How HVDC Works

Siemens Video: How HVDC Provides Remote Power to the Market

Historically, the transfer of electricity between regions of the United States has been over high voltage alternating current (AC) transmission lines, which means that both the voltage and the current on these lines move in a wave-like pattern along the lines and are continually changing direction.  In North America, this change in direction occurs 60 times per second (defined as 60 hertz [Hz]).  The electric power transmitted over AC transmission lines is exactly the same as the power we use every day from AC outlets, but at a much higher voltage.

Unlike an AC transmission line, the voltage and current on a direct current (DC) transmission line are not time varying, meaning they do not change direction as energy is transmitted.  DC electricity is the constant, zero-frequency movement of electrons from an area of negative (-) charge to an area of positive (+) charge.

The first commercial electric power system built by Thomas Edison in the late nineteenth century carried DC electricity, but given some early advantages, AC power eventually became the primary power system in the United States.  Some of these advantages are no longer applicable (e.g., technology has advanced to allow efficient conversion from AC to DC), and DC transmission is the preferred solution for moving large amounts of power over long distances.

Clean Line’s projects will deliver power from new, renewable energy resources.  These resources will be AC generators, as is normally the case, and their energy will be transmitted along AC collector lines.  These collector lines will then be connected to a substation where the power will be collected and the voltage will be transformed from the voltage of the collector lines to a common voltage (such as 345,000 volts).  The power will then be converted to DC, a process known as rectification, using power electronic switches called thyristors.  The power will then be transmitted several hundred miles along a set of conductors called a transmission line before getting converted back to AC, a process known as inversion, again using thyristors as the switching devices.  After the DC power is converted back to AC, it is transformed to the common voltage of the grid to which it is being connected (e.g. 395,000 volts in Missouri and 765,000 volts in Indiana, in the case of the Grain Belt Express Clean Line).  This power is then distributed via the interconnected grid by the local utilities to homes and businesses.  See below for an illustration of this process.

How High Voltage DC Transmission (HVDC) Works