Compressor Station Layout Fundamentals | Equipment Spacing & Plot Plan Design

1. Layout Principles

The layout of a compressor station depends on location, proximity to homes and businesses, vegetation, predominant wind direction, and land contour. Equipment placement must minimize impact on the local environment while providing safe and efficient operations.

Primary Design Objectives

Fire protection: Adequate access for fire fighting equipment and personnel
Operations: Efficient access for routine operations and monitoring
Maintenance: Space for equipment removal, laydown, and crane access
Personnel safety: Protection from hazards and clear evacuation routes
Equipment protection: Separation from ignition sources and hazardous areas
Adjacent properties: Prevention of danger or nuisance to neighbors

Aerial plot plan of compressor station showing compressor building, control building, aerial coolers, condensate tanks with containment dike, blowdown stack, pig launcher/receiver, inlet/outlet headers, and perimeter fence with gates — Station layout: Control building upwind, blowdown stack 100 ft minimum from buildings, condensate tanks in diked area with 50 ft separation.

General Layout Considerations

Future expansion: The compressor building shall be located to allow addition of future compression and/or gas cooling
Wind direction: Vents shall be placed so hydrocarbon vapors do not pass over potential ignition sources
Site security: Local conditions may require increased or decreased spacing from property line
Adjacent development: Consider current and future proximity of homes, businesses, and public areas
Terrain: Use natural features for noise screening and drainage

Development Planning: Where adjoining land is undeveloped but subject to future development, adequate spacing should be provided. Consider zoning requirements and planned developments when establishing property boundaries.

Access Requirements

The facility layout must provide:

Access to individual equipment for maintenance while adjacent facilities remain in operation
Sufficient exit doors from compressor building to provide escape from any point
Emergency vehicle access around the perimeter of major equipment areas
Crane access for equipment removal and replacement

2. Equipment Spacing Requirements

Minimum spacing requirements provide adequate safety margins for operations, maintenance, fire protection, and emergency response. These distances are based on industry practice and regulatory requirements.

Building Separation Distances

From	To	Minimum Distance
Compressor building	Control building	50 ft
Compressor building	Shop/warehouse	50 ft
Compressor building	Boiler building	50 ft
Compressor building	General office building	50 ft

Note: Control building should preferably be located on the free air and exhaust side of the compressor building.

Vent and Blowdown Distances

System	Minimum Distance from Compressor Building
Blowdown vent header discharge	100 ft
Compressor unit piping vent system	100 ft
Cranking gas vent header	100 ft

Storage Tank Distances

Equipment	Minimum Distance	From
Pipeline condensate storage tanks	50 ft	Any building
Pipeline condensate storage tanks	50 ft	Operating equipment
Pipeline condensate storage tanks	50 ft	Source of ignition

Safety Factor Considerations: These are minimum distances. Greater separation may be required based on consequence analysis, local regulations, or specific hazards. Always evaluate site-specific conditions and consult with safety professionals.

Property Line Considerations

Distance from facility to property line depends on:

Type of facility nearest the boundary
Nature of adjacent property (industrial vs. residential)
Local noise ordinances and zoning requirements
Potential for light, odor, and noise impacts

In residential areas, additional space for screening may be required to mitigate light, noise, and odor impacts.

3. Emergency Shutdown (ESD) Requirements

Per 49 CFR 192, each compressor station (except unattended field stations of 1,000 HP or less) must have an emergency shutdown system meeting specific requirements.

ESD System Capabilities

The emergency shutdown system must:

Block gas out of the station and blow down the station piping
Discharge gas from blowdown piping at a location where gas will not create a hazard
Provide means for shutdown of gas compressing equipment, gas fires, and electrical facilities in the vicinity of gas headers

ESD Actuation Points

Requirement	Specification
Number of actuation locations	Minimum 2 locations
Location requirement	Outside the gas area of the station
Placement (fenced station)	Near exit gates
Placement (unfenced station)	Near emergency exits
Maximum distance from station	500 ft from station limits
Distance from compressor building	Minimum 25 ft

Electrical Circuits Exceptions

The following electrical circuits may remain energized during ESD:

Emergency lighting: Circuits that supply lighting required to assist personnel in evacuating the compressor building and gas header area
Equipment protection: Circuits needed to protect equipment from damage

Fuel Gas Shutdown

The compressor building fuel gas shutdown system shall have block and bleed valves located outside of the compressor building.

Distribution System Supply: If a compressor station supplies gas directly to a distribution system with no other adequate source available, the ESD system must be designed so it will not function at the wrong time and cause an unintended outage.

Automatic ESD Triggers (Offshore/Inland Navigable Waters)

For platforms located offshore or in inland navigable waters, the ESD must actuate automatically for:

Unattended Compressor Stations:

Gas pressure reaches MAOP + 15%
Uncontrolled fire occurs on platform

Compressor Stations in Buildings:

Uncontrolled fire occurs in building
Gas concentration reaches 50% or more of LEL in a building with ignition source

Class 1, Group D Equipment: An electrical facility conforming to Class 1, Group D of the National Electrical Code is not considered a source of ignition for the 50% LEL trigger requirement.

4. Noise Considerations

FERC requires noise estimates for any new or modified facility. Noise is often the controlling factor in equipment placement and orientation.

FERC Noise Limits

Parameter	Limit	Description
L_dn	55 dBA	Day-night equivalent sound level at NSA
L_eq (equivalent)	48.6 dBA	Continuous equivalent for 24-hour operation

Note: The 55 dBA L_dn limit applies to station contribution only at noise-sensitive areas (NSAs). Environmental noise from traffic, aircraft, etc. is excluded.

Noise-Sensitive Areas (NSAs)

NSAs include:

Residences
Schools
Hospitals
Churches
Playgrounds
Farms
Camping facilities

Layout Strategies for Noise Control

Maximize distance from noise-generating equipment to NSAs
Consider prevailing wind direction (sound travels farther downwind)
Use terrain features as natural noise barriers
Position buildings or trees as noise screens
Orient equipment exhaust away from NSAs

Noise Abatement Options

Source	Abatement Method
Turbine inlet/exhaust	Additional silencing
Gas engine exhaust	Hospital grade silencers
High-velocity piping/valves	Sound insulation or burial
Aerial coolers	Reduced fan speeds, acoustical hoods
Compressor building	Acoustical wall/roof insulation

Noise Survey Requirements

New facilities: Baseline survey of environmental noise before construction
Modified facilities: Survey with existing facilities at full load (avoid unusual/extraneous noise)
Modeling: Expected noise from additions modeled over baseline

Grandfathered Equipment: FERC noise limits apply to new or modified compression equipment only. However, total station noise must not increase due to additions. This no-increase policy is enforced to the tenth of a decibel.

5. Air Emissions

Air emissions must be evaluated early in planning for any horsepower addition or modification. Emission considerations can significantly impact driver selection and project costs.

Emission Evaluation Checklist

Existing emissions and permit conditions
Attainment vs. non-attainment area status
NOx, CO, and unburned hydrocarbon levels
Anticipated emissions from proposed addition
Control requirements for acceptable emission levels
Existing horsepower that can be shut down/removed
Project timing vs. permit acquisition time

Major Source Thresholds (MST)

Area Status	MST	Notes
Attainment	250 T/yr	Any pollutant
Non-attainment (marginal)	100 T/yr	Varies by pollutant
Non-attainment (severe)	25 T/yr	Most restrictive

Title V Permit Triggers

Pollutant	Attainment Area	Non-attainment Area
NOx	100 T/yr	50 or 25 T/yr
CO	100 T/yr	50 or 25 T/yr

Typical Driver Emission Levels

Driver Type	NOx	CO
Gas turbine (dry low NOx)	25 ppmvd @ 15% O₂	Varies
Clean-burn gas engine	0.7 g/bhp-hr	1.9 g/bhp-hr
Electric motor	Zero	Zero

New Source Review: If PTE exceeds MST or Significant Emission Rate (SER), the facility is subject to New Source Review (NSR) and BACT/LAER review. Early involvement of environmental specialists is critical.

6. Driver Selection Impact on Layout

The choice of prime mover/compressor package affects facility layout, spacing requirements, and infrastructure needs.

Common Driver/Compressor Combinations

Driver	Compressor	Layout Considerations
Electric motor	Reciprocating	Substation space, cooling requirements
Electric motor	Centrifugal	Higher flow, smaller footprint
Gas engine	Reciprocating	Exhaust stack, fuel gas system, noise
Gas turbine	Centrifugal	Inlet air, exhaust, larger setbacks

Selection Factors

Pipeline conditions: Suction/discharge pressures, gas volume, flow variability
Operating philosophy: Base load vs. swing/peaking service
Existing equipment: Compatibility with maintenance, spare parts
Control requirements: Manned vs. remote operation
Operating costs: Fuel/electricity costs, efficiency
Installation cost: Package cost plus utilities, buildings, site work
Delivery time: Compressor package typically longest lead item
Station location: Neighborhood, environmental constraints, space
Air emissions: Permit requirements, attainment status
Noise: Local ordinances, NSA proximity
Project life: Short life may not justify higher capital cost

General Application Guidelines

Centrifugal: Preferred for high flow or low compression ratios
Reciprocating: Preferred for low flow or higher compression ratios
Electric: Zero site emissions, lower noise, higher efficiency
Gas-fired: No electrical infrastructure, fuel available on-site

7. Code Requirements

Applicable Regulations & Standards

Code/Standard	Scope	Authority
49 CFR Part 192	Gas transmission/distribution pipelines	DOT/PHMSA (Federal)
FERC Regulations	Interstate gas transmission facilities	FERC (Federal)
NFPA 30	Flammable liquids storage	Industry standard
NFPA 70 (NEC)	Electrical installations	Industry standard
API RP 500/505	Electrical area classification	Industry standard
State/Local codes	Building, fire, zoning	Varies by jurisdiction

Key Regulatory Requirements

ESD system: Required for stations >1,000 HP per 49 CFR 192
Noise limit: 55 dBA L_dn at NSA per FERC
Air permits: Required based on PTE vs. thresholds
Hazardous area classification: Per API RP 500/505
Fire protection: Per NFPA and local requirements

Summary: Minimum Spacing Quick Reference

Item	Minimum Distance
Control/office building from compressor building	50 ft
Condensate tanks from buildings/equipment	50 ft
Blowdown/vent discharge from compressor building	100 ft
ESD actuation from compressor building	25 ft (minimum)
ESD actuation from station limits	500 ft (maximum)

References

49 CFR Part 192 – Transportation of Natural Gas by Pipeline (DOT/PHMSA)
18 CFR Part 380 – FERC Environmental Review Regulations
API RP 500 – Classification of Locations for Electrical Installations
API RP 505 – Classification of Locations for Electrical Installations (Zone System)
NFPA 30 – Flammable and Combustible Liquids Code
NFPA 70 – National Electrical Code
ASME B31.8 – Gas Transmission and Distribution Piping Systems

Compressor Station Layout

50 ft min

100 ft min

55 dBA Ldn

Contents

ESD System Design