ITMI20131489A1 - UNDERWATER PROPULSION DEVICE - Google Patents

Description

DESCRIPTION

UNDERWATER PROPULSION DEVICE

The present invention relates to an underwater propulsion device of the type specified in the preamble of the first claim.

In particular, the invention concerns a particular device designed to be used during an underwater dive to facilitate and, in particular, speed up the diver's movements.

As is known, hydraulic propulsion devices are usually identifiable in electric propulsion vehicles. They therefore provide a propeller, usually enclosed in a grid or other similar protection device, capable of determining the thrust force; an electric motor capable of transmitting, through a shaft, a rotational motion to the propeller; batteries designed to power the engine; and a casing designed to define a watertight containment chamber for the engine and batteries and which can be fitted with sockets designed to be gripped by the operator.

Such propulsion devices have some important drawbacks.

A first important drawback is represented by the fact that, due to the high weight of the batteries and motor, the known underwater propulsion devices are particularly heavy and bulky both to carry and to use.

This aspect is particularly relevant if we consider that the diver, in addition to the propulsion device, is equipped with cylinders and other particularly bulky and heavy instruments.

Another drawback is represented by the fact that the manufacturers, in order to limit the weight and, therefore, the overall dimensions of the device, adopt not very powerful batteries which ensure its operation for a short time.

A further drawback is the fact that, during a dive, the diver must return to the surface to replace or recharge the batteries, consequently losing a long time.

A not secondary defect is represented by the fact that, especially during the movements, the diver, having to manually guide the known devices, has his hands full and, therefore, is unable to perform other operations.

In this situation, the technical task underlying the present invention is to devise an underwater propulsion device capable of substantially obviating the aforementioned drawbacks.

Within the scope of said technical task, it is an important object of the invention to have an underwater propulsion device characterized by extremely reduced weights and dimensions and which therefore is extremely easy and simple to use and transport.

Another important purpose of the invention is to develop a device that does not engage the hands of the operator who, therefore, is free to perform other operations.

The technical task and the specified aims are achieved by an underwater propulsion device as claimed in the attached Claim 1.

Preferred embodiments are highlighted in the sub-claims.

The characteristics and advantages of the invention are clarified below by the detailed description of a preferred embodiment of the invention, with reference to Fig. 1 which shows an underwater propulsion device according to the invention.

With reference to the aforementioned Figures, the underwater propulsion device according to the invention is globally indicated with the number 1.

It is designed to be immersed in a fluid, usually salt water (sea) and / or fresh water (river, lake), to facilitate and, in detail, speed up the operator's movements by exerting a thrust force.

The underwater propulsion device 1 is substantially made of metal, for example steel, preferably sintered and mainly comprises a circular duct 20 defining a prevalent development axis 20a, an inlet section 20b for the conducted fluid and an outlet section 20c of the motor fluid; and an attachment 30 designed to allow a flow of gas, for example air, under pressure to enter the duct through the inlet section 20b and with a direction of advancement substantially parallel to the prevailing development axis 20a; fixing means adapted to constrain the device 1 at the operator's back (preferably to the cylinder) by arranging the axis 20a substantially parallel to the direction of motion.

At the beginning of the duct 20, or in another area, an on, off or flow regulation valve is also preferably provided.

The duct 20 begins with a convergent / divergent and has an inlet section 20b lower than the outlet section 20c. Preferably, it has an inlet section 20b having a diameter substantially equal to 60% -40% of the diameter of the outlet section 20c; and a groove, that is the passage section from the converging to the diverging section, with a diameter substantially equal to 30% -10% of the diameter of the inlet section 20b.

The duct 20 comprises a convergent portion 21 defining the inlet section 20b and having a convergence angle substantially between 25 ° and 45 °; and a diverging portion 22 defining the outlet section 20c and having a divergence angle substantially lower than 20 °.

The diverging portion 22 has a length, calculated along the prevailing axis 20a, substantially greater and, conveniently, at least equal to five times the length of the converging portion 21.

The diverging portion 22 comprises a first sector 22a, adjacent to the converging portion 21, and a second sector 22b defining the outlet section 20c and having a different divergence angle and length with respect to the first sector 22a; and one or more inlet holes 22c made in correspondence with the second sector 22b and adapted to allow the fluid external to the duct 20, ie the water, to enter the divergent portion 22.

The first sector 22a has a divergence angle substantially greater than that of the second sector 22b and a length which is practically shorter than the length of this second sector 22b.

Preferably, the sectors 22a and 22b identify two distinct bodies mutually coupled by interlocking, threading or other similar solution designed to define, for example through the adoption of a seal, a watertight bond.

Conveniently made along the second sector 22b, the duct 20 has a plurality of inlet holes 22c.

The holes 22c have an axis substantially transverse to the development axis 20a, even if not straight, so that the water enters the divergent portion 22 with a speed having the component parallel to the prevailing development axis 20a equiverse to the gas. In particular, the axis of the holes 22c is inclined with respect to the axis 20a, by an angle substantially between 15 ° and 60 ° and, preferably, substantially equal to 45 °.

They also have sections characterized by increasing diameters near the outlet section 20c.

The connection 30 is designed to constrain, by means of a threaded coupling, a flexible pipe or other similar element, not shown in the figure, through which one or more of the gas cylinders are connected to the duct 20.

Finally, the propulsion device 1 comprises a circular duct 40 having an axis of extension substantially coincident with the prevailing development axis 20a and able to house inside it at least part of the divergent portion 22 so as to guide the external flow of the water along the same divergent portion 22.

The conduit 40 is of the convergent / divergent type and has the groove arranged near the outlet section 20c and, in particular, on the opposite side to the inlet section 20b with respect to said outlet section 20c.

Preferably, the throat of the conduit 40 is substantially larger than the outlet section 20c.

The conduit 40 comprises a converging conduit 41 defining an inlet 40a in the conduit 40, a diverging conduit 42 defining an outlet 40b from the conduit 40 and, in particular, from the propulsion device 1; and a fixing body 43 adapted to constrain the conduit 40 to the conduit 20.

The convergent pipeline 41 has a length at least equal to that of the divergent portion 22 and adapted to house it substantially inside it so as to guide the water along the same divergent portion 22 favoring its entry into the second sector 22b.

Finally, it has a convergence angle substantially between 5 ° and 40 °. In some cases, said angle of convergence may not be constant. The diverging pipeline 42 is adapted to accommodate and, in particular, guide the exit from the propulsion device 1 both of the water coming from the converging pipeline 41 and of the mixture of water and gas coming from the divergent portion 22, as described in detail below.

The fixing body 43 comprises a coupling 43a suitable for binding, preferably by means of a thread, to the duct 20 in correspondence with the outlet section 20c; and one or more fins 43b, preferably three, or other similar elements extending radially with respect to the development axis 20a and able to connect the divergent duct 42 to the coupling 43a and, therefore, to the duct 20.

The operation of an underwater propulsion device, described above in a structural sense, is as follows.

Initially, the operator connects the connection 30 to a pressurized gas cylinder by arranging the prevailing development axis 20a substantially parallel to the direction of motion and, therefore, immerses itself so that the conducted fluid, i.e. the water, fills the pipeline 40.

When the pressurized air arrives, through the connection 30, in the duct 20 it begins to cross the converging portion twenty-one where, due to the reduction of the section, the speed increases and the pressure decreases.

In detail, thanks to the specific sizing of the converging portion 21, the gas is accelerated up to the flow duct in the throat section, continuing to accelerate after the throat reaches low static pressure values which draw the fluid back into the duct 20.

the air takes on a pressure lower than that outside the duct 20 and, to be precise, lower than the water pressure.

Once the minimum section of the duct 40 is reached, the air enters the divergent portion 22 where, having a static pressure lower than the water pressure in the duct 40, it draws the water through the holes 22c. This action places the conduit 40 in depression and, consequently, exerts a pressure on the water external to the device 1 which forces the water to enter through the inlet 40a and, therefore, generates a forward thrust on the operator. .

The water thus begins to travel along the converging pipeline 41, increasing its speed.

When it reaches the holes 22c, the water, thanks to the depression present in the diverging portion 22, accelerates further and, at least in part, enters the divergent portion 22 with a velocity having the component parallel to the axis 20a favorably equal to the motion of the 'air.

In particular, as one advances along the prevailing development axis 20a, an increasing amount of water enters the second sector 22b and mixes with the air creating a mixture of high mass and speed.

At this point, this mixture comes out of the duct 20, joins the residual water present in the converging duct 41, further increasing its mass, and runs through the final section of the same converging duct 41 undergoing a further increase in speed.

Finally, the mixture crosses the divergent pipeline 42 and exits from the outlet 40b with a greater speed than the water entering the inlet 40a and, therefore, creating a propulsive thrust on the operator.

The invention allows important advantages.

A first advantage is represented by the fact that the underwater propulsion device 1, being devoid of batteries, propellers and pumps, is extremely lighter than known devices.

This aspect gives the underwater propulsion device 1 high maneuverability and ease of transport.

Another important advantage can be identified in the high thrust obtained thanks to the propulsion device 1 thanks to the emission of a mixture of high mass and speed and, therefore, of considerable kinetic energy.

In fact, the adoption of a duct 20 and holes 22c generates a flow of air at high speed and which, mixing with the water, accelerates the water itself, generating a particularly powerful propulsive jet.

The aforementioned high thrust is further guaranteed thanks to the fact that the duct 20, by placing the air in depression with respect to the water, creates a force of recalling the water in the duct 40 and, as described above, an advantageous thrust force on the operator. .

This propulsive effect is finally increased by the presence of the conduit 40 and, in particular, of the converging conduit 41.

In fact, this convergent duct 41, surrounding at least the second sector 22b and, in particular, almost all of the convergent portion 22, favors the entry of water into duct 20 by increasing the intensity of said propulsive jet.

Furthermore, the water, passing through at least a portion of converging pipeline 41, increases its speed and, therefore, further increasing the thrust generated by the device 1.

Another advantage given by the presence of the convergent pipeline 41 is identifiable in the fact that the water, increasing its speed before entering the conduit 20, does not slow down the flow of gas and, therefore, does not degrade its propulsive capacity.

A further advantage is represented by the fact that the device 1, being bound to the back, does not engage the hands of the operator who, therefore, is free to perform other operations.

The invention is susceptible of variants falling within the scope of the inventive concept.

The individual constituent elements of the device 1 can be made in a single body by means of different production technologies.

In particular, the conduit 40, ie the conduits 41 and 42 and the fixing body 43, and the sectors 22a and 22b, can be made in a single piece so as not to be mutually separable.

All the elements described and claimed can be replaced by equivalent elements and the details, materials, shapes and dimensions can be any.

Claims (11)

CLAIMS 1. Underwater propulsion device (1) adapted to be immersed in a fluid and comprising a conduit (20) defining a prevalent development axis (20a), an inlet section (20b) and an outlet section (20c); an attachment (30) adapted to allow a flow of gas under pressure to enter said conduit (20) through said inlet section (20b); characterized in that said duct (20) is convergent-divergent and comprises a divergent portion (22) and inlet holes (22c) made in correspondence with said divergent portion (22) and adapted to allow said fluid to enter said duct ( 20) mixing with said gas under pressure. 2. Underwater propulsion device (1) according to claim 1, wherein said holes (22c) have a substantially transverse axis with respect to said prevalent development axis (20a). 3. Underwater propulsion device (1) according to the preceding claim, wherein said axis of said holes (22c) is inclined with respect to said prevalent development axis (20a) by an angle substantially comprised between 15 ° and 60 °. 4. Underwater propulsion device (1) according to one or more of the preceding claims, wherein said diverging portion (22) comprises a first sector (22a) and a second sector (22b) defining said outlet section (20c) and having an angle of different divergence with respect to the divergence angle of said first sector (22a). 5. Underwater propulsion device (1) according to the preceding claim, in which said inlet holes (22c) are made in correspondence with said second sector (22b). 6. Underwater propulsion device (1) according to one or more of the preceding claims, comprising a conduit (40) and having an extension axis substantially coincident with said prevalent development axis (20a) and able to house at least part of said axis inside it diverging portion (22) so as to guide the external flow of said fluid along said diverging portion (22). 7. Underwater propulsion device (1) according to the preceding claim, wherein said conduit (40) is of the convergent-divergent type. Underwater propulsion device (1) according to the preceding claim, wherein said conduit (40) comprises a groove arranged in proximity to said outlet section (20c). Underwater propulsion device (1) according to one or more of claims 7-8, wherein said groove of said conduit (40) is arranged opposite to said inlet section (20b) with respect to said outlet section (20c ). Underwater propulsion device (1) according to one or more of claims 6-9, wherein said conduit (40) comprises a fixing body (43) adapted to constrain said conduit (40) to said conduit (20). 11. Underwater propulsion device (1) according to one or more of the preceding claims, in which said conduit (40) and said sectors (22a, 22b) are made in a single piece.