INITIAL OBSERVATIONS

On October 6th, we successfully completed the Pacific Trials 350 nautical miles from land, through which we were able to confirm the system’s general behavior and seaworthiness.

After giving the go-ahead to continue the remaining 850 nautical miles to the GPGP, we deployed System 001, or Wilson, in its operational configuration. There has been one crew change since the launch, which brought in a new set of team members with different objectives. The main goal of Crew 1 was to deploy and install Wilson in its U-shape, and, now, Crew 2 is focused on observation, data analysis and, soon, plastic collection. These have been their main, initial observations:

For the most part, the system is behaving as predicted

Plastic density in the GPGP is in line with our expectations; but, due to our short time in the GPGP, this is a limited data set, so we cannot fully verify this yet

No interactions with marine life have been observed

Small particles float within the system, though quantitative measurements are still required

Plastic remains in the system for a relatively short time

CAUSE AND EFFECTS

Although the technology is built on simple principles, the dynamics are complex. There could be various reasons why plastic is not staying inside the system. We have concluded that the system does appear to be moving too slow at times (remember, to catch the plastic, we need a speed difference where the system is faster than the plastic) or, occasionally, the speed difference appears to be reversed, where the plastic is then faster than the system. At the very minimum, the system needs to be continuously traveling faster than the plastic.

One hypothesis is that the force of the wind against the system might be making both extreme ends of the floater pipe oscillate (like the fin of a fish), which may lead to a motion force against the wind direction. This motion counteracts the force of the wind, and, therefore, slows down the system.

It is also possible that the vibrations in the ends of the U-shape could be creating a type of ripple-force field that repels the plastic away from as it nears the mouth of the system.

We believe the first solution we will attempt could potentially remediate both of these causes.

SOLUTION

We have conducted scale model tests and created computer models, and, yet, this phenomenon was never observed, so we have not had a solution ready to deploy. Fortunately, the first logical solution can be easily-enacted because we have the materials available on board the vessel.

We will address the speed difference by opening the U-shape about 60-70 meters wider. Doing this should, theoretically, have two effects on the speed of the system; firstly, it will increase the surface area of the system exposed to the wind and waves, which are the driving forces of the system. Secondly, by widening the span, we think this could also reduce the propulsive force caused by the undulating ends, simply because it would not be directed straight into the motion direction of the system anymore.

To perform the extension, we will lengthen the closing lines which keep the cleanup system in its U-shape. We will perform the extension in several stages until we will (hopefully) reach the desired effect. As an increased span is expected to have a negative effect on the system’s ability to rapidly pivot when a change in wind direction occurs, we must be careful to not increase the span too much.

WHAT’S NEXT

System 001 must work before we can look to scaling up, so there is no time to waste. While we are busy implementing this first solution, our team is continuing to analyze more data and test alternative solutions until the system is fully operational.

Currently, the weather appears to be favorable to implement the closing line extensions this Thursday. We’ll keep you posted as this happens.