Cylinder and Cart
To transport the cylinder and cart, place
one hand on the safety cap over the
cylinder valve and the other hand on
the handle of the cart.

Push the cylinder and cart in front of
you while keeping a sharp eye out for
other personnel, objects, or hazards.
 Cracking the Cylinder
Before attachment of any equipment to
a cylinder, the cylinder valve must be
cracked. Cracking the cylinder removes
any dust, or particulate matter, from
the outlet of the cylinder valve.
 Cracking the Cylinder

When a cylinder is cracked, 2200 psi exiting
through the narrow opening of the cylinder
valve makes a very loud hissing noise. The
sudden noise is enough to sufficiently
startle anyone.
Give Warning, “Cracking.”
And wear Safety Googles to avoid getting
debris in your eyes.
 Cracking the Cylinder
Respiratory care practitioners must
ensure that any oil or dust is cleared
from high-pressure medical-gas
delivery systems before
pressurization. Why is this action
needed?
Adiabatic compression could
ignite the oil or dust.
 E !
T I M
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