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G420E/G424E Tier LP Engine LPG and LPG Fuel Tanks 8

CHAPTER 0 LPG AND LPG FUEL TANKS

LPG Fuel Supply

Liquefied petroleum gas (LPG) consists mainly of

propane, propylene, butane, and butylenes in various

mixtures. LPG is produced as a by-product of natural

gas processing or it can be obtained from crude oil as

part of the oil refining process. LPG, like gasoline, is a

compound of hydrogen and carbon, commonly called

hydrocarbons.

In its natural state, propane is colorless and odorless;

an odorant (ethyl mercaptan) is added to the fuel so

its presence can be detected. There are currently

three grades of propane available in the United States.

A propane grade designation of HD5 (not exceeding

5% propylene), is used for internal combustion

engines while much higher levels of propylene

(HD10) are used as commercial grade propane along

with a commercial propane /butane mixture.

APPROXIMATE COMPOSITION OF HD5

PROPANE BY VOLUME

Propane

(C3H8)

Propy

lene

Butane

(C4H10)

Iso-

Butane

Methane

(CH4)

TOTAL

90.0%

min.

5% max. 2.0% 1.5% 1.5% 100%

An advantage of LPG is the ability to safely store and

transport the product in the liquid state. In the liquid

state propane is approximately 270 times as dense

as it is in a gaseous form. By pressurizing a container

of LPG we can effectively raise the boiling point

above –44 deg. C / -42 deg. C, keeping the propane

in liquid form. The point at which the liquid becomes a

gas (boiling point) depends on the amount of

pressure applied to the container.

This process operates similarly to an engine coolant

system where water is kept from boiling by

pressurizing the system and adding a mixture of

glycol. For example water at normal atmospheric

pressure will boil at 212 deg. F / 100 deg. C. If an

engines operating temperature is approximately 230

deg. F / 110 deg. C, then the water in an open un-

pressurized cooling system would simply boil off into

steam, eventually leaving the cooling system empty

and over heating the engine. If we install a 10 PSIG

cap on the radiator, pressurizing the cooling system

to 10 PSIG, the boiling point of the water increases to

242 deg. F / 117 deg. C, which will cause the water to

remain in liquid state at the engines operating

temperature.

The same principle is applied to LPG in a container,

commonly referred to as an LPG tank or cylinder.

Typically an LPG tank is not filled over 80% capacity

allowing for a 20% vapor expansion space. Outside

air temperature effect’s an LPG tank and must be

considered when using an LPG system. (Figure 2)

shows the relationship between pressure and

temperature in a LPG tank at a steady state condition.

With 128 PSIG vapor pressure acting against the

liquid propane the boiling point has been raised to

slightly more than 80 deg. F / 27 deg. C.

NOTE

Vapor pressure inside an LPG tank

depends on the ambient air temperature

outside the tank, not the amount of liquid

inside the tank. A tank that is ¾ full of

liquid propane at 80 deg. F will contain

the same vapor pressure as a tank that is

only ¼ full of liquid propane.

LPG’s relative ease of vaporization makes it an

excellent fuel for low-rpm engines on start-and-stop

operations. The more readily a fuel vaporizes the

more complete combustion will be.

Because propane has a low boiling point (-44F), and

is a low carbon fuel, engine life can be extended due

to less cylinder wall wash down and little, if any,

carbon build up.

100

150

200

250

300

-20 0 20 40 60 80 100 120 140

Temperature, deg F

Pressure, psig

LPG Tank Pressure VS Temperature

Compressed

Vapor

128 PSIG

Liquid

Propane

LPG Tank

Figure 2

Figure 3