METHOD AND SYSTEM FOR A DC NANOGRID

Organization Name

Purdue Research Foundation

Inventor(s)

Jonathan Ore of Jacksonville FL (US)

Philip Teague of Indianapolis IN (US)

Frank W. Teague, Iii of Campbell CA (US)

Eckhard Groll of West Lafayette IN (US)

METHOD AND SYSTEM FOR A DC NANOGRID - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240039252 titled 'METHOD AND SYSTEM FOR A DC NANOGRID

Simplified Explanation

The abstract describes a patent application for a direct current (DC) electrical panel, also known as a DC combiner. The panel consists of multiple input pairs, each consisting of positive and negative inputs. Each input pair is designed to provide a positive DC input at a specific voltage and a negative DC return. Each positive input is connected to a protection circuit, which isolates it from other positive inputs, resulting in a protected input. These protected inputs are then connected to a busbar, which is further connected to multiple switched circuits through a breaker switch in line with each protected input.

• The patent application describes a DC electrical panel with multiple input pairs, each providing a positive DC input and a negative DC return.
• Each positive input is isolated from other positive inputs using a protection circuit, generating a protected input.
• The protected inputs are connected to a busbar, which is then connected to multiple switched circuits through breaker switches.
• The invention aims to provide a safe and efficient way to manage and distribute DC power in electrical systems.

Potential applications of this technology:

• Renewable energy systems: The DC combiner can be used in solar power systems or wind turbines to combine and distribute the generated DC power.
• Electric vehicle charging stations: The panel can be utilized to manage and distribute DC power for charging electric vehicles.
• Industrial applications: The technology can be employed in various industrial settings where DC power distribution is required, such as manufacturing plants or data centers.

Problems solved by this technology:

• Isolation of positive inputs: The protection circuit ensures that each positive input is isolated from others, preventing any potential issues or malfunctions.
• Efficient power distribution: The use of a busbar and breaker switches allows for efficient distribution of DC power to multiple switched circuits.
• Safety: The technology provides a safe way to manage and distribute DC power, reducing the risk of electrical hazards.

Benefits of this technology:

• Improved system reliability: The isolation of positive inputs and the use of protection circuits enhance the overall reliability of the DC electrical panel.
• Enhanced safety: The technology ensures safe power distribution, reducing the risk of electrical accidents or damage.
• Flexibility and scalability: The panel can be easily expanded or modified to accommodate different power requirements or system configurations.

Original Abstract Submitted

a direct current (dc) electrical panel (dc combiner) is disclosed which includes a plurality of input pairs of positive and negative inputs, each input pair of the plurality of input pairs is configured to provide a positive dc input at a predefined voltage and a negative dc return, each positive input is coupled to a protection circuit whereby each such positive input is isolated from other positive inputs of the plurality of input pairs, thereby generating a protected input, each protected input is coupled to a busbar, and the busbar coupled to a plurality of switched circuits via a breaker switch in line with a protected input.