What Is a Single-Line Diagram?

A single-line diagram (SLD), also called a one-line diagram, is a simplified schematic that shows the main components of an electrical power system using single lines to represent three-phase conductors. Rather than showing all three phases separately, an SLD uses standardized symbols to represent transformers, circuit breakers, fuses, switchgear, motors, generators, and utility connections.

SLDs are the primary reference document for power engineers, electricians, and facility managers. They show how electrical power flows from the utility through the facility's distribution system to the end loads.

Key Symbols to Know

Utility Service is typically shown at the top of the diagram with a symbol indicating the utility connection point, the voltage level (e.g., 13.8 kV), and the available fault current (short circuit current).

Transformers are shown as two circles (representing the primary and secondary windings) with a line between them. The voltage ratio (e.g., 480V:208/120V), KVA rating, and winding configuration (delta or wye) are labeled next to the symbol.

Circuit Breakers appear as a small square or rectangle with a diagonal line through it. The breaker's frame size, trip rating, and interrupting capacity are typically noted nearby.

Fused Disconnects show a switch symbol with a small rectangle (the fuse) in series. Fuse ratings and voltage class are labeled.

Buses are horizontal lines representing busbars — the copper or aluminum conductors that distribute power within switchgear or panelboards. Bus ampacity is labeled on the line.

Meters are shown as circles with letters inside: V (voltmeter), A (ammeter), W (wattmeter), VAR (var meter), WH (watt-hour meter).

Ground symbols indicate grounding connections — either system grounding (neutral grounded) or equipment grounding.

How to Read the Power Flow

Start at the top and work downward. Power flows from the utility (top) through the main service entrance, through transformers that step down voltage, through distribution switchgear or panelboards, and finally to branch circuits and loads at the bottom.

Each level of the diagram represents a different voltage tier. A typical commercial building might show 13.8 kV at the utility, 480V at the main switchboard, and 208/120V at branch circuit panels.

Key Information Shown on an SLD

  • Voltage levels at each tier of the distribution system
  • Interrupting ratings — the fault current each breaker can safely clear
  • Conductor sizes and conduit types for major feeders
  • Panel and transformer schedules referenced from the SLD
  • Emergency and normal power systems — often shown with different line styles
  • Generator and UPS connections with automatic transfer switch (ATS) detail

SLD vs. Schematic vs. Wiring Diagram

Engineers use three types of electrical drawings for different purposes. An SLD shows power flow and system overview — it is a planning and coordination document. A schematic diagram shows how a control circuit works logically (used for relay logic, motor starters, PLC wiring). A wiring diagram shows the physical layout of wires between terminals — used by installers and maintenance technicians. All three may be needed for a complete electrical project.

Reading SLDs in the Field

When responding to a power outage or tracing a fault, start with the SLD to understand the system architecture. Identify which bus supplies the affected panel, which upstream breaker protects it, and where the utility tie is. This mental model, built from reading the SLD, dramatically speeds up troubleshooting.