Wind-Assisted Propulsion Systems for vessels | bound4blue (2024)

The suction fan is a standard axial compressor driven by an electric motor. It is responsible for sucking in the air to ensure the airflow remains attached to the sail.

The suction area is a porous area of the skin through which the air is sucked. It is strategically designed and located to ensure airflow remains attached to the eSAIL^®with minimal power consumption.

The geometry of the eSAIL^® inverts depending on whether the wind blows from port or starboard. The flap is a movable structure, manufactured using marine-grade materials, that can be positioned on both sides of the eSAIL^®, generating the appropriate aerodynamic shape of the eSAIL^® and, at the same time, covering the suction area that is not in use. The flap positioning is achieved by means of standard electric motors.

The eSAIL^® main structure and skin provide the external aerodynamic shape of the sail and, at the same time bear the loads that affect the eSAIL^®. It is manufactured using marine-grade materials and also contains and protects the equipment located inside.

The rotation system ensures that the eSAIL^® can rotate and make the most of any existing wind direction. It is based on a standard slew-bearing actuated by an electric motor. This part is very similar to a deck crane.

The eSAIL^® mechanically connects to the vessel by means of a flange, which is secured using bolts. Again, this is a well-known solution, based on standard deck cranes.

The suction fan is a standard axial compressor driven by an electric motor. It is responsible for sucking in the air to ensure the airflow remains attached to the sail.

The suction area is a porous area of the skin through which the air is sucked. It is strategically designed and located to ensure airflow remains attached to the eSAIL^®with minimal power consumption.

The geometry of the eSAIL^® inverts depending on whether the wind blows from port or starboard. The flap is a movable structure, manufactured using marine-grade materials, that can be positioned on both sides of the eSAIL^®, generating the appropriate aerodynamic shape of the eSAIL^® and, at the same time, covering the suction area that is not in use. The flap positioning is achieved by means of standard electric motors.

The eSAIL^® main structure and skin provide the external aerodynamic shape of the sail and, at the same time bear the loads that affect the eSAIL^®. It is manufactured using marine-grade materials and also contains and protects the equipment located inside.

The rotation system ensures that the eSAIL^® can rotate and make the most of any existing wind direction. It is based on a standard slew-bearing actuated by an electric motor. This part is very similar to a deck crane.

The eSAIL^® mechanically connects to the vessel by means of a flange, which is secured using bolts. Again, this is a well-known solution, based on standard deck cranes.

Control

system

Portfolio

The optimum number of eSAILs^® – defined during the vessel transformation project – will be positioned on the foundations and their flanges bolted together.

Weather sensors, capable of measuring various weather parameters like wind intensity and direction, temperature, and atmospheric pressure, are combined with GPS/inertial sensors capable of giving us several vessel navigation and attitude parameters. Sensor redundancy, as well as data accuracy, is achieved via a multi-sensor architecture.

The eSAIL^® Main cabinet is the central part of the control system. It is located inside the eSAIL^® body and contains the main equipment of the system (PLC, motor speed controllers, etc.). The eSAIL^® Cabinet is the input for power supply (from the vessel) and it distributes this power to all control system elements.

All eSAIL^® electronic components are interconnected via a closed Ethernet redundant loop that safely allows the operation of all eSAILs^® from the main bridge or any other vessel location.

The Touchscreent is installed on the vessel’s bridge, allowing simple eSAIL^® monitoring by the captain or any other crew member.

The optimum number of eSAILs^® – defined during the vessel transformation project – will be positioned on the foundations and their flanges bolted together.

Weather sensors, capable of measuring various weather parameters like wind intensity and direction, temperature, and atmospheric pressure, are combined with GPS/inertial sensors capable of giving us several vessel navigation and attitude parameters. Sensor redundancy, as well as data accuracy, is achieved via a multi-sensor architecture.

The eSAIL^® Main cabinet is the central part of the control system. It is located inside the eSAIL^® body and contains the main equipment of the system (PLC, motor speed controllers, etc.). The eSAIL^® Cabinet is the input for power supply (from the vessel) and it distributes this power to all control system elements.

All eSAIL^® electronic components are interconnected via a closed Ethernet redundant loop that safely allows the operation of all eSAILs^® from the main bridge or any other vessel location.

The Touchscreent is installed on the vessel’s bridge, allowing simple eSAIL^® monitoring by the captain or any other crew member.