medical piped system design

Types of medical gas systems

There are two basic types of medical gas systems, namely:

unilateral system:

It is a system that is the pressure to reduce medical gas pressure required at the exits and the beginning of the main station for the supply of various gases.

 binary system:

It is a system that reduce pressure medical gas which is in two phases the first phase takes place in the main station to the top of the exits at the desired pressure and then pressure is then pressure reduction phase

Components of medical gas system

Medical gas systems consist of the following elements:

sources of supply plants or various medical gases.

Distributed gas piping network.

exits medical gases.

 monitoring and warning system.

sources of supply stations and various medical gases

Are sources that supply piping system various medical gases and this element is also divided into several elements are as follows:

• the supply of medical gas cylinders through the station.

• the supply of compressed air station through the air compressors.

• suction through suction pumps station.

First: medical gas supply station through the cylinder

It is designed to extend hospital departments and medical gases (oxygen, nitrous oxide, carbon dioxide, nitrogen). Overall cylinder station consists of two rows of cylinders equal, one of these two grades be in working condition while the other shall be the primary alternative to the class when emptied Alostoanat.oicon automatically switch between grades through autoomatic switch the possibility of switching from row to row the other hand. It must be designed so that the station does not stem the tide of medical gas at the service station or maintenance.

May use liquefied oxygen tanks in large hospitals or when a large consumption rate. Oxygen tanks are insulated tanks containing thousands Turat of liquefied oxygen when evaporation produces oxygen gas multiplier hundreds of times the size of its size it is liquefied. These tanks are placed in special places and each tank there and from which you can fill the empty tin when its piping system, 

Second: The compressed air supply station through the air compressors

Unlike other medical gases, which are supplied through the cylinder, the medical compressed air is usually Antiajh in the hospital itself and that is through the payment of external atmospheric air into the air compressors, which are linked to a network of pipes that supply the various medical departments air after treatment in order to comply with the air specifications Medical where the following conditions must be in the compressed medical air and the output of the station are available:

• oils ratio does not exceed 0.5 mg per cubic meter.

• dew degree of not less than 5 degrees down less unexpected degree of operating temperature.

• Carbon monoxide ratio does not exceed 5 ml per cubic meter.

• carbon dioxide ratio does not exceed 1 000 ml per cubic meter.

Third, the suction through suction pumps station

Suction station of three or more suction pumps consists, tank or more, two or more filters bacteria, a jar exchange or more in addition to the unit for the station control. It must be suction abroad exchange station away from the neighboring buildings and the direction of the wind away from neighboring buildings.

Distributed pipes for gas network

Piping system used for the transmission and distribution of medical gases from gas stations to the exits of the various sections, taking into account the following:

• pipes must bear the pressure equivalent to 1.2 of the maximum possible pressure.

• flexible connections may be used as part of the network so as to prevent transmission of vibration.

• You must reach your piping system grounded in hospital.

• must be the protection of piping system from damage that may result from the collision devices such as Alterolliat and dispute.

• must prove pipes pillars so as not bend or bows out.

• props must be made of corrosion resistant material.

• should not be used for any special props pipes other uses.

•

Portable Air Compressors - Mobile & Portable

(1) SAFETY RELIEF VALVE Every ROLAIR air compressor is equipped with a safety relief valve which is designed to

discharge tank pressure at a predetermined setting when a systems failure occurs. Check the safety valve periodically by

pulling on the ring only when the tank pressure is completely drained. The spring loaded valve should move freely within the

safety valve body. An inoperable safety valve could allow an excessive amount of tank pressure to build causing the air tank to

catastrophically rupture or explode.

Do not tamper with or attempt to eliminate the safety relief valve.

(2) MANUAL OVERLOAD / MOTOR RESET Every ROLAIR electric air compressor is built with manual overload protection. If

the motor overheats, the overload sensor will trip the reset button to protect the motor. If this occurs, please allow the motor to

cool for approximately five minutes. Locate and push in the reset button. The use of an undersized or excessive length of

extension cord may be the cause of overheating. Re-evaluate the power source and gauge/length of extension cord being

used. (Refer to chart on page 8)

(3) PRESSURE SWITCH Most electric air compressors are operated by the use of a pressure switch. Always make sure

the lever is in the off position before plugging in the power cord. By moving the lever to the “On/Auto” position, the compressor

will start and stop automatically within the settings of the pressure switch which are typically 105 – 130 PSI. Do not attempt to

stop the compressor by unplugging the power cord. To stop, simply move the lever to the “Off” position. The lever operates a

relief valve that dumps off head pressure and allows the compressor to restart without load the next time it is used.

(4)REGULATOR – WORKING PRESSURE To adjust the output/line pressure, simply lift up on the regulator adjustment knob

and rotate clockwise to increase working pressure or counter-clockwise to decrease. Push adjustment knob back down to lock

in setting. Never exceed the manufacturer’s maximum allowable pressure rating of the tool being used or item being inflated.

(5) PRESSURE GAUGE(S) Typically, most compressors are designed with a gauge to measure tank or storage pressure

and another gauge attached to the regulator that indicates output or working pressure.

(6) DRAIN VALVE(S) One or more drain valves are installed to allow moisture to be drained on a daily basis from the

compressor storage tank(s). Open drains carefully and slowly to prevent scale, rust, or debris from becoming expelled at a

high rate of speed.

(7) AIR INTAKE FILTER Air intake filters are installed to prevent foreign matter from entering into the engine or

compressor pump. Check intake elements on a regular basis and either clean or replace as needed. Warm soapy water or

low compressed air may be used to clean the elements. Check intake canisters or elbow components for cracks or broken

seals and replace if structural problems are found.

centrifugal pump

A centrifugal pump

converts input power to kinetic energy by accelerating liquid in a revolving device - an impeller.

The most common is the volute pump - where fluid enters the pump through the eye of the impeller which rotates at high speed. The fluid accelerates radially outward from the pump chasing and a vacuum is created at the impellers eye that continuously draws more fluid into the pump.

The energy from the pumps prime mover is transfered to kinetic energy according the Bernoulli Equation. The energy transferred to the liquid corresponds to the velocity at the edge or vane tip of the impeller. The faster the impeller revolves or the bigger the impeller is, the higher will the velocity of the liquid energy transferred to the liquid be. This is described by the Affinity Laws.

Pressure and Head

If the discharge of a centrifugal pump is pointed straight up into the air the fluid will pumped to a certain height -  or head - called the shut off head. This maximum head is mainly determined by the outside diameter of the pump's impeller and the speed of the rotating shaft. The head will change as the capacity of the pump is altered.

The kinetic energy of a liquid coming out of an impeller is obstructed by creating a resistance in the flow. The first resistance is created by the pump casing which catches the liquid and slows it down. When the liquid slows down the kinetic energy is converted to pressure energy. 

• it is the resistance to the pump's flow that is read on a pressure gauge attached to the discharge line

A pump does not create pressure, it only creates flow. The gauge pressure is a measurement of the resistance to flow.

In fluids the term head is used to measure the kinetic energy which a pump creates. Head is a measurement of the height of the liquid column the pump could create from the kinetic energy the pump gives to the liquid. 

• the main reason for using head instead of pressure to measure a centrifugal pump's energy is that the pressure from a pump will change if the specific gravity (weight) of the liquid changes, but the head will not

The pump's performance on any Newtonian fluid can always be described by using the term head. 

Different Types of Pump Head

• Total Static Head -  Total head when the pump is not running
• Total Dynamic Head (Total System Head) - Total head when the pump is running
• Static Suction Head - Head on the suction side, with pump off, if the head is higher than the pump impeller
• Static Suction Lift - Head on the suction side, with pump off, if the head is lower than the pump impeller
• Static Discharge Head - Head on discharge side of pump with the pump off
• Dynamic Suction Head/Lift - Head on suction side of pump with pump on
• Dynamic Discharge Head - Head on discharge side of pump with pump on

The head is measured in either feet or meters and can be converted to common units for pressure - like psi, Pa or bar.

• it is important to understand that the pump will pump all fluids to the same height if the shaft is turning at the same rpm

The only difference between the fluids is the amount of power it takes to get the shaft to the proper rpm. The higher the specific gravity of the fluid the more power is required.

• Centrifugal Pumps are "constant head machines"

Note that the latter is not a constant pressure machine, since pressure is a function of head and density. The head is constant, even if the density (and therefore pressure) changes.

The head of a pump can be expressed in metric units as:

h = (p₂ - p₁) / (ρ  g) + v₂² / (2 g)         (1)

where

h = total head developed (m) 

p₂ = pressure at outlet (N/m²)

p₁ = pressure at inlet (N/m²)

ρ =   density (kg/m³)

g = acceleration of gravity (9.81)  m/s²

v₂ = velocity at the outlet (m/s)

Head described in simple terms

• a pump's vertical discharge "pressure-head" is the vertical lift in height - usually measured in feet or m of water - at which a pump can no longer exert enough pressure to move water. At this point, the pump may be said to have reached its "shut-off" head pressure. In the flow curve chart for a pump the "shut-off head" is the point on the graph where the flow rate is zero

Pump Efficiency

Pump efficiency, η (%) is a measure of the efficiency with wich the pump transfers useful work to the fluid. 

η = P_out / P_in  (2)

where 

η = efficiency (%)

P_in = power input

P_out = power output  

hvac system

Air Conditioning

Air Conditioning systems - heating, cooling and dehumidification of indoor air for thermal comfort

Heating

Heating systems - capacity and design of boilers, pipelines, heat exchangers, expansion systems and more

Noise and Attenuation

Noise is usually defined as unwanted sound - noise, noise generation, silencers and attenuation in HVAC systems

Ventilation

Systems for ventilation and air handling - air change rates, ducts and pressure drops, charts and diagrams and more

Acoustic Calculation of Ventilation Systems

Procedure for acoustic noise calculation of ventilation systems

Air-Duct Sizing

Air flow and required duct area

Calculating Indoor Temperature and Humidity Loads

Calculating sensible and latent heat from persons, lights, electric equipment, machines, evaporation from water surfaces, polluting fluids and miscellaneous loads

Dehumidification - Removing Moisture from Air

Principles of dehumidifying - cooling, adsorption or absorption

Fuels - Combustion Air and Flue Gases

Combustion air and flue gas for common fuels - coke, oil, wood, natural gas and more

Fuels - Exhaust Temperatures

Exhaust and outlet temperatures for some common fuels - natural gas, liquefied petroleum, diesel and more

Fuels - Higher Calorific Values

Higher calorific values for some common fuels - coke, oil, wood, hydrogen and others

Fuels and Chemicals - Auto Ignition Temperatures

The ignition point for some common fuels and chemicals butane, coke, hydrogen, petroleum and more

Sponsored Links

HVAC Diagram - Online Drawing

Draw HVAC diagrams - Online with the Google Drive drawing tool

HVAC Terms

Definition of some common HVAC industry terms - absolute humidity, pressure, temperature and more

Heat, Work and Energy

Heat, work and energy tutorial - essentials as specific heat

Humidifying Air with Steam - SI units

Use steam to humidify air

Introduction to Psychrometry

An introduction to air psychrometrics

Maximum Duct and Pipe Sizes through Steel Joists, K-series

Lubrificação Compressor

Lubrificação Compressor

5.28 Compressores isentos de óleo têm sido utilizados com sucesso em cirurgias dentárias,

e evitar a necessidade de separadores de óleo e filtros. Cuidados devem, no entanto, ser

tomadas para garantir que os anéis de PTFE e óleos lubrificantes não se tornem excessivamente

quente. Um sensor de temperatura pode ser equipado com controlos adequados para cortar o

fonte de alimentação em caso de excesso de temperatura.

Tratamento do ar

5.29 Os contaminantes podem entrar nos sistemas de ar comprimido de três

fontes: a atmosfera, o compressor eo sistema de distribuição de gasoduto.

Cada fonte de potencial deve ser tida em conta quando se especifica o tipo

e localização de equipamentos de tratamento de ar.

5,30 Um filtro de entrada de ar 5 micron é necessária para impedir o bloqueio de interno

separadores de ar / óleo.

5,31 Água é sempre um contaminante em um sistema de ar comprimido, independentemente

do tipo e da localização das instalações de compressor, uma vez que o ar aspirado para dentro do

ingestão de compressor nunca está completamente livre de vapor de água.

5.32 O reservatório deve ser revestido internamente para minimizar a produção de ferrugem.

5.33 um teor de água não deve exceder um ponto de condensação de -20 ° C a atmosférica

pressão é recomendado, a fim de evitar estes problemas.

5,34 Isto pode ser difícil de alcançar na prática, com um secador de refrigeração,

e, por conseguinte, secador dessecante deve ser usado.

5.35 O secador pode ser localizado quer a montante quer a jusante do ar

receptor, dependendo da concepção do sistema.

5,36 Para pequenas instalações, pode haver vantagens em localizar o secador

a montante do receptor, a fim de assegurar que o reservatório de ar não é

contaminada com ar húmido e o ar seco que a partir do receptor pode ser usado

de se regenerar o secador.

5,37 Se o secador está localizado a jusante do receptor, o receptor actua

como um pós-resfriador secundário e também suaviza o efeito de um pulsar

alternativo bomba. Isto pode ser adequado para instalações de maiores dimensões.

5.38 O sistema de secagem deve ser equipado com um higrômetro para continuamente

monitorar a secura do ar comprimido e desligar automaticamente o

sistema em caso de excesso de humidade.

5.39 Um alarme deve ser instalado para indicar alto teor de umidade. Para o

sistema menor pode ser mais apropriado para esta condição de alarme, em vez de

desligar automaticamente o sistema, o que pode ser inconveniente. O orvalho

ponto pode subir a uma pressão de ponto de orvalho de + 3 ° C, antes de o sistema deve

alarme. Detalhes de alarmes são apresentadas nos pontos 5.47-5.49.

5,40 Um sistema típico com o secador localizado a montante do receptor é

mostrado na Figura 2.

Um secador de refrigerante pode ser

adequado em pequenas instalações, que

é, menos de 2/3 cadeiras, fornecida

que o comprimento de pipeworki externo

Lubrificazione del compressore

Lubrificazione del compressore
5.28 Compressori privi d'olio sono state utilizzate con successo negli studi odontoiatrici,
e ovviare alla necessità di separatori di olio e filtri. Si deve, tuttavia, essere
adottare per garantire che gli anelli in PTFE e oli lubrificanti non diventino eccessivamente
caldo. Un sensore di temperatura può essere dotato di opportuni controlli per tagliare il
alimentazione in caso di temperatura eccessiva.
Trattamento aria
5.29 contaminanti possono entrare nei sistemi ad aria compressa da tre
fonti: l'atmosfera, il compressore e il sistema di distribuzione conduttura.
Ogni sorgente potenziale deve essere preso in considerazione quando si specifica il tipo
e ubicazione delle apparecchiature di trattamento dell'aria.
5.30 Un filtro di aspirazione dell'aria 5 micron è necessaria per impedire il blocco di interno
separatori aria / olio.
5.31 acqua è sempre un contaminante in un sistema ad aria compressa, indipendentemente
del tipo e la posizione del sistema di compressione, dato che l'aria aspirata nel
aspirazione del compressore è mai completamente privo di vapore acqueo.
5.32 Il serbatoio deve essere rivestito internamente per ridurre al minimo la produzione di ruggine.
5.33 Un contenuto di acqua non superiore al punto di rugiada di -20 ° C in atmosfera
pressione è consigliabile per evitare questi problemi.
5.34 Questo può essere difficile da ottenere in pratica con un essiccatore a refrigerazione,
e quindi dovrebbe essere usato essiccatore.
5.35 L'essiccatore può essere posizionato a monte oa valle dell'aria
ricevitore a seconda del progetto del sistema.
5.36 Per le piccole installazioni, ci possono essere dei vantaggi per la localizzazione del dryer
monte del ricevitore in modo da garantire che il ricevitore aria non è
contaminato con aria umida e che l'aria secca dal ricevitore può essere utilizzato
per rigenerare l'essiccatore.
5.37 Se l'asciugatrice si trova a valle del ricevitore, il ricevitore agisce
come un secondario aftercooler e leviga anche l'effetto di un pulsante
alternativo pompa. Questo può essere opportuno grandi installazioni.
5.38 Il sistema essiccatore deve essere dotato di un igrometro a continuamente
monitorare la secchezza dell'aria compressa e di chiudere automaticamente la
sistema in caso di eccessiva umidità.
5.39 Un allarme deve essere installato per indicare elevato contenuto di umidità. Per il
sistema più piccolo può essere più appropriato per questa condizione di allarme, piuttosto che
spegnendo automaticamente il sistema, che può essere scomodo. La rugiada
punto può salire ad una pressione del punto di rugiada di + 3 ° C prima che il sistema dovrebbe
allarme. Dettagli di allarmi sono riportati nei paragrafi 5.47-5.49.
5.40 Un tipico sistema con l'essiccatore a monte del ricevitore è
illustrato nella figura 2.
Un essiccatore refrigerante può essere
appropriato in piccoli impianti, che
è, meno di 2/3 sedie, a condizione
che la lunghezza di pipeworki esterna

medical air system

S

S

S

Areas of Application

• ICU ventilators

• Anaesthesia machines

• Infant ventilators

• Various medical devices

Requirements for Compressed Medical Air According to ISO 8573

• Oil free

• Water mist free

• Clean – no particles larger than 0.1 µm

• Bacteria free

The imtmedical Solution

aeris is the only compressor in its class using the Triple Filter System to fiter out residual water, oil, mist,

droplets and other particulate matter. Additional fiters, as well as an active carbon cartridge, ensure that the fier

molecules (> 0.01 micron) are trapped while the carbon cartridge 

absorbs hydrocarbon and odors.

Design and construction of cylinder stores

General

8.11 Cylinder stores should be covered and adequately ventilated. Stores

should not be located in close proximity to any installation which may present

a fire risk or other hazard.

8.12 The floor and hard standing should be level and constructed of

concrete or other non-combustible, non-porous material. A concrete finish is

preferred and is likely to have a longer life. The floor should be laid to a fall to

prevent the accumulation of water.

8.13 The store should have easy access for trolleys. The cylinder bays should

be arranged to allow trolleys to be safely manoeuvred and cylinders to be

loaded and unloaded.

8.14 Separate, clearly identified bays should be provided for full and empty

cylinders.

8.15 Separate areas for different gases should be provided, but it is not

necessary to construct a physical barrier unless it is convenient to do so.

Adequate means of securing large cylinders should be provided to prevent

falling. Small cylinders should be secured in racks in accordance with BS 1319.

8.16 The doors should be large enough to facilitate cylinder

loading/unloading and should be on an external wall. The emergency exit

should be provided with a panic-release lock. Doors should open outwards.

35

Hazchem/warning signs

8.18 Safety warning signs and notices should be used where appropriate

and posted in prominent positions. They should be sited and designed in

accordance with the requirements of SI 1980 No 1471 ‘The Safety Signs

Regulations 1980’; BS 5378: Part 1: 1980, Part 3: 1982 ‘Safety Signs and

Colours’; BS 5499: Part 1: 1984 ‘Fire Safety Signs Notices and Graphic

Symbols’ and the Health and Safety at Work etc Act 1974.

Location

8.19 Cylinder stores should be located at ground level, not underground, for

example in a basement.

8.20 Cylinder stores should be located as close as possible to the delivery

point. Wherever possible there should be only one delivery supply point for

each site.

8.21 No parking should be permitted within the delivery and storage area,

other than for loading and unloading cylinders.

8.22 The location of the cylinder store should be marked clearly on the site

plan for ease of identification in the event of an emergency.

Handling of cylinders

General

8.23 Cylinders can be heavy and bulky and should therefore be handled with

care only by personnel who have been trained in cylinder handling and who

understand the potential hazards.

8.24 A suitable trolley should be used for transporting cylinders whenever

they are moved.

8.25 Cylinders should not be lifted by their guards or valves unless

specifically designed for that purpose.

8.26 Cylinders should not be dropped, knocked, used as “rollers” or be

permitted to strike each other violently.

8.27 Cylinders and valves should be kept free from oil, grease and other

debris. Cylinders should not be marked with chalk, crayon, paint or other

materials, nor by the application of adhesive tapes etc. A tie-on label indicating

the content state may be attached to the cylinder.

8.28 Smoking and naked lights should be prohibited in the vicinity of all

cylinders.

8.29 Cylinders should always be secured during transportation and in use

Precautions against fire, heat and chemicals

8.55 General fire precautions applicable to MGPS are given in the “Fire

precautions” section of Chapter 9 “General safety and fire precautions”.

8.56 Oil and grease in the presence of high-pressure oxygen and nitrous

oxide are liable to combustion and should not be used as a lubricant on any

gas cylinder or equipment. In particular, the cylinder valve, couplings,

regulators, tools, hands and clothing should be kept free from these

substances.

8.57 A hazardous situation could arise if cylinders are subjected to extremes

of temperature. Cylinders should be kept away from sources of heat,

including steam pipes and hot sunny positions.

8.58 When equipment is coupled to a cylinder, the cylinder valve should

initially be opened as slowly as possible, as rapid opening can cause a sudden

adiabatic increase in downstream gas pressure. The consequent temperature

rise may result in ignition of combustible material in contact with the hot gas

downstream. Only regulators designed for oxygen use should be used for this

service a s they are constructed to prevent this occurrence.

8.59 Serious incidents have occurred as a result of ignition occurring within

the cylinder valve or regulator. This has been attributable to friction generated

by particulate matter, such as dust or dirt, within the system when the

cylinder valve is opened.

8.60 Cylinders and their associated equipment should be protected from

contact with oil, grease, bituminous products, acids and other corrosive

substances.

Storage of cylinders in manifold rooms

The number of cylinders in manifold rooms should be restricted to the

minimum required for operational and reserve purposes. This will include

cylinders connected to the manifold(s) and a sufficient reserve to replenish one

complete bank. In the case of manifolds for nitrous oxide/oxygen mixtures,

sufficient cylinders to replace two complete banks should be stored.

8.63 Only cylinders of the gases required for connection to the manifold

should be kept in the manifold room. The manifold room should not be used

for any other purpose, although an exception may be made for essential

storage of nitrous oxide/oxygen mixture cylinders on trolleys to permit

temperature equilibration before use with directly connected equipment.

Storage of cylinders in ready-to-use stores

8.64 In some areas it will be essential to hold small numbers of spare

cylinders for immediate use for connection to anaesthetic machines and for

sudden unanticipated demands. Such areas would include operating

departments, A&E departments, coronary care units, central delivery suites of

maternity departments, special care baby units, intensive therapy units,

sterilizing and disinfecting units etc. These stores should only be used for full

cylinders and all empty cylinders should be returned immediately to the main

cylinder store.

8.65 The numbers of cylinders held should be kept to the minimum; a

24-hour supply should suffice for normal circumstances, although this may

have to be increased for weekends, bank holidays etc and other operational

reasons.

8.66 These cylinders should be kept in a specially designated room. This

should comply as far as possible with the requirements for manifold rooms,

but in any case should be well ventilated and where practicable have at least

one external wall to facilitate natural ventilation.

8.67 This designated room should be clearly labelled with the types of

cylinder contained and “no smoking” warning signs.

8.68 No combustible material should be kept in the ready-to-use store. The

general principles given in paragraphs 8.83–8.85 and 6.61 should be followed

where appropriate.

8.69 Cylinders should be stored in racks in accordance with BS 1319.

Sufficient space should be provided for manoeuvring cylinders onto and off

trolleys. Adequate means of securing large cylinders should be provided to

prevent falling.

.

hospital compressor

The problem

In compressed air fed systems, ambient air is drawn into

the compressor, therefore any contaminants present in the

ambient air plus those introduced by the compressor itself

will be present unless removed by a purification system.

Contaminants present can include:

• Carbon monoxide

• Carbon dioxide

• Water vapor

• Micro-organisms

• Atmospheric dirt

• Oil vapor

• Water aerosols

• Condensed liquid water

• Liquid oil

• Oil aerosols

• Rust

• Pipescale

Located in the bowels of most hospitals, you will find the source of the Level 1 Medical Air compressed air system. Per the NFPA Section 99 Specification (National Fire Protection Association), Level 1 air compressor systems provide air for human consumption within the hospital facility. Level 2 Systems are used where patients are not dependent upon mechanical ventilation (such as driving pneumatic tools). Level 3 Systems are used to drive hand pieces in dental offices or hospitals. Medical air may be supplied from cylinders, bulk containers and/or medical air compressors. The definition of a medical air compressor (per NFPA) is a compressor that is designed to exclude oil from the air stream and compression chamber and that does not, under normal operating conditions or any single fault, add toxic or flammable contaminants to the compressed air.

A Level 1 medical compressed air system is made up of four major sections; the compressors, control panel, receiver, and purification. The air system supplies compressed air through hundreds, if not thousands, of feet of copper pipe that has been cleaned and installed per requirements established by the NFPA Section 99 Specification. The pipeline leads to many areas of the hospital with the most vital area being surgery. Surgery and patient rooms are equipped with medical outlets that act as quick connections for attaching respirators and ventilators.

Powerex SOS Scroll Medical Compressors

Air compressors used in medical systems have been evolving over the last twenty years. Historically, air compressors were mostly of two different technologies; liquid ring and oil-free reciprocating. Liquid ring pumps are very reliable, however, they require water to cool and seal the pump, which increases operating costs due to the additional cost of the water and sewage. Oil-free reciprocating air compressors have a oil-free piston and cylinder with an oil-lubricated crankshaft and crankcase. The piston and crankcase areas are separated by a extension shaft. This extension shaft is required, by NFPA 99, to be within visual access, to insure that the extension seals are not leaking oil that could find its way to the piston and cylinder.

Oil-less Scroll Air Compressors

The primary technologies used today are oil-less reciprocating and oil-less scroll air compressors. Reciprocating oil-less pumps have proven to be reliable in applications requiring less than a 50 % duty cycle. A lower duty-cycle reduces the temperatures of the piston and cylinder areas. Powerex reciprocating pumps are designed and built with composite piston technology that greatly reduces the temperature of the cylinder areas and the temperature on the wrist pin bearing.

Medical Air

by Ervin Moss, M.D. and Thomas Nagle, M.B.A.

---

Unlike the other piped medical gases which are typically delivered to hospitals in cylinders, medical air is most often manufactured on-site. This is accomplished by pulling outside air into a medical air compressor which is connected to the piping system feeding the facility. Rarely, due to poor quality ambient air, medical air can be produced from blending compressed cylinder nitrogen and oxygen. Due to the large volume of air that most hospitals consume, on-site production is usually the most practical and economical method of supply. There is a down side, however, in that the equipment required to produce medical air suitable for patient use is quite complex and as such must be carefully installed and maintained to ensure that the risk of contamination or breakdown is kept to a minimum.

Most anesthesiologists are unaware of the complexity of the systems used to produce the medical air that they use. As medical air is considered by United States Pharmacopoeia to be a manufactured drug, anesthesiologists should be aware of the quality of the medical air produced in their facility and delivered to their patients. This article is meant to provide a basic understanding of a typical medical air system, including the purpose and operation of the key components. A familiarity with these basics should be sufficient to allow anesthesiologists to make inquires concerning the quality of the medical air delivered to their patients.

Medical air is used for a variety of patient applications. Many patients sensitive to oxygen toxicity are delivered air to lower their exposure to oxygen. Many of these patients have extremely delicate respiratory systems or processes which rely on a pure, accurate concentration of medical air. Some examples of patients dependent on a reliable, quality air supply would be neonates and those patients suffering from adult respiratory depression syndrome. Medical air is also used during anesthesia as a substitute for nitrous oxide to reduce the high concentration of oxygen exposure. While the source of medical air may be a manifold with a bank of compressed air cylinders, most hospitals use a compressor system. This article will refer to installations with air compressors. An illustration of a typical medical air plant is provided for your reference throughout this article's discussion. To better understand the medical air system, we will follow the path of the air as it flows through the key components, from the source to the patient.

Start at the Source

The logical place to start learning about the medical air system is the intake pipe of the compressor. The intake is usually located on the facility's roof. The intake location can have a major impact on the quality of the medical air produced. The location, design, and components of the air intake are described in National Fire Protection Association (NFPA) codes. NFPA 99, Standard for Health Care Facilities, recommendations for the design of medical gas systems are followed throughout the United States and will be referenced frequently in this article. However, you should be aware that local codes can supersede NFPA codes. NFPA 99 Sec. 4-3.1.9.2 states that the air intake shall be located outdoors above roof level, a minimum distance of 10 feet (3m) from any door, window, other intakes, or opening in the building, and a minimum distance of 20 feet above the ground. Intakes shall be turned down and screened or otherwise protected against entry of vermin or water with screening that shall be fabricated or composed of a non-corrosive material, such as stainless steel or other suitable materials. The NFPA allows flexibility when the roofs are staggered in height and suggests that factors such as the size of roofs, distance to nearest doors and windows, and the presence of other roof equipment can influence the final location. The intake need not always be higher than the highest roof.

In the case where there is more than one compressor system in the hospital, it is permissible to join pipes from separate compressors to one intake pipe which must be properly sized. However, the design must allow each compressor intake to be closed off by check valve, blind flange, or tube cap when a compressor is removed from service. This is meant to prevent mechanical room air from being drawn into the system from the open pipe.

The intake shall be labeled as the source of medical air. There has been a case where the medical air intake was located in the facilities heating ventilation air conditioning (HVAC) system. The coils on an HVAC system were being washed with an acidic solution for cleaning and maintenance. This resulted in fumes being unknowingly drawn into the medical air system and to the patients.

Air quality varies from region to region and even with proximity of your facility. For example, the air on the roof of a hospital located within a large city will not be as pure as air at a rural hospital. Yet, a rural facility's air can be polluted by its proximity to a major highway, or the air intake placed too close to the medical vacuum system exhaust outlet. The latter is not an uncommon source of bacterial pollution where the gases from vacuum systems, literally of sewer quality, can be sucked into its medical air intake pipe. In older facilities the air intake may have been properly located and initially certified, but, there are cases where an intake became improperly located as the environment around the intake changed through facility expansion. Such has been the case with the addition of helicopter pads, parking lots, and truck loading docks where exhausts rich in carbon monoxide and engine pollutants were thus introduced in the manufacture of medical air.

The infamous "tweety bird" at the APSF scientific exhibit "Look Beyond the Walls" is an example of gross particulate contamination of a medical air supply. In this case, a bird was aspirated into the medical air compressor of a hospital and had occluded the system. The foul odor resulting from the decaying bird was a patient complaint that brought our committee member, Mr. Fred Evans, to service the system. Foul odor of any kind in a medical air system must be investigated. If the bird entered the system through an unscreened roof intake, the hospital was in violation of NFPA code. However, the entry was most likely through a break in the intake pipe which ran along a warehouse roof in course from the roof intake to the compressor. The break in pipeline continuity was a contractor error.

Interestingly, NFPA permits the intake to be within the building when the air source is equal or better than outside air, as filtered for use in operating rooms ventilating systems. It must be available twenty-four hours a day, seven days a week and periodically checked for purity. It is a good practice to test both the inside and outside air to occasionally determine if the inside air is of equal or better quality. Unless removed through the use of scrubbers or special filtration, any undesirable gases found in the atmosphere where the intake pipe is located will be compressed and delivered through the medical air system. Examples of this were covered at the beginning of the article.

Air Compressor and Its System

Inlet Filter/Muffler:

The air compressor process takes eight cubic feet of ambient air and compresses it into one cubic foot of compressed air. As a result, containments such as particulate matter, pollen, water, carbon monoxide, and breakdown materials of internal combustion engines or other containments are concentrated. Therefore, it is necessary to have methods in the manufacturing process to eliminate contaminates. The inlet filter/muffler should be located in the inlet side of the air compressor and can be part of some factory compressor packages. It is not uncommon for some systems to lack this filter since NFPA does not recognize it as a standard. Its primary function is to filter gross particulate from the ambient air aspirated through the screened intake usually located on the roof. It also acts as muffler for the air compressor to reduce noise pollution.

Air Compressor:

The air, usually from the atmosphere, is compressed by multiplexed medical air compressors, the "heart" of the medical air system. Two or more compressors (usually two) must be used for the support of medical air. Triplex and quadraplex systems are also available for facilities requiring greater demand. Simplex system components are not acceptable by NFPA 99. The duplication of much of the medical air systems provides a backup system if one unit breaks down or is in need of repair. The multiplexing provided by alternating units extends the life of the units and provides backup during demand overload. NFPA 99 requires that each unit separately must be capable of maintaining the supply of air at peak demand (NFPA 99 Sec. 4-3.9.1.2). Each compressor should be provided with an isolation valve, a pressure relief valve, and a check valve in its discharge line. Each compressor should be isolated from the system for servicing through an isolation (shut-off) valve in its discharge line. As stated in NFPA 99 Sec. 4-3.1.9.1, "The medical air compressors shall be designed to prevent the introduction of contaminants or liquid into the pipeline by: (a) Elimination of oil anywhere in the compressor, or (b) Separation of the oil-containing section by an open area to atmosphere, which allows continuous visual inspection of the interconnecting shaft."There have been cases where non-medical grade compressors have been installed in hospitals which can create oils, water, and toxic oil breakdown products to mix with the medical air.

The medical air system is intended to produce gas used exclusively for breathable air delivered to patients through devices such as: flowmeters, blenders, anesthesia machines, and critical care ventilators. This would also include instruments that exhaust into the pharynx such as dental tools and pneumatically powered surgical tools. Medical air should not be used for non-medical applications such as powering pneumatic operated doors, engineering, or maintenance needs. As stated in NFPA 99, "As a compressed air supply source, a medical air compressor should not be used to supply air for other purposes because such use could increase service interruptions, reduced service life, and introduce additional opportunities for contamination."

Aftercoolers (if required):

In larger air plants, aftercoolers may be desirable. Through the compression process air is heated and warmer air holds more moisture. Aftercoolers are used to reduce the temperature of the air after the compression process; this results in the precipitation of water. This water is then drained off. Aftercoolers should be duplexed so that one unit can handle 100% of the load. They should have water traps with automatic drains for water removal and isolation valves for servicing without the need to shut down the system. Although aftercoolers remove gross amounts of water they are not a substitute for dryers (see below).

Receiver:

The receiver is a large cylindrically shaped reservoir which stores a reserve volume of compressed air for usage. The receiver allows the efficient on/off operation of the compressors. Receivers are usually composed of iron and can be a source for rust particulate. Even though iron receivers meet NFPA standards, this material is subject to oxidation and flaking when introduced to moisture. Stainless steel receivers are available and should be installed during new construction, repair, or expansion despite the minimum NFPA standard. The receiver should be equipped with a pressure relief valve, site glass, pressure gauge, and a water trap with an automatic drain. The receiver should also be provided with a three valve bypass to allow servicing.

Air Dryers:

Dryers are an essential part of the system used to remove the water produced in the manufacturing process by the compression of ambient air which may be rich with humidity. Air dryers are usually of the refrigerant or desiccant type technology. Refrigerant dryers are an air-to-air refrigerant heat exchanger, a mechanical condensate separator, and an automatic drain trap. While desiccant dryers use an adsorption process to remove water, desiccant particulate can contaminate medical air if not properly maintained or filtered. The dryers should be duplexed so that only one dryer is used at one given time. Hence, each dryer should be capable of handling 100% of the load. They should also use bypass valves for isolation during servicing. Desiccant dryers are approximately 50% more expensive than refrigerant dryers.

Final Line Filters:

Important components of the medical air system are final line filters used to prevent introduction of particulate, oil, and odors from the medical air supply. Some contaminants may be introduced as hydrocarbons from leaking oil seals, spill-over from overloaded filters, rust flaking from a receiver, etc. NFPA 99 states, "Each of the filters shall be sized for 100% of the system peak calculated demand at design conditions and be rated for a minimum of 98% efficiency at 1 micron. These filters shall be equipped with a continuous visual indicator showing the status of the filter element life." The need for visual indication was added by NFPA in 1993. The filters shall also be duplexed for isolation and shut down for servicing without completely shutting down the system. NFPA 99 recommends quarterly inspection of the filters. Some manufacturers provided filtration capabilities down to a .1 micron level. In environments with high concentrations of carbon monoxide special scrubbers may be introduced at this location to remove this or other pollutants.

Final Line Regulators:

Final line regulators should provide operating pressure for medical air throughout the facility at 50 to 55 psig. Whereas, the air compressor plant generates operating pressures of 80 to 100 psig. to facilitate the efficiency of the dryers. The regulators should be duplexed with isolation valves to allow servicing without the need to shut down the system. In Air Quality Monitoring as of the 1993 edition, NFPA 99 requires new construction to have continuous monitoring with central alarm capabilities for dew point and carbon monoxide contaminants downstream of the dryers and upstream of the piping system. These requirements have been largely driven by the water and elevated levels of carbon monoxide found in some medical gas systems.

Shut-off Valves:

The source shut-off valve should be located to permit the entire source of supply to be isolated from the piping system. This valve is located at the air compressor and its accessories downstream of the final line regulators. All shut-off valves should be quarter turn, specially cleaned, ball valves suitable for medical gas applications. The main supply shut-off valve should be located downstream of the source valve and outside of the enclosure, source room, or where the main line source first enters the building. The purpose of this valve is to shut off the supply in case of emergency or if the source valve is inaccessible. Each riser distributing gases to the above floors should have a shut-off valve adjacent to the riser connection. Each lateral branch or zone shall be provided with a shut-off valve which controls the flow of gases to the patient rooms on that branch. The branch/zone valve should allow the control of gases to that specific area and not effect the gas flow anywhere else in the system. Pressure gauges should be provided downstream of each lateral branch shut-off valve. NFPA 99 also states: "Anesthetizing locations and other vital life-support and critical areas, such as postanesthesia recovery, intensive care units, and coronary care units, shall be supplied directly from the riser without intervening valves...""A shut-off valve shall be located outside each anesthetizing location in each medical gas line, so located as to readily be accessible at all times for use in an emergency." It is important that all shut-off valves be labeled with a caution, the name of the gas, and the location(s) which the valve controls. There have been numerous incidents of medical gases being shut off due to poor labeling (if any) of the valve and the locations which it supplies.

Alarms:

An automatic pressure switch shall be located downstream of the main supply line shut-off valve. A visual and audible alarm should indicate a rise or fall of the main line pressure above or below the nominal line pressure. The alarm should be located where it is continuously monitored throughout the facility's time of operation. NFPA 99 states, "Area alarms shall be provided for anesthetizing locations and critical care areas. Warning signals shall be provided for all medical gas piping systems supplying these areas..." The area alarm in the anesthetizing location is intended to monitor all locations on a single branch, not each individual operating room.

Piping:

Piping which is used for the system downstream of the source shut-off valve shall be composed of copper. NFPA states: "Piping shall be hard-drawn seamless medical gas tube Type K or L (ASTM B819), and bear one of the following markings: OXY, MED, OXY/MED, ACR/OXY, or ACR/MED." Medical air pipes are to be of the same material and quality as oxygen pipes.

The type of material used with the compressors and with the piping system shall be non-corrosive. Copper and brass are most commonly used. The pipe bringing air from the outside intake to the compressor should be non-corrosive since it is exposed to moisture and atmospheric contaminants. Although the NFPA does not spell out the intake pipe's specific composition, as it does for the compressor and the pipeline downstream, the intake pipe should not be iron. It is not uncommon to find the plumbing contractors engaged to install medical piping to treat the piping as ordinary water or sewer plumbing. Galvanized steel is also unacceptable since the zinc plating could flake off under the pressure and flow of gases.

A recent (1995) major hospital inspection was found to have iron piping between the medical air compressor, dryers, receiver, and aftercoolers. The system had been certified as meeting NFPA codes seven years earlier. The correction of such design errors can be expensive. It is far more reasonable for the anesthesiologists to be aware of basic construction codes and have a say in proper installation from the beginning. Iron and galvanized pipe may oxidize, resulting in particulate matter flaking off from the pressure and flow, and will result in being carried downstream where it may interfere with the flow of gases or proper operation of station outlets, ventilators, blenders, anesthesia systems, or other pieces of secondary equipment.

Station Patient/Outlets:

Station outlets consist of primary and secondary check valves which allow secondary pieces of equipment to be attached to the medical gas line. Station outlets should be used only for the delivery of gases intended for medical use. The outlet shall also be designed as being gas specific by using size or keyed dissimilar connections specific for each individual gas. Each outlet shall be labeled with the name or chemical symbol and the specific color coding for the gas supplied.

More on Contaminants and Particulates:

Water is the most common contaminant found in medical air lines and is perhaps the most insidious of the contaminants found. It can also cause some of the most costly damage to secondary equipment. Water, unlike particulate, can pass through particulate filters and make its way into anesthesia machines, ventilators, other commonly used secondary equipment, and the patient as well. Jerry Lavene, Manager of the Anesthesia Vaporizer Repair Center from Ohmeda, states "The most common contaminant we find in vaporizers during their disassemble for remanufacture is moisture. Moisture or the combined effects of moisture with the anesthetic agent can create issues within the internal mechanisms of the vaporizer." Some critical care ventilators saturated with water were non-repairable and had to be scraped by one facility. The anesthesia machines required a complete overhaul to restore them to usable condition. The presence of water can also provide the medium for bacterial growth. Water located in medical air lines which are subjected to low temperatures can freeze and occlude gas flow. Water can also facilitate the oxidation of the copper piping inside the medical air line.

Water may be introduced through a variety of ways. Inadequate removal of water through undersized, saturated, or the lack of appropriate air dryers is common. Water may be introduced through malfunctioning liquid ring air compressor components. Failure of automatic drains in aftercoolers, receivers, dryers, or other components of the medical air plant is an area of frequent fault allowing unwanted water into the system.

Oils can be introduced through a non-medical grade air compressor being installed. This may occur through improper equipment specification or purchasing. Medical grade compressors have been known to fail and introduce oil into the system. Some medical air compressors are now available which use a totally oil-less compressor technology to prevent this possibility. Don't assume the air compressor being used for your facility is suitable for medical grade air. The possibility of oil contamination has resulted in hydrocarbon monitoring requirements.

Construction debris such as sand, solder, flux, dirt, vermin, and so on have been found in medical air lines due to poor techniques in the construction process. These particulates can be introduced downstream of the filtration system located at the medical air plant. This can be avoided through proper design, installation procedures and techniques, and final testing (certification) of the new system or addition. There are processes available to remove these contaminants found in existing systems. Medical air is an important life sustaining gas commonly used in our facilities. Anesthesiologists should be aware of those responsible for overseeing the medical air system and their qualifications. During construction they should be aware of design and installation specifications. Preventative maintenance programs should be in place and the results of as many as 17 tests performed at required intervals should be reviewed and evaluated.

Vigilance will result in patients receiving clean and safe medical air. Ask yourself, "Would you want your family placed on your present medical air syste

Rotary screw compressor

A rotary screw compressor is a type of gas compressor which uses a rotary type positive displacement mechanism. They are commonly used to replace piston compressors where large volumes of high pressure air are needed, either for large industrial applications or to operate high-power air tools such as jackhammers.

The gas compression process of a rotary screw is a continuous sweeping motion, so there is very little

pulsation or surging of flow, as occurs with piston compressors.

Operation[edit]

Rotary screw compressors use two meshing helical screws, known as rotors, to compress the gas. In a dry running rotary screw compressor, timing gears ensure that the male and female rotors maintain precise alignment. In an oil-flooded rotary screw compressor, lubricating oil bridges the space between the rotors, both providing a hydraulic seal and transferring mechanical energy between the driving and driven rotor. Gas enters at the suction side and moves through the threads as the screws rotate. The meshing rotors force the gas through the compressor, and the gas exits at the end of the screws.^[1]

The effectiveness of this mechanism is dependent on precisely fitting clearances between the helical rotors, and between the rotors and the chamber for sealing of the compression cavities. Some leakage is however inevitable, and high rotational speeds must be used to minimize the ratio of leakage flow rate over effective flow rate.

Size[edit]

Rotary screw compressors tend to be compact and smooth running with limited vibration and thus do not require spring suspension. Many rotary screw compressors are, however, mounted using rubber vibration isolating mounts to absorb high-frequency vibrations, especially in rotary screw compressors that operate at high rotational speeds. Rotary screw compressors are produced in sizes that range from 10 cubic feet per minute to several thousand CFM. Rotary screw compressors are typically used in applications requiring more airflow than is produced by small reciprocating compressors but less than is produced bycentrifugal compressors.

Applications[]

Typically, they are used to supply compressed air for general industrial applications. Trailer mounted diesel powered units are often seen at construction sites, and are used to power air operated construction machinery.

Oil-free[]

In an oil-free compressor, the air is compressed entirely through the action of the screws, without the assistance of an oil seal. They usually have lower maximum discharge pressure capability as a result. However, multi-stage oil-free compressors, where the air is compressed by several sets of screws, can achieve pressures of over 150 psig, and output volume of over 2000 cubic feet (56.634 cubic meters) per minute (measured at 60 °C and atmospheric pressure).

Oil-free compressors are used in applications where entrained oil carry-over is not acceptable, such as medical research and semiconductor manufacturing. However, this does not preclude the need for filtration as hydrocarbons and other contaminants ingested from the ambient air must also be removed prior to the point-of-use. Subsequently, air treatment identical to that used for an oil-flooded screw compressor is frequently still required to ensure a given quality of compressed air.

Oil-injected[edit]

Diagram of a rotary screw compressor

In an oil-injected rotary screw compressor, oil is injected into the compression cavities to aid sealing and provide cooling sink for the gas charge. The oil is separated from the discharge stream, then cooled, filtered and recycled. The oil captures non-polar particulates from the incoming air, effectively reducing the particle loading of compressed air particulate filtration. It is usual for some entrained compressor oil to carry over into the compressed gas stream downstream of the compressor. In many applications, this is rectified by coalescer/filter vessels.^[2] In other applications, this is rectified by the use of receiver tanks that reduce the local velocity of compressed air, allowing oil to condense and drop out of the air stream to be removed from the compressed air system via condensate management equipment.

Control schemes[edit]

Among rotary screw compressors, there are multiple control schemes, each with differing advantages and disadvantages.

Start/stop[edit]

In a start/stop control scheme, compressor controls actuate relays to apply and remove power to the motor according to compressed air needs.

Load/unload[edit]

In a load/unload control scheme, the compressor remains continuously powered. However, when the demand for compressed air is satisfied or reduced, instead of disconnecting power to the compressor, a device known as a slide valve is activated. This device uncovers part of the rotor and proportionately reduces capacity of the machine down to typically 25% of the compressors capability thereby unloading the compressor. This reduces the number of start/stop cycles for electric motors over a start/stop control scheme in electrically-driven compressors, improving equipment service life with a minimal change in operating cost. This scheme is utilised by nearly all industrial air compressor manufacturers. When a load/unload control scheme is combined with a timer to stop the compressor after a predetermined period of continuously unloaded operation, it is known as a dual-control or auto-

dual scheme

Medical Air

by Ervin Moss, M.D. and Thomas Nagle, M.B.A.

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Unlike the other piped medical gases which are typically delivered to hospitals in cylinders, medical air is most often manufactured on-site. This is accomplished by pulling outside air into a medical air compressor which is connected to the piping system feeding the facility. Rarely, due to poor quality ambient air, medical air can be produced from blending compressed cylinder nitrogen and oxygen. Due to the large volume of air that most hospitals consume, on-site production is usually the most practical and economical method of supply. There is a down side, however, in that the equipment required to produce medical air suitable for patient use is quite complex and as such must be carefully installed and maintained to ensure that the risk of contamination or breakdown is kept to a minimum.

Most anesthesiologists are unaware of the complexity of the systems used to produce the medical air that they use. As medical air is considered by United States Pharmacopoeia to be a manufactured drug, anesthesiologists should be aware of the quality of the medical air produced in their facility and delivered to their patients. This article is meant to provide a basic understanding of a typical medical air system, including the purpose and operation of the key components. A familiarity with these basics should be sufficient to allow anesthesiologists to make inquires concerning the quality of the medical air delivered to their patients.

Medical air is used for a variety of patient applications. Many patients sensitive to oxygen toxicity are delivered air to lower their exposure to oxygen. Many of these patients have extremely delicate respiratory systems or processes which rely on a pure, accurate concentration of medical air. Some examples of patients dependent on a reliable, quality air supply would be neonates and those patients suffering from adult respiratory depression syndrome. Medical air is also used during anesthesia as a substitute for nitrous oxide to reduce the high concentration of oxygen exposure. While the source of medical air may be a manifold with a bank of compressed air cylinders, most hospitals use a compressor system. This article will refer to installations with air compressors. An illustration of a typical medical air plant is provided for your reference throughout this article's discussion. To better understand the medical air system, we will follow the path of the air as it flows through the key components, from the source to the patient.

Start at the Source

The logical place to start learning about the medical air system is the intake pipe of the compressor. The intake is usually located on the facility's roof. The intake location can have a major impact on the quality of the medical air produced. The location, design, and components of the air intake are described in National Fire Protection Association (NFPA) codes. NFPA 99, Standard for Health Care Facilities, recommendations for the design of medical gas systems are followed throughout the United States and will be referenced frequently in this article. However, you should be aware that local codes can supersede NFPA codes. NFPA 99 Sec. 4-3.1.9.2 states that the air intake shall be located outdoors above roof level, a minimum distance of 10 feet (3m) from any door, window, other intakes, or opening in the building, and a minimum distance of 20 feet above the ground. Intakes shall be turned down and screened or otherwise protected against entry of vermin or water with screening that shall be fabricated or composed of a non-corrosive material, such as stainless steel or other suitable materials. The NFPA allows flexibility when the roofs are staggered in height and suggests that factors such as the size of roofs, distance to nearest doors and windows, and the presence of other roof equipment can influence the final location. The intake need not always be higher than the highest roof.

In the case where there is more than one compressor system in the hospital, it is permissible to join pipes from separate compressors to one intake pipe which must be properly sized. However, the design must allow each compressor intake to be closed off by check valve, blind flange, or tube cap when a compressor is removed from service. This is meant to prevent mechanical room air from being drawn into the system from the open pipe.

The intake shall be labeled as the source of medical air. There has been a case where the medical air intake was located in the facilities heating ventilation air conditioning (HVAC) system. The coils on an HVAC system were being washed with an acidic solution for cleaning and maintenance. This resulted in fumes being unknowingly drawn into the medical air system and to the patients.

Air quality varies from region to region and even with proximity of your facility. For example, the air on the roof of a hospital located within a large city will not be as pure as air at a rural hospital. Yet, a rural facility's air can be polluted by its proximity to a major highway, or the air intake placed too close to the medical vacuum system exhaust outlet. The latter is not an uncommon source of bacterial pollution where the gases from vacuum systems, literally of sewer quality, can be sucked into its medical air intake pipe. In older facilities the air intake may have been properly located and initially certified, but, there are cases where an intake became improperly located as the environment around the intake changed through facility expansion. Such has been the case with the addition of helicopter pads, parking lots, and truck loading docks where exhausts rich in carbon monoxide and engine pollutants were thus introduced in the manufacture of medical air.

The infamous "tweety bird" at the APSF scientific exhibit "Look Beyond the Walls" is an example of gross particulate contamination of a medical air supply. In this case, a bird was aspirated into the medical air compressor of a hospital and had occluded the system. The foul odor resulting from the decaying bird was a patient complaint that brought our committee member, Mr. Fred Evans, to service the system. Foul odor of any kind in a medical air system must be investigated. If the bird entered the system through an unscreened roof intake, the hospital was in violation of NFPA code. However, the entry was most likely through a break in the intake pipe which ran along a warehouse roof in course from the roof intake to the compressor. The break in pipeline continuity was a contractor error.

Interestingly, NFPA permits the intake to be within the building when the air source is equal or better than outside air, as filtered for use in operating rooms ventilating systems. It must be available twenty-four hours a day, seven days a week and periodically checked for purity. It is a good practice to test both the inside and outside air to occasionally determine if the inside air is of equal or better quality. Unless removed through the use of scrubbers or special filtration, any undesirable gases found in the atmosphere where the intake pipe is located will be compressed and delivered through the medical air system. Examples of this were covered at the beginning of the article.

Air Compressor and Its System

Inlet Filter/Muffler:

The air compressor process takes eight cubic feet of ambient air and compresses it into one cubic foot of compressed air. As a result, containments such as particulate matter, pollen, water, carbon monoxide, and breakdown materials of internal combustion engines or other containments are concentrated. Therefore, it is necessary to have methods in the manufacturing process to eliminate contaminates. The inlet filter/muffler should be located in the inlet side of the air compressor and can be part of some factory compressor packages. It is not uncommon for some systems to lack this filter since NFPA does not recognize it as a standard. Its primary function is to filter gross particulate from the ambient air aspirated through the screened intake usually located on the roof. It also acts as muffler for the air compressor to reduce noise pollution.

Air Compressor:

The air, usually from the atmosphere, is compressed by multiplexed medical air compressors, the "heart" of the medical air system. Two or more compressors (usually two) must be used for the support of medical air. Triplex and quadraplex systems are also available for facilities requiring greater demand. Simplex system components are not acceptable by NFPA 99. The duplication of much of the medical air systems provides a backup system if one unit breaks down or is in need of repair. The multiplexing provided by alternating units extends the life of the units and provides backup during demand overload. NFPA 99 requires that each unit separately must be capable of maintaining the supply of air at peak demand (NFPA 99 Sec. 4-3.9.1.2). Each compressor should be provided with an isolation valve, a pressure relief valve, and a check valve in its discharge line. Each compressor should be isolated from the system for servicing through an isolation (shut-off) valve in its discharge line. As stated in NFPA 99 Sec. 4-3.1.9.1, "The medical air compressors shall be designed to prevent the introduction of contaminants or liquid into the pipeline by: (a) Elimination of oil anywhere in the compressor, or (b) Separation of the oil-containing section by an open area to atmosphere, which allows continuous visual inspection of the interconnecting shaft."There have been cases where non-medical grade compressors have been installed in hospitals which can create oils, water, and toxic oil breakdown products to mix with the medical air.

The medical air system is intended to produce gas used exclusively for breathable air delivered to patients through devices such as: flowmeters, blenders, anesthesia machines, and critical care ventilators. This would also include instruments that exhaust into the pharynx such as dental tools and pneumatically powered surgical tools. Medical air should not be used for non-medical applications such as powering pneumatic operated doors, engineering, or maintenance needs. As stated in NFPA 99, "As a compressed air supply source, a medical air compressor should not be used to supply air for other purposes because such use could increase service interruptions, reduced service life, and introduce additional opportunities for contamination."

Aftercoolers (if required):

In larger air plants, aftercoolers may be desirable. Through the compression process air is heated and warmer air holds more moisture. Aftercoolers are used to reduce the temperature of the air after the compression process; this results in the precipitation of water. This water is then drained off. Aftercoolers should be duplexed so that one unit can handle 100% of the load. They should have water traps with automatic drains for water removal and isolation valves for servicing without the need to shut down the system. Although aftercoolers remove gross amounts of water they are not a substitute for dryers (see below).

Receiver:

The receiver is a large cylindrically shaped reservoir which stores a reserve volume of compressed air for usage. The receiver allows the efficient on/off operation of the compressors. Receivers are usually composed of iron and can be a source for rust particulate. Even though iron receivers meet NFPA standards, this material is subject to oxidation and flaking when introduced to moisture. Stainless steel receivers are available and should be installed during new construction, repair, or expansion despite the minimum NFPA standard. The receiver should be equipped with a pressure relief valve, site glass, pressure gauge, and a water trap with an automatic drain. The receiver should also be provided with a three valve bypass to allow servicing.

Air Dryers:

Dryers are an essential part of the system used to remove the water produced in the manufacturing process by the compression of ambient air which may be rich with humidity. Air dryers are usually of the refrigerant or desiccant type technology. Refrigerant dryers are an air-to-air refrigerant heat exchanger, a mechanical condensate separator, and an automatic drain trap. While desiccant dryers use an adsorption process to remove water, desiccant particulate can contaminate medical air if not properly maintained or filtered. The dryers should be duplexed so that only one dryer is used at one given time. Hence, each dryer should be capable of handling 100% of the load. They should also use bypass valves for isolation during servicing. Desiccant dryers are approximately 50% more expensive than refrigerant dryers.

Final Line Filters:

Important components of the medical air system are final line filters used to prevent introduction of particulate, oil, and odors from the medical air supply. Some contaminants may be introduced as hydrocarbons from leaking oil seals, spill-over from overloaded filters, rust flaking from a receiver, etc. NFPA 99 states, "Each of the filters shall be sized for 100% of the system peak calculated demand at design conditions and be rated for a minimum of 98% efficiency at 1 micron. These filters shall be equipped with a continuous visual indicator showing the status of the filter element life." The need for visual indication was added by NFPA in 1993. The filters shall also be duplexed for isolation and shut down for servicing without completely shutting down the system. NFPA 99 recommends quarterly inspection of the filters. Some manufacturers provided filtration capabilities down to a .1 micron level. In environments with high concentrations of carbon monoxide special scrubbers may be introduced at this location to remove this or other pollutants.

Final Line Regulators:

Final line regulators should provide operating pressure for medical air throughout the facility at 50 to 55 psig. Whereas, the air compressor plant generates operating pressures of 80 to 100 psig. to facilitate the efficiency of the dryers. The regulators should be duplexed with isolation valves to allow servicing without the need to shut down the system. In Air Quality Monitoring as of the 1993 edition, NFPA 99 requires new construction to have continuous monitoring with central alarm capabilities for dew point and carbon monoxide contaminants downstream of the dryers and upstream of the piping system. These requirements have been largely driven by the water and elevated levels of carbon monoxide found in some medical gas systems.

Shut-off Valves:

The source shut-off valve should be located to permit the entire source of supply to be isolated from the piping system. This valve is located at the air compressor and its accessories downstream of the final line regulators. All shut-off valves should be quarter turn, specially cleaned, ball valves suitable for medical gas applications. The main supply shut-off valve should be located downstream of the source valve and outside of the enclosure, source room, or where the main line source first enters the building. The purpose of this valve is to shut off the supply in case of emergency or if the source valve is inaccessible. Each riser distributing gases to the above floors should have a shut-off valve adjacent to the riser connection. Each lateral branch or zone shall be provided with a shut-off valve which controls the flow of gases to the patient rooms on that branch. The branch/zone valve should allow the control of gases to that specific area and not effect the gas flow anywhere else in the system. Pressure gauges should be provided downstream of each lateral branch shut-off valve. NFPA 99 also states: "Anesthetizing locations and other vital life-support and critical areas, such as postanesthesia recovery, intensive care units, and coronary care units, shall be supplied directly from the riser without intervening valves...""A shut-off valve shall be located outside each anesthetizing location in each medical gas line, so located as to readily be accessible at all times for use in an emergency." It is important that all shut-off valves be labeled with a caution, the name of the gas, and the location(s) which the valve controls. There have been numerous incidents of medical gases being shut off due to poor labeling (if any) of the valve and the locations which it supplies.

Alarms:

An automatic pressure switch shall be located downstream of the main supply line shut-off valve. A visual and audible alarm should indicate a rise or fall of the main line pressure above or below the nominal line pressure. The alarm should be located where it is continuously monitored throughout the facility's time of operation. NFPA 99 states, "Area alarms shall be provided for anesthetizing locations and critical care areas. Warning signals shall be provided for all medical gas piping systems supplying these areas..." The area alarm in the anesthetizing location is intended to monitor all locations on a single branch, not each individual operating room.

Piping:

Piping which is used for the system downstream of the source shut-off valve shall be composed of copper. NFPA states: "Piping shall be hard-drawn seamless medical gas tube Type K or L (ASTM B819), and bear one of the following markings: OXY, MED, OXY/MED, ACR/OXY, or ACR/MED." Medical air pipes are to be of the same material and quality as oxygen pipes.

The type of material used with the compressors and with the piping system shall be non-corrosive. Copper and brass are most commonly used. The pipe bringing air from the outside intake to the compressor should be non-corrosive since it is exposed to moisture and atmospheric contaminants. Although the NFPA does not spell out the intake pipe's specific composition, as it does for the compressor and the pipeline downstream, the intake pipe should not be iron. It is not uncommon to find the plumbing contractors engaged to install medical piping to treat the piping as ordinary water or sewer plumbing. Galvanized steel is also unacceptable since the zinc plating could flake off under the pressure and flow of gases.

A recent (1995) major hospital inspection was found to have iron piping between the medical air compressor, dryers, receiver, and aftercoolers. The system had been certified as meeting NFPA codes seven years earlier. The correction of such design errors can be expensive. It is far more reasonable for the anesthesiologists to be aware of basic construction codes and have a say in proper installation from the beginning. Iron and galvanized pipe may oxidize, resulting in particulate matter flaking off from the pressure and flow, and will result in being carried downstream where it may interfere with the flow of gases or proper operation of station outlets, ventilators, blenders, anesthesia systems, or other pieces of secondary equipment.

Station Patient/Outlets:

Station outlets consist of primary and secondary check valves which allow secondary pieces of equipment to be attached to the medical gas line. Station outlets should be used only for the delivery of gases intended for medical use. The outlet shall also be designed as being gas specific by using size or keyed dissimilar connections specific for each individual gas. Each outlet shall be labeled with the name or chemical symbol and the specific color coding for the gas supplied.

More on Contaminants and Particulates:

Water is the most common contaminant found in medical air lines and is perhaps the most insidious of the contaminants found. It can also cause some of the most costly damage to secondary equipment. Water, unlike particulate, can pass through particulate filters and make its way into anesthesia machines, ventilators, other commonly used secondary equipment, and the patient as well. Jerry Lavene, Manager of the Anesthesia Vaporizer Repair Center from Ohmeda, states "The most common contaminant we find in vaporizers during their disassemble for remanufacture is moisture. Moisture or the combined effects of moisture with the anesthetic agent can create issues within the internal mechanisms of the vaporizer." Some critical care ventilators saturated with water were non-repairable and had to be scraped by one facility. The anesthesia machines required a complete overhaul to restore them to usable condition. The presence of water can also provide the medium for bacterial growth. Water located in medical air lines which are subjected to low temperatures can freeze and occlude gas flow. Water can also facilitate the oxidation of the copper piping inside the medical air line.

Water may be introduced through a variety of ways. Inadequate removal of water through undersized, saturated, or the lack of appropriate air dryers is common. Water may be introduced through malfunctioning liquid ring air compressor components. Failure of automatic drains in aftercoolers, receivers, dryers, or other components of the medical air plant is an area of frequent fault allowing unwanted water into the system.

Oils can be introduced through a non-medical grade air compressor being installed. This may occur through improper equipment specification or purchasing. Medical grade compressors have been known to fail and introduce oil into the system. Some medical air compressors are now available which use a totally oil-less compressor technology to prevent this possibility. Don't assume the air compressor being used for your facility is suitable for medical grade air. The possibility of oil contamination has resulted in hydrocarbon monitoring requirements.

Construction debris such as sand, solder, flux, dirt, vermin, and so on have been found in medical air lines due to poor techniques in the construction process. These particulates can be introduced downstream of the filtration system located at the medical air plant. This can be avoided through proper design, installation procedures and techniques, and final testing (certification) of the new system or addition. There are processes available to remove these contaminants found in existing systems. Medical air is an important life sustaining gas commonly used in our facilities. Anesthesiologists should be aware of those responsible for overseeing the medical air system and their qualifications. During construction they should be aware of design and installation specifications. Preventative maintenance programs should be in place and the results of as many as 17 tests performed at required intervals should be reviewed and evaluated.

Vigilance will result in patients receiving clean and safe medical air. Ask yourself, "Would you want your family placed on your present medical air syste