LPG (Propane) Vaporisation – LPG Liquid to Vapor Conversion
LPG liquid to vapor conversion, or vaporisation, occurs every time you turn on one of your gas appliances, the LPG in your gas bottles starts to boil?
If you could see though the steel, you would also notice that it looks just like water boiling.
The big difference is that it happens at -42°C or -44°F.
This is vaporisation, which is how LPG – propane – goes from liquid to vapour (gas).
LPG – Propane & Butane Liquid to Vapor Conversion
LPG (propane and/or butane) turns goes through LPG liquid to vapor conversion when it boils.
However, propane and butane boil at different temperatures.
Propane boils at a lower temperature than butane, making it more suitable for cold climates.
On a cold winter day, outdoor butane cylinders may not reach their boiling temperature, leaving the user with no gas.
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LPG – Propane Turns
from Liquid or Gas?
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LPG (1atm)
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Liquid
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Vapour (Gas)
|
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Propane
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< -42°C or
< -43.6ºF
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≥ -42°C or
≥ -43.6ºF
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Butane
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< -0.4°C or
< 31.28ºF
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≥ -0.4°C or
≥ 31.28ºF
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How LPG Liquid to Vapor Conversion Happens – LPG (Propane) Vaporisation
Liquid LPG boils and turns back into gas vapour when you release some of the pressure in the gas bottle, by turning on your gas appliance.
The LPG vaporisation rate and pressure in the bottle also increases with temperature, as explained below.
How LPG-Propane Boils
To boil, the liquid LPG draws heat from the steel walls of the gas bottle which, in turn, get heat from the ambient air.
As with water, the more heat that is applied, the more rapidly it boils, increasing the LPG vaporisation rate.
As the steel of the bottle draws heat from the ambient air heat, cold weather will slow down the LPG vaporisation rate.
LPG liquid to vapor conversion also makes the gas bottle feel colder than the ambient temperature.
The gas bottle gets even colder when you are actually in the process of using the gas.
LPG Boiling Point
Water boils at 100°C or 212°F, becoming a gas (steam).
In contrast, LPG (propane) boils at -42°C or -44°F, becoming LPG vapour.
LPG stays liquid because it is under pressure in a gas cylinder.
As a liquid, it looks a lot like water.
It is colourless and odourless in its natural state.
Unlike water, 1 kilogram of LPG does NOT equal 1 litre of liquid LPG.
LPG density or specific gravity is about half that of water, at 0.51.
In Australia, where LPG is propane, 1kg of LPG has a volume of 1.96L.
Conversely, 1L of LPG weighs 0.51kg.
LPG Vaporisation Rate Must Match Consumption
The amount of gas that the appliance or appliances are drawing from the gas bottles must be matched by the LPG vaporisation rate.
If a gas bottle ices up regularly, it simply means that the vessel is too small for the vaporisation load placed on it.
Switching to a larger vessel can provide a higher LPG vaporisation rate.
Heat is absorbed through the vessel shell and into the liquid.
This is known as the “wetted area”.
The larger the tank or the fuller the tank, the more gas that can be vaporised at a given temperature.
Vaporisation tables (as shown below) are used to match the required vaporisation rates to the corresponding vessel size.
LPG vaporisation rate tables show the maximum continuous LPG vaporisation rates, in MJ/hr, at different ambient temperatures for each available vessel size.
In instances where a larger vessel is not an option, the only alternative is to supply some artificial means of increasing vaporisation.
The units used are very appropriately call vapourisers.
Lower Fill Equals Less Vaporisation
Keeping in mind the concept of “wetted area”, the maximum rate of vaporisation drops as the fill level drops.
Larger gas bottles have higher vaporisation than small gas bottles e.g. 45kg vs 9kg.
If there is less LPG in the vessel, there is less contact area between the liquid LPG and the steel that provides the heat for vaporisation.
Depending on the consumption rate of the attached appliances, this may make no difference at all, if the consumption rate is low.
However, if the consumption rate is high, the vaporisation rate may not keep pace with the consumption.
Depending on the appliance, this starvation may cause the appliance to function poorly or not at all.
LPG (Propane) Vaporisation Rate Table
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LPG Vaporisation Chart of Standard Size Vessels |
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Nominal LPG Vessel Size |
Volume in Water Capacity |
Maximum Continuous Vapourisation Rates for LPG (propane) at Indicated Ambient Temperatures.
(in MJ/hr)
at 30% full
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Weight
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Volume
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-18˚C
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-7˚C
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-1˚C
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4˚C
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10˚C
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16˚C
|
|
45kg
|
108L
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46
|
92
|
115
|
138
|
161
|
184 |
|
90kg
|
215L
|
70
|
140
|
175
|
211
|
246
|
281
|
|
190kg
|
499L
|
106 |
219
|
274
|
328
|
383
|
438
|
|
0.5t
|
1.35kL
|
235
|
469
|
587
|
704
|
821
|
939
|
|
1.0t
|
2.2kL
|
327
|
653
|
816
|
980
|
1143
|
1306
|
|
2.0t
|
4.3kL
|
545
|
1090
|
1363
|
1636
|
1908
|
2181
|
|
2.5t
|
6.7kL
|
826
|
1652
|
2065
|
2478
|
2891
|
3304
|
|
3.0t
|
7.5kL
|
921
|
1841
|
2302
|
2762
|
3222
|
3683
|
|
10t
|
23kL
|
1616
|
3231
|
4039
|
4847
|
5655
|
6463
|
|
13t
|
33kL
|
2214
|
4482
|
5603
|
6724
|
7844
|
8965
|
|
17t
|
43kL
|
2502
|
5003
|
6300
|
7505
|
8756
|
10006
|
|
21t
|
53kL
|
3492
|
6984
|
8730
|
10476
|
12222
|
13968
|
|
25t
|
62kL
|
3502
|
7004
|
8755
|
10507
|
12258
|
14009
|
|
33t
|
81kL
|
4503
|
9006
|
11257
|
13509
|
15760
|
18011
|
|
40t
|
100kL
|
5504
|
11007
|
13759
|
16511
|
19262
|
22014
|
LPG Vaporisation Rate Table Notes:
1. As a simple rule of thumb, when using vessels of say 2.75 or 5.1kL capacities, simply extrapolate between the two nearest size vessels but biasing your calculations on the conservative side. Always consult your supplier’s technical representative for advice.
2. Always check with your supplier’s technical representative that the above LPG vapourisation rates are correct for the particular vessel you have designated.
3. For sites requiring a high vapourisation rate but it is not cost effective to install larger and/or multiple vessels, consider using a vapouriser.
4. Vessels above 3 tonnes or over 7.5kL will be custom designed by supplier to suit customer needs. Figures provided are only rough estimates, based on previous designs.
Condensation Turns to Ice
Initially, condensation forms when the temperature of the gas bottle or regulator drops below the dew point.
This is exactly the same as the condensation you get on a humid day with a glass of ice water.
Under the right conditions, when you are using gas very rapidly, ice can even form on the gas bottle!
LPG Vapour vs Gas
Let’s also clarify the terminology.
The two terms, LPG vapour and gas, are used interchangeably by most people in reference to LPG.
LPG vapour (or vapor in American spelling) is the more technically correct term for LPG, as it is in gaseous and liquid equilibrium at room temperature.
It can be turned back into a liquid by increasing the pressure on it without reducing the temperature.
A gas has one defined state at room temperature.
So, vapours are gases however not all gases are vapours
Gas Bottles Contain Liquid and Gas
The LPG vapour is held in the top of the bottle and the liquid LPG at the bottom, as shown in the accompanying image.
Almost all of the uses for LPG involve the use of the LPG vapour, not the liquefied gas.
LPG Vapour Pressure Varies with Temperature
As previously mentioned, when LPG is stored in a gas bottle, it is under pressure.
The term “pressure” refers to the average force per unit of area that the gas exerts on the inside walls of the gas bottle.
(LPG Vapour Pressure-Temperature Chart shown)
LPG vapour pressure is measured in kilopascals (kPa) or pounds per square inch (psi).
“Bar” is yet another unit of measure for pressure.
1 Bar = 100 kPa, so it is metric based but not an SI unit of measure.
LPG vapour pressure can vary greatly based on temperature, as shown in the chart.
The level of fill in the gas bottle comes into play when the LPG is being used, as it affects the LPG vaporisation rate.
As LPG is a liquefied gas, the LPG vapour pressure inside the cylinder will remain the same from full until the last of the liquid LPG is vaporised.
Then the LPG vapour pressure will fall quickly as the last of the LPG vapour is used, as well.
Final Thoughts
Understanding vaporisation helps explain LPG liquid to vapor conversion.
It is particularly important for larger commercial installations where the rates of gas consumption are higher.
The technical staff matches the gas load to the appropriate vessel size and, if required, a vapouriser.
Eric Hahn has over a decade of experience in the LPG industry and has become a key figure in shaping how LPG is marketed and communicated. As the creator of one of the world’s first LPG blogs, Eric has authored over 200 technical posts, helping educate and inform the industry and consumers.
Eric has served on multiple committees for Gas Energy Australia and the World LPG Association (WLPGA), contributing to important discussions and advancements within the global LPG sector. He has presented at WLPGA Annual Conferences, sharing his expertise as a speaker, panellist, and panel chair.
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Steve Reynolds
Technical Consultant
Steve Reynolds is a leading expert in the LPG industry with over 22 years of experience. As part of the national management team at ELGAS, Steve ensures the safe and efficient storage, handling, and transportation of LPG. He serves as the lead investigator for incidents and collaborates with authorities on industry developments.
Steve is a technical advisor to Standards Australia and Gas Energy Australia (GEA), and an active member of the World LPG Association (WLPGA), contributing to global standards and technical reviews. He holds a BSc. (Hons) in Industrial Chemistry from UNSW and has held senior safety and technical roles at ELGAS, making him a trusted authority in LPG safety and standards.