Gas Transportation & Storage

CNG Tube Trailers & Cascade Systems

Calculate compressed natural gas volumes for tube trailers, design cascade storage systems, and plan virtual pipeline logistics using real gas equations with pressure-dependent compressibility factors.

Launch Calculator Cascade Design

Standard CNG Pressure

3,000-3,600 psig

DOT-rated cylinders for CNG storage and transport.

Tube Trailer Capacity

150-350 MCF

Typical deliverable volume per trailer load.

Compressibility Factor

Z = 0.82-0.88

At 3600 psig, 60°F for pipeline quality gas.

Contents

Use this guide when you need to:

  • Calculate deliverable CNG volumes from tube trailers
  • Design cascade storage for CNG stations
  • Plan virtual pipeline trucking operations

1. CNG Transport Overview

Compressed Natural Gas (CNG) transport via tube trailers enables "virtual pipelines" to deliver gas where physical pipelines are unavailable or uneconomical. Understanding real gas behavior at high pressures is critical for accurate volume calculations.

Virtual Pipeline

Remote gas delivery

Trucked CNG to industrial users, drilling rigs, or remote communities without pipeline access.

CNG Stations

Vehicle fueling

Fleet fueling stations using cascade storage to dispense CNG to vehicles.

Peak Shaving

Demand management

Supplemental gas supply during high-demand periods or pipeline constraints.

Emergency Supply

Backup gas source

Temporary gas supply during pipeline outages or maintenance.

Regulatory Framework

Regulation Scope Key Requirements
DOT 49 CFR Part 178 Compressed gas cylinders Cylinder design, testing, marking (DOT-3AA, DOT-3AAX)
DOT 49 CFR Part 180 Cylinder requalification Hydrostatic testing every 5 years, visual inspection
NFPA 52 CNG vehicular fuel systems Station design, cascade sizing, safety systems
SAE J2601 CNG fueling protocols Fast-fill temperature compensation, pressure targets
CGA C-6.4 Tube trailer operations Loading, unloading, transport safety procedures
Why real gas matters: At CNG operating pressures (3000-3600 psig), natural gas deviates significantly from ideal gas behavior. The compressibility factor Z can be 0.82-0.88, meaning actual gas volume is 12-18% less than ideal gas law predicts. Accurate Z-factor calculation is essential for inventory management, custody transfer, and system sizing.

2. Real Gas Calculations

CNG volume calculations require the real gas equation of state, which accounts for molecular interactions at high pressures through the compressibility factor Z.

Real Gas Equation of State

Real Gas Law: PV = ZnRT Rearranged for standard volume: V_std = V_actual × (P_actual / P_std) × (T_std / T_actual) × (Z_std / Z_actual) Where: V_std = Volume at standard conditions (SCF) V_actual = Physical container volume (ft³) P_actual = Absolute pressure (psia) P_std = Standard pressure = 14.73 psia (GPA) T_actual = Absolute temperature (°R = °F + 459.67) T_std = Standard temperature = 519.67°R (60°F) Z_actual = Compressibility factor at actual conditions Z_std ≈ 1.0 (at standard conditions)

Compressibility Factor (Z-Factor)

The Z-factor accounts for deviation from ideal gas behavior and is calculated using the Dranchuk-Abou-Kassem correlation, which approximates the Standing-Katz chart:

Pseudo-Critical Properties (Kay's Rule): For natural gas with specific gravity SG (air = 1.0): T_pc = 170.5 + 307.3 × SG (°R) P_pc = 709.6 - 58.7 × SG (psia) Reduced Properties: T_r = T / T_pc (reduced temperature) P_r = P / P_pc (reduced pressure) Example: Pipeline quality gas (SG = 0.60) at 3600 psig, 60°F T_pc = 170.5 + 307.3 × 0.60 = 354.9°R P_pc = 709.6 - 58.7 × 0.60 = 674.4 psia P_abs = 3600 + 14.7 = 3614.7 psia T_abs = 60 + 459.67 = 519.67°R T_r = 519.67 / 354.9 = 1.46 P_r = 3614.7 / 674.4 = 5.36 From Standing-Katz chart or DAK correlation: Z ≈ 0.85

[Image: Standing-Katz Compressibility Factor Chart]

Z-factor vs. reduced pressure for various reduced temperatures

Z-Factor Reference Table

Compressibility factors for pipeline quality natural gas (SG = 0.60) at 60°F:

Pressure (psig) P_abs (psia) P_r Z-Factor Deviation from Ideal
500 514.7 0.76 0.945 -5.5%
1000 1014.7 1.50 0.895 -10.5%
2000 2014.7 2.99 0.850 -15.0%
2400 2414.7 3.58 0.845 -15.5%
3000 3014.7 4.47 0.850 -15.0%
3600 3614.7 5.36 0.865 -13.5%
4500 4514.7 6.69 0.905 -9.5%

Deliverable Volume Calculation

Tube Trailer Deliverable Volume: The deliverable volume is the difference between gas at fill pressure and gas remaining at delivery (heel) pressure: V_deliverable = V_fill - V_heel Where: V_fill = V_tank × (P_fill / P_std) × (T_std / T_fill) × (Z_std / Z_fill) V_heel = V_tank × (P_heel / P_std) × (T_std / T_heel) × (Z_std / Z_heel) Example: 9000 gallon trailer, 3600 psig fill, 100 psig heel, 60°F V_tank = 9000 gal × 0.13368 ft³/gal = 1203 ft³ At fill (3600 psig, Z = 0.865): V_fill = 1203 × (3614.7/14.73) × (519.67/519.67) × (1.0/0.865) V_fill = 1203 × 245.4 × 1.0 × 1.156 = 341,300 SCF At heel (100 psig, Z = 0.995): V_heel = 1203 × (114.7/14.73) × (519.67/519.67) × (1.0/0.995) V_heel = 1203 × 7.79 × 1.0 × 1.005 = 9,420 SCF Deliverable = 341,300 - 9,420 = 331,880 SCF = 331.9 MCF

3. Tube Trailer Specifications

CNG tube trailers consist of multiple high-pressure cylinders mounted on a road-legal trailer. Design and construction follow DOT 49 CFR Part 178 requirements.

Cylinder Types

DOT Type Material Service Pressure Weight (per SCF) Notes
DOT-3AA Seamless steel 2400-3600 psig 0.25-0.30 lb/SCF Most common, cost-effective
DOT-3AAX High-strength steel 3600-5000 psig 0.22-0.26 lb/SCF Higher pressure rating
DOT-3T Seamless steel 2400-3600 psig 0.25-0.28 lb/SCF Thick-wall design
Composite (Type 3) Al liner + carbon wrap 3600-5000 psig 0.10-0.15 lb/SCF Lightweight, higher cost
Composite (Type 4) Plastic liner + carbon wrap 3600-5000 psig 0.08-0.12 lb/SCF Lightest, premium cost

Typical Tube Trailer Configurations

[Image: CNG Tube Trailer Schematic]

Side view showing cylinder arrangement, manifold, and valve systems

Configuration Water Capacity Deliverable Volume* Tare Weight Payload Weight
Small (6 tubes) 4,000-5,000 gal 140-180 MCF 18,000-22,000 lb 6,500-8,500 lb
Standard (8-10 tubes) 6,500-8,000 gal 230-290 MCF 25,000-32,000 lb 10,500-13,500 lb
Large (12-16 tubes) 9,000-12,000 gal 320-430 MCF 35,000-45,000 lb 14,500-20,000 lb
Jumbo (composite) 15,000-20,000 gal 530-720 MCF 25,000-35,000 lb 24,000-32,000 lb

*At 3600 psig fill, 100 psig heel, 60°F, SG = 0.60

Energy Equivalents

CNG Energy Conversions: Natural gas heating value: 1,020 BTU/SCF (pipeline quality) 1 MCF natural gas = 1,020,000 BTU = 1.02 MMBTU 1 GGE (gasoline gallon equivalent) = 126.67 SCF = 129,200 BTU (Based on 114,000 BTU/gal gasoline × 1.134 efficiency factor) 1 DGE (diesel gallon equivalent) = 142.7 SCF = 145,600 BTU (Based on 128,700 BTU/gal diesel) Example: 330 MCF tube trailer load Energy content: 330 × 1.02 = 336.6 MMBTU GGE equivalent: 330,000 / 126.67 = 2,605 GGE DGE equivalent: 330,000 / 142.7 = 2,312 DGE This equals approximately: - 2,600 gallons of gasoline - 2,300 gallons of diesel - 73 fill-ups of a CNG vehicle with 35 GGE tank

Loading and Unloading

  • Fill time: 2-4 hours depending on compressor capacity and cascade pressure
  • Unload time: 30 minutes to 4 hours depending on pressure differential and destination equipment
  • Fill connection: NGV1 or custom high-flow couplings (typical 1" or 1.5")
  • Safety systems: Excess flow valves, manual shutoffs, pressure relief devices
  • Grounding: Required during all transfer operations per NFPA 52

4. Cascade Storage Systems

Cascade storage uses multiple pressure banks to efficiently transfer CNG to vehicle tanks. The cascade principle minimizes the compressor work required to achieve full vehicle tank pressure.

Cascade Operating Principle

[Image: 3-Bank Cascade System Diagram]

Showing High/Medium/Low banks, priority panel, and dispenser connections

Cascade Filling Sequence: 1. LOW BANK first (1200-2000 psi range) - Vehicle tank pressure rises from empty to ~1800 psi - Low bank pressure drops as gas transfers 2. MEDIUM BANK second (2000-2800 psi range) - Continues filling from low bank ending pressure - Vehicle reaches ~2600 psi 3. HIGH BANK last (2800-3600 psi range) - Completes fill to target pressure (3000-3600 psi) - Highest pressure bank used least, preserving capacity Why cascade is efficient: Without cascade (direct from 3600 psi source): - All gas transfers against full pressure differential - 100% of gas comes from high-pressure storage - Compressor must refill entire storage to 3600 psi With 3-bank cascade: - ~40% of gas comes from low bank (1200→1800 psi range) - ~35% from medium bank (1800→2600 psi range) - ~25% from high bank (2600→3600 psi range) - Average compression ratio reduced by ~35%

Cascade Efficiency

Cascade efficiency accounts for gas that cannot be delivered due to pressure equalization limits:

Cascade Utilization Factor: η_cascade = V_delivered / V_theoretical Typical values: - 3-bank cascade: 82-87% efficiency - 4-bank cascade: 85-90% efficiency - 5-bank cascade: 87-92% efficiency Factors affecting efficiency: 1. Minimum bank pressure (heel pressure) - Lower heel = more deliverable gas - Typical minimum: 100-300 psig 2. Vehicle tank size - Larger tanks extract more gas per fill - Small tanks (5 GGE) = lower efficiency 3. Fast-fill temperature rise - Gas heats during rapid transfer - SAE J2601 compensates with reduced pressure target - Can reduce effective fill by 5-10% 4. Equalization losses - Small amounts of gas remain in lines - Estimated 1-3% per fill cycle

Cascade Sizing Guidelines

Station Type Daily Throughput Cascade Size Banks Compressor
Small fleet 50-100 GGE 500-1,000 gal 2-3 25-50 SCFM
Medium fleet 100-300 GGE 1,000-2,500 gal 3 50-100 SCFM
Large fleet 300-1,000 GGE 2,500-6,000 gal 3-4 100-200 SCFM
Public fast-fill 500-2,000 GGE 4,000-10,000 gal 3-4 150-400 SCFM
High-volume 2,000+ GGE 10,000+ gal 4-5 300+ SCFM

Vehicle Fill Estimation

Fills per Cascade Cycle: N_fills = (V_cascade × η_cascade) / V_vehicle Where: V_cascade = Total cascade storage (SCF at STP) η_cascade = Cascade efficiency (typically 0.85) V_vehicle = Average vehicle tank size (SCF) Example: 3000 gallon cascade, 35 GGE vehicle tanks V_cascade = 3000 gal × 0.13368 ft³/gal × (3614.7/14.73) × (1/0.865) V_cascade = 114,000 SCF at 3600 psig Deliverable (3600→100 psig): ~110,000 SCF Vehicle tank: 35 GGE × 126.67 SCF/GGE = 4,433 SCF N_fills = (110,000 × 0.85) / 4,433 = 21 vehicle fills At 10 fills/hour average, cascade provides ~2 hours of operation before compressor must refill storage.

5. Virtual Pipeline Logistics

Virtual pipelines use tube trailers to deliver CNG where physical pipelines are not available. Logistics planning considers fleet size, delivery frequency, and operating costs.

Virtual Pipeline Applications

Industrial Users

Remote manufacturing

Factories, food processing, heat treating operations off the pipeline grid.

Drilling Operations

Rig fuel & frac

Dual-fuel drilling rigs, hydraulic fracturing operations.

Remote Communities

Distributed supply

Island, arctic, or mountainous communities without pipeline access.

Pipeline Bypass

Maintenance support

Temporary gas supply during pipeline repairs or capacity constraints.

Fleet Sizing Calculation

Required Number of Trailers: N_trailers = ceiling(D_daily / V_deliverable) × (T_cycle / T_operating) Where: D_daily = Daily gas demand (MCF/day) V_deliverable = Deliverable volume per trailer (MCF) T_cycle = Round trip cycle time (hours) T_operating = Operating hours per day Example: 500 MCF/day demand, 4-hour cycle, 12-hour operation Trailer capacity: 330 MCF deliverable Trips needed: 500 / 330 = 1.52 trips/day Trips per trailer: 12 / 4 = 3 trips/day N_trailers = ceiling(1.52 / 3) = 1 trailer minimum With 20% contingency: 2 trailers recommended Fleet utilization: Actual trips: 1.52 trips/day Capacity: 2 trailers × 3 trips = 6 trips/day Utilization: 1.52 / 6 = 25% (excess capacity for growth/contingency)

Operating Cost Estimation

Cost Component Typical Range Units Notes
Fuel (diesel) $0.50 - 0.80 $/MCF delivered Varies with distance, fuel price
Driver labor $0.30 - 0.60 $/MCF delivered Union vs. non-union, region
Trailer lease $0.20 - 0.40 $/MCF delivered ~$3,000-5,000/month lease
Tractor cost $0.15 - 0.30 $/MCF delivered Lease + maintenance
Compression $0.10 - 0.25 $/MCF delivered At loading station
Insurance/permits $0.05 - 0.15 $/MCF delivered Hazmat, liability coverage
Total delivered cost $1.30 - 2.50 $/MCF Excluding gas commodity

Economics vs. Pipeline

Virtual Pipeline Break-Even Analysis: Virtual pipeline is typically competitive when: - Distance to pipeline: > 5-10 miles - Demand: 100-2,000 MCF/day - Duration: < 3-5 years Cost comparison (approximate): Pipeline construction: $50,000 - $200,000 per mile Pipeline operating: $0.10 - 0.30 $/MCF Virtual pipeline: $1.30 - 2.50 $/MCF delivered Break-even calculation: For 500 MCF/day demand, 10 miles from pipeline: Pipeline option: - Construction: 10 mi × $100,000/mi = $1,000,000 - Operating: 500 MCF × $0.20 × 365 = $36,500/year - 10-year total: $1,365,000 Virtual pipeline: - Delivered cost: 500 MCF × $1.80 × 365 = $328,500/year - 10-year total: $3,285,000 Break-even: ~4 years If demand expected < 4 years: virtual pipeline wins If demand expected > 4 years: pipeline wins
Virtual pipeline advantages: Quick deployment (weeks vs. years for pipeline), scalable capacity, no right-of-way issues, relocatable assets. Best for temporary demands, remote locations, or as a bridge until pipeline infrastructure is built.

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