EUROPEAN PATROL BOATS


A new generation of Life Rescue and Patrol Boats is available from Hi tech International, the developer of the European Patrol Boat (EPB) series.

These new products have been designed using the latest sea technologies, including Kevlar® or Aramid® hulls as well as traditional materials such as aluminium, fibreglass, steel or even wood.

The special design of the V-Hull allows the European Patrol Boat (EPB) to reach speeds that range from 60 to 85 knots, with the lowest fuel consumption of its class and the highest comfort level due to the fluid shock absorbers incorporated in the hull profile.

Patented closed cells foam rings along the perimeter, protected by 860 Hypalon anti-cutting, ensure the self floating buoyancy of EPB during any weather and sea condition.

EPB are guaranteed 25 years excluding the motors which have a 5 years guarantee.

EPB is naturally self righting in less than 6 seconds in case of roll over.

Different sizes are available, from 16 up to 70 feet with out board motors - diesel or gasoline - propeller or water jet as specified by the customer.

The EPB is also available in Kevlar® hull bullet proof up to level IV A.

Many options are available, including: air conditioning, night visors, plotter, radars, search lights, gps, satellite communication systems, internet, … please do not hesitate to contact us today for more informations..

Since the design of Archimedes, known as Archimedes’ screw, propellers are in our life. In not only vessels but also in some aircraft, they are the driving forces. From the smallest to the most enormous one, the majority of the ships can move because of a propulsion system. Their distinctive look makes them efficient, effective and sustainable. Today, lots of different propellers are in use and technological developments make them more efficient. Let’s dive into the details of a typical ship propeller’s design and what makes it unique.

For determining the performance of the ships, propellers play an important role. Undoubtedly, the right choices of propellers can lead to competence to change the performances of handling, riding, speed, velocity, engine and fuel efficiency. Such a variety of differences originated from a simple principle.

Ship propellers simultaneously pull and push water to create a forward thrust. As propellers rotate, they push water and whilst transforming rotational energy into thrust. Therefore, water pressure goes high to its rear as the propeller rotates, and moves into the area of reduced pressure in front of the propeller. Like every mechanical detail applied in everyday life, Newton’s laws show up in the process of the propeller’s performance. As the third law mentions, for every action, there’s an equal and opposite reaction. In this manner, as the propeller moves water backwards, the vessel moves forward. The principle originated from the unique design of the propeller.


The Design and Properties of the Propeller


Propellers are classified as their size. For better understanding, their diameter is used in the assortment. The diameter of a propeller is the distance between the edges of a circle drawn around the tips of the blades. It can be small or enormous. The biggest ship propeller so far, Emma Maersk, weighs 131 tons. In other words, Emma Maersk is heavier than a single-store house and a Boeing 757-200.

Certainly, selecting the most accurate and congenial size of the propeller needs expert judgement and research.

If we exclude the exceptions, larger propellers are used on slower boats and smaller propellers on faster boats. Power is mostly proportional to size.

Pitch, which looks just like the screw, evaluates the margin of the propeller through a soft solid as referring to the diameter and how far it moves in full revolution. There are two types of pitches. Flat pitch, as its name signifies, means that the blade is flat. In the meantime, progressive pitch means the blade proceeds with a lower pitch at the leading edge and increases to the trailing edge.

Another aspect that affects the design is the number of blades. The most banausic solution would be using one blade yet it leads to the creation of vibration and cavitation. Commonly, three or four blades are used in ship propellers. The image that comes to mind when we think about propellers is the one with four blades, which is the most common. Nonetheless, there are also some models that use even more blades.


Terminology for Propellers


Theleading edgeis called the front of the blade. Its design is consequential because that helps better water pull. On the other hand, the back of the blade is known as thetrailing edge. The outermost part where these two meet is called theblade tip.

As thecuprefers to the small curve on the leading edge which renders possible blades to hold water, the blade face is the side facing where negative pressure is created. The outer hub is attached to theblade rootat the bottom of the blade. On the other hand, theinner hubis a fix to the shaft that turns the propeller.

One of the other important parts of the propeller is the root and tip. In short,rootrefers to the attachment where blades come together with the ship propeller. And thetipimplies the furthest point of the blade from the ship propeller.