Spherical liquefied petroleum gas storage tanks at an industrial refinery.
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Author: Atul Singla | Piping Engineering Expert | Updated: May 2026
Spherical Liquefied Petroleum Gas LPG storage tanks at a modern refinery

What is Liquefied Petroleum Gas or LPG?

Liquefied Petroleum Gas: A flammable hydrocarbon fuel mixture consisting primarily of propane and butane, maintained in a liquid state under moderate pressure to facilitate high-density storage and transport in compliance with NFPA 58 and ASME Section VIII standards.

In my 20-plus years of designing piping systems and refinery storage facilities, I have seen how Liquefied Petroleum Gas (LPG) behaves under varying thermal and pressure conditions. It is not just a simple fuel; it is a highly volatile, pressurized liquid that demands precise thermodynamic calculations and strict adherence to safety codes. When you are dealing with a substance that expands 270 times its liquid volume when vaporized, there is zero margin for error.

In this guide, I will break down the chemical composition, physical properties, and engineering design parameters that govern safe LPG handling. Whether you are designing a bulk terminal or specifying piping materials, understanding these fundamentals is critical to preventing catastrophic system failures.

Key Engineering Takeaways:

  • Understand the phase-change behavior of propane-butane mixtures under varying ambient temperatures.
  • Master the design pressure requirements for storage vessels according to ASME Section VIII Division 1.
  • Implement robust safety relief systems to prevent Boiling Liquid Expanding Vapor Explosions (BLEVE).



Interactive Engineering Quiz
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Question 1 of 3

How does the chemical composition of Liquefied Petroleum Gas (LPG)—specifically the ratio of propane to butane—affect its vapor pressure and the corresponding design requirements for storage vessels under ASME Section VIII?




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Thermodynamic & Chemical Foundations

Understanding the Thermodynamics of Liquefied Petroleum Gas

Liquefied Petroleum Gas Composition: A multi-component hydrocarbon mixture dominated by propane and butane, whose vapor pressure and boiling point vary dynamically based on the molar ratio of its constituents in accordance with Raoult’s Law.

LPG is primarily sourced from natural gas processing and crude oil refining. The exact ratio of propane to butane is adjusted seasonally and geographically to optimize vapor pressure. For instance, in colder climates, a higher propane concentration is required to maintain adequate vapor pressure at low temperatures. Conversely, in warmer regions, butane content is increased to prevent excessive pressure build-up inside storage vessels.

Let us look at the fundamental physical properties of the two primary components:

  • Propane (C3H8): Boiling point of -42 degrees Celsius (-44 degrees Fahrenheit) at atmospheric pressure. Vapor pressure at 37.8 degrees Celsius (100 degrees Fahrenheit) is approximately 1.3 MPa (190 psig).
  • Butane (C4H10): Boiling point of -0.5 degrees Celsius (31 degrees Fahrenheit) at atmospheric pressure. Vapor pressure at 37.8 degrees Celsius (100 degrees Fahrenheit) is approximately 0.36 MPa (52 psig).

To calculate the vapor pressure of an LPG mixture, we apply Raoult’s Law for ideal mixtures, though real-world applications require the Peng-Robinson equation of state for high-accuracy phase-equilibrium modeling. The simplified mixture vapor pressure (P_mix) can be estimated as:

P_mix = (x_propane * P_propane) + (x_butane * P_butane)

Where x represents the liquid mole fraction of each component, and P represents the pure component vapor pressure at the operating temperature.

When designing piping systems under ASME B31.3, we must account for the minimum design metal temperature (MDMT). If an LPG system undergoes rapid depressurization (auto-refrigeration), the temperature can drop to -42 degrees Celsius. This requires the use of impact-tested materials, such as ASTM A333 Grade 6 carbon steel, rather than standard ASTM A106 Grade B, to prevent brittle fracture.

CRITICAL SAFETY WARNING: Liquid Thermal Expansion

LPG has an extremely high coefficient of volumetric expansion. If liquid LPG is trapped between two closed valves without a thermal relief valve (TRV), a temperature rise of just 1 degree Celsius can increase the internal pressure by approximately 5 to 6 MPa (725 to 870 psi). This will inevitably lead to catastrophic piping rupture. Always install thermal relief valves set to discharge back to the storage vessel or a safe disposal system.

LPG molecular composition and phase change diagram showing propane and butane properties

Physical & Thermodynamic Properties of LPG Components
Property Propane (C3H8) Butane (C4H10) Reference Standard
Boiling Point (at 1 atm) -42.1 °C (-43.8 °F) -0.5 °C (31.1 °F) GPA Standard 2145
Vapor Pressure (at 37.8 °C / 100 °F) 1.31 MPa (190 psig) 0.36 MPa (51.6 psig) ASTM D1267
Liquid Density (at 15 °C) 506 kg/m³ 584 kg/m³ ASTM D1657
Flammability Limits in Air 2.1% to 9.5% (Vol) 1.8% to 8.4% (Vol) NFPA 325
Latent Heat of Vaporization (at boiling) 426 kJ/kg 385 kJ/kg ASHRAE Handbook

Technical Mapping & Specifications Matrix
System Component Primary Standard Key Design Parameter Material Specification
Storage Vessels (Bullet/Sphere) ASME BPVC Sec VIII Div 1 Design Pressure: Min 1.72 MPa (250 psig) ASTM A516 Grade 70 (Normalized)
Process Piping ASME B31.3 Flange Rating: ASME Class 300 minimum ASTM A333 Grade 6 / ASTM A105
Safety Relief Valves API Standard 520 / 526 Fire sizing scenario (Wetted surface area) Stainless Steel Trim (316 SS)
System Installation NFPA 58 Separation distances & vapor barriers N/A (Spatial Layout)

Site Verification Checklist for Liquefied Petroleum Gas Systems

Site Verification Checklist for Liquefied Petroleum Gas Systems

LPG System Commissioning: A systematic field verification protocol executed prior to introducing hydrocarbons to ensure mechanical integrity, instrument calibration, and emergency shutdown system functionality in compliance with NFPA 58.

Before introducing liquid LPG into any newly constructed or modified piping system, I always insist on a rigorous physical walkdown. The checklist below represents the minimum verification steps required to ensure the system is safe for commissioning.

Pre-Commissioning Field Checklist:


  • Hydrostatic Testing: Verify that hydrostatic testing has been completed at 1.5 times the design pressure in accordance with ASME B31.3, and that the system has been completely dried with nitrogen to a dew point of -40 degrees Celsius.

  • Electrical Grounding: Confirm that all piping flanges are bonded and the storage vessel grounding resistance is less than 10 Ohms to prevent static electricity accumulation.

  • Thermal Relief Valves (TRVs): Verify that TRVs are installed on all liquid-trappable segments and that their discharge lines are routed back to the vapor space of the storage vessel.

  • Emergency Shutdown Valves (ESVs): Test the fail-safe closure of all pneumatic and hydraulic ESVs. Ensure they close fully within 5 seconds of activation.

  • Gas Detection: Confirm that catalytic or infrared combustible gas detectors are calibrated and positioned at low points, as LPG vapors are heavier than air and will pool in low-lying areas.

Field Case Study: Real-World Application

Field Case Study: Real-World Application

The Problem: Vapor Lock and Cavitation in LPG Transfer Pumps

At a bulk LPG terminal in the Middle East, a set of multi-stage centrifugal transfer pumps experienced severe cavitation and mechanical seal failures during summer operations when ambient temperatures reached 48 degrees Celsius. The system was transferring a 60/40 propane/butane mix from mounded storage vessels to road tankers. The high ambient heat caused the LPG inside the suction piping to flash into vapor, resulting in vapor lock. The Net Positive Suction Head Available (NPSHa) dropped below the Net Positive Suction Head Required (NPSHr), causing immediate pump degradation.

The Outcome: Hydraulic Optimization and Vapor Return Line Redesign

As the lead piping consultant, I redesigned the suction piping configuration to minimize friction losses. We increased the suction line size from 4 inches to 6 inches, reducing the fluid velocity and pressure drop. Additionally, we installed a dedicated vapor-equalizing line between the road tanker and the storage vessel to balance the pressures during transfer. Insulation and reflective white coatings were applied to all exposed suction piping to minimize solar heat gain. These modifications increased the NPSHa by 1.2 meters, completely eliminating cavitation and extending the mechanical seal life from 3 weeks to over 3 years.

Direct Recommendation: When designing LPG pumping systems, always calculate NPSHa under the worst-case summer ambient temperatures. Never rely on nominal fluid properties; use the maximum vapor pressure of the specific hydrocarbon blend to ensure the liquid remains subcooled throughout the suction path.

Frequently Asked Engineering Questions

What is the difference between LPG and LNG?
LPG (Liquefied Petroleum Gas) consists primarily of propane and butane, which can be liquefied at moderate pressures (0.2 to 1.5 MPa) at ambient temperatures. LNG (Liquefied Natural Gas) is almost entirely methane and must be cryogenically cooled to -162 degrees Celsius to remain liquid at atmospheric pressure. This makes LPG much easier and cheaper to store and transport in smaller quantities.
Why is an odorant added to LPG, and what chemical is used?
Naturally, LPG is completely odorless and colorless. Because it is highly flammable and heavier than air, leaks can accumulate undetected in low areas, creating a severe explosion hazard. To mitigate this, an odorant—typically Ethyl Mercaptan—is added at a concentration of approximately 1.5 to 2.0 lbs per 10,000 gallons, allowing human detection at concentrations well below the Lower Flammable Limit (LFL).
What are the design pressure requirements for LPG storage vessels?
According to NFPA 58 and ASME Section VIII, LPG storage vessels must be designed for a minimum working pressure of 1.72 MPa (250 psig) to safely contain pure propane at the maximum expected ambient temperature of 46 degrees Celsius (115 degrees Fahrenheit).
How does temperature affect the liquid level in an LPG tank?
LPG expands significantly as temperature increases. For this reason, tanks are never filled to 100% capacity. They are typically filled to a maximum of 80% to 85% liquid volume at 15 degrees Celsius. This leaves a vapor space (ullage) to accommodate liquid expansion without hydrostatic overpressurization of the vessel.
What is a BLEVE, and how is it prevented in LPG installations?
A BLEVE (Boiling Liquid Expanding Vapor Explosion) occurs when an LPG vessel is exposed to external fire, weakening the steel shell above the liquid level. The vessel ruptures catastrophically, releasing superheated liquid that flashes instantly into vapor and ignites. Prevention methods include passive fireproofing, water spray deluge systems designed per NFPA 15, and mounding the storage vessels under sand.
Which piping materials are approved for LPG service?
For metallic piping, ASTM A106 Grade B or ASTM A333 Grade 6 (for low-temperature auto-refrigeration scenarios) seamless carbon steel is standard. Threaded joints are restricted to small sizes (typically 2 inches and below) and must use Schedule 80 minimum. Flanged connections must use spiral wound gaskets with a stainless steel winding and a flexible graphite filler.

Atul Singla - Piping EXpert

Atul Singla

Senior Piping Engineering Consultant

Bridging the gap between university theory and EPC reality. With 20+ years of experience in Oil & Gas design, I help engineers master ASME codes, Stress Analysis, and complex piping systems.

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