Sunday 7 October 2018

The Aegean rigging-A flat main sail



Introduction

The Aegean rigging in a sailing boat is a simple arrangement that provides for maximum driving force by use of the total surface of the boom sail as a perfect airfoil. As such, exploiting new materials, it can ultimately enable a friendly to the environment design of a sailing boat free of a carbon content fuel.

A flat main sail rigging, consists of a rigid boom with an embedded guiding rail with its runner-camber controller (figure 1). The runner is controlled by a chain attached to it, moving via rotating wheels at both ends of the boom. It can be stabilised at any position. Rotating power is delivered to the wheel near the mast end of the boom by an outside power source (by electric motor or manually). A flat surface sail with in-mast reefing feature is attached to the runner at its clew end. The boom is positioned via the main sheet at its optimum angle of attack to the apparent wind direction. The sail camber is regulated by the position of the runner-camber controller according to wind speed, so that the air flow around the whole surface of the sail is as linear as possible. This layout also ensures the stability of the sail to wind parameters variations.

In larger vessels, boom position and sail camber are determined by a computerized system controlled by sensors at the leech end of the sail. It adjusts the boom angle of attack and the cumber of the sail in accordance with the apparent wind parameters for the attainment of a close to linear air flow.

The Aegean Rigging itself requires negligible electrical power and stored energy and none in case of manual handling.

Claim: The Aegean rigging, as described above as an arrangement around a flat sail is new according to EPO Article 54.

The proposal, as opposed to a fully attached boom sail rigging, delivers an optimal airfoil shape for the whole sail surface and significant reduction of wake turbulence due to the pressure differential between its two sides at the boom end. More importantly by streamlining its lower part, it provides significant increase in the effective sail surface. These modifications result in an increase in propulsive power and a lowering of the sail’s center of effort.

When compared to a vessel equipped with a traditional rigging arrangement, and for the same sail area, the invention provides relative benefit from:

·       The effective use of the whole surface of a flat main sail.

·       The possibility to use modern sail materials including solar cells imbedded foils.

·       A boat righting couple reduction due to lower sail center of effort.

·       Sharper tacking behavior, due to an increase of the effective sail surface.

·       Smaller ballast and thus lighter and faster boat.

The system can be incorporated on new boats and larger commercial vessels utilising this particular rigging of boom supported sails to augment their propulsive power but can also be deployed with moderate modifications on existing vessels delivering a significant gain in sail power.

Prior Art 
An example (figure 3) illustrates how sails are typically arranged on an sailing boat with one mast. The design shown consists of sails attached to the mast, located ahead of amidships. A triangular sail ahead of the mast is raised or pre-hoisted along a forestay which is braced approximately from the bow to near the mast tip. The clew as the free end of the leech and foot of the sail is hauled tightly by means of a jib sheet so that the sail can adopt the most favorable possible aerodynamic profiled shape to take advantage of the apparent wind.

The draft of this head sail also energetically intensifies the lee flow of the subsequently positioned mainsail. This ensures the most extensive possible wind deflection without the lee flow becoming separated from the mainsail, and thus minimises the risk of creation of complex wake turbulence,   which would result in an    important   loss   of   sail   driving   force.

The characteristic configuration of the sail profile and its angle of attack is crucial for the specific propulsion power per square meter of sail area. Utilising current practices and current sail, mast and boom technology, the maximum production of driving force is achieved in the upper part of the boom sail. In the area near the boom, the propulsion-bringing flow profile is increasingly deflected - and ultimately interrupted - by the turbulence produced by the boom.

Neither the angle of attack in the luff zone of a well-positioned main sail, that is close to the incoming wind direction, nor the outflow angle at the leech following the forward-driving flow deflection inside the sail are similarly directed to the angle of attack of the boom attached to the sail. Thus, appreciable power losses occur in the transition zones from the sail, even when profiled as correctly as possible, in the upper region, to the straight connected boom. Modern sails design has reached its limit in remedying this deficiency. This problem is accentuated as the otherwise usable downdraft of the head sail does not meet an ordered lee flow on the rear side of the main sail. 

In conclusion, when the main sail is attached to a standard profiled straight rigid boom head, in addition to serious wake turbulence formed along the foot of the sail, caused by the exchange of air from the luff-side to the lee side with the boom’s presence, more important turbulence losses result from the distortion of the linear flow on the sail surface near the straight boom at serious expense of drive energy (figure 4). Wind tunnel research confirms this situation.


Description of the invention
The proposal, described hereinafter as the Aegean Rigging, is designed to address and minimise the effect of the aforementioned disadvantages. It also creates a boom sail  rigging that ultimately will be decisive for the design of a sailing boat free of a carbon content fuel and thus friendly to the environment 
The generic concept is demonstrated in figures 2.

The invention consists of a rigid sail boom with an embedded guiding rail with its runner-camber controller. The boom, as driven by the main sheet, is positioned at optimal angle of attack to the apparent wind. The runner is moving via rotating wheels at both ends of the boom by a chain attached to it on both sides. It can be stabilised at any position. Movement and positioning of the runner is secured by the wheel near the mast end of the boom that is rotated by outside power source (figure 2). A flat surfaced sail with in-mast furling feature is attached to the runner-camber controller at its clew end. The aim of the runner is to achieve, under given apparent wind speed, the most efficient airfoil shape of the total surface area of the sail thus maximising propulsive force. Optimum efficiency is attained through the use of modern foil materials for the sail, including foils with impregnated solar cells. This provides the possibility for additional energy stored during daytime and the use of a complementary electric propulsion plant, avoiding a combustion engine.

Other runner-camber control mechanisms can be arranged to achieve its generic control function.

In its complete form, the rigging includes a computerised control system that determines and positions the boom and the guiding rail runner according to apparent wind parameters.

The above description broadly only reproduces the more important features of the present disclosure.

As a simple package, the system can easily be installed on existing vessels. In this form, the invention requires no modifications to the remaining sail rigging systems and results in significant gains in sail power.

Given the generic basis of this proposition, the embodiments of the disclosure are not restricted to this description and the outline of the example construction. Other embodiments can also be implemented within the scope of the invention as defined by the claim and executed in different ways. Furthermore, it is understood that the phraseology and terminology used is only used for the description and not as a restriction as it does not demonstrate finer details of the system’s design deemed unnecessary for the purposes of this application.

The exemplary  embodiments  of  the  invention  are  explained  in  more  detail  with reference to the drawings.

List of Figures
Figure 1 shows the Aegean rigging layout
Figure 2 shows the main sheet and runner-camber controller details
Figure 3 shows a prior art arrangement
Figure 4 shows a wind tunnel experiment

Description of the drawings
Figure 1 shows proposed arrangements of the boom rigging. The boom spar with its kicking strap is attached in the usual manner to the mast and controlled by the main sheet. The sail is attached forward to the mast via a reefing gear and to the boom via the runner, the position of the latter controlled by the guiding rail mechanism. Consequently, the boom angle relative to the apparent wind is controlled by the main sheet and the camber of the sail, adjusting to the wind strength, is controlled by the position of the runner. Need for minor adjustments of the boom to control the leech shape is taken care by the kicking strap.

Figure 2 shows the main sheet and runner-camber controller details. The main sheet is attached to the boom in the usual manner. The runner of the guiding mechanism is attached to the clew of the sail.

Figure 3 shows a prior art arrangement.  Sails are typically arranged on an average sailing boat with one mast located ahead of amidships with sails attached to it. A head sail ahead of the mast is raised along a forestay. Its clew is hauled tightly by a jib sheet and this helps the sail to adopt an aerodynamic profiled. The draft of this sail also intensifies the lee flow of the subsequently positioned mainsail. This ensures the most extensive possible wind deflection without the lee flow becoming separated from the mainsail. The characteristic configuration of the sail profile and its angle of attack is crucial for the specific propulsion power per square meter of sail area. Utilising current practices and current sail, mast and boom technology, the maximum production of driving force is achieved in the upper part of the boom sail. In the area near the boom, the propulsion-bringing flow profile is increasingly deflected - and ultimately interrupted - by the turbulence produced by the boom.  Neither the angle of attack in the luff zone of a well-positioned main sail, that is close to the incoming wind direction, nor the outflow angle at the leech following the forward-driving flow deflection inside the sail are similarly directed to the angle of attack of the boom attached to the sail.

Figure 4 shows a wind tunnel experiment. It is apparent that when the main sail is attached to a standard profiled straight boom head, in addition to serious wake turbulence formed along the foot of the sail, caused by the exchange of air from the luff-side to the lee side with the boom’s presence, more important turbulence losses result from the distortion of the linear flow on the sail surface near the boom at serious expense of drive energy.


                                                               Figure 1

Figure 2

Figure 3

Figure 4