ITGE20120027A1 - SECOND STAGE OF PRESSURE REDUCTION FOR UNDERWATER USE PROVIDED WITH A BYPASS DUCT AND MEANS OF ADJUSTMENT OF THE GAS FLOW IN ENTRY OR OF THE PASSING FLOW TO THE INSIDE OF THAT BYPASS - Google Patents

Description

DESCRIPTION of the Industrial Invention entitled: â € œSecond pressure reduction stage for underwater use equipped with a bypass duct and means for regulating the incoming gas flow or the flow passing through said bypass ductâ €

TEXT OF THE DESCRIPTION

The present invention relates to a second pressure reduction stage for underwater use provided with a bypass.

There are known devices for delivering air or second pressure reduction stages for underwater use which can be connected to first pressure reduction stages suitable for reducing the high pressure (200-300 bar) of a breathable gas contained inside a tank, generally a cylinder, at a predetermined intermediate value, which second stages reduce the gas pressure from said intermediate value to a physiologically suitable value for breathing.

A second stage for delivering breathable gas for underwater use comprises a casing with an internal chamber equipped with:

- an inlet for the pressure air that can be connected, by means of a hose, to a first pressure reduction stage, which inlet is equipped with a device with a valve for reducing the pressure of the gas entering said chamber, - a Intake / exhalation opening through which the air fed into the internal chamber of the case is inspired by the user and through which the user feeds the exhaled air into the chamber, which opening is connected to a suction / exhalation port,

- an exhaust outlet for exhaled air equipped with a non-return valve.

US patent 4,002,166 describes a second pressure reduction stage provided with a bypass duct for conveying the entering breathing gas following the opening of the reduction valve, directly from the supply duct to the suction / exhalation union, bypassing the chamber inside the case.

The second stage requires that the bypass duct, external to the casing, has a tangential connection with the union and that inside the union there is a deflector with adjustable inclination.

Patent EP 937640 describes a second pressure reduction stage in which the bypass duct is formed as a piece inside the casing of said second stage.

The invention has the purpose of perfecting a second pressure reduction stage for underwater use provided with a bypass duct such as those described above in such a way that the inlet gas flow and / or the flow passing through can be regulated. ™ inside said bypass duct, in particular the flow rate of breathable gas in the direction of the suction / exhalation port.

A further object of the present invention is that of obtaining an improved second pressure reduction stage, which is easy and inexpensive to make and to overhaul.

The invention achieves the purposes described above by means of a second pressure reduction stage for underwater use comprising:

- a valve of a device for reducing the pressure of a breathable gas, which valve is interposed between a supply duct and an intake / exhalation port of said breathable gas,

- a box that contains pressure-sensitive means to control the opening / closing of said valve, the suction / exhalation port being connected to an opening on said box through which the breathing gas inhaled by the user is exhaled in the box, and being said box equipped with an exhaust outlet for exhaled air with a non-return valve,

- a duct, so-called bypass duct, for feeding said breathable gas from the pressure reducing device directly into the suction / exhalation port,

- means for regulating the inlet gas flow and / or the gas flow passing through said bypass duct.

Said adjustment means can allow the passage from a condition of total, or preferably partial blockage of the passage of the breathable gas, to a condition of maximum flow of breathable gas towards the suction / exhalation port, preferably they can allow the passage from a pre-dive position , with the possibility of breathing on the surface, using said second stage, in a condition that offers maximum performance of delivery of breathable gas in water, at pressures higher than atmospheric pressure.

In particular, it is possible to provide means for regulating the flow which can be moved between two different extreme positions, corresponding to the condition of maximum opening and maximum or partial closure of an opening for the passage of breathable gas.

Said flow regulating means terminate outside the casing with a manual control member for moving the said regulating means between said two extreme positions.

The displacement of said adjustment means between the two extreme positions can take place in jerks, and it is possible to provide means for stopping or stopping the displacement of said adjustment means with respect to the opening for the passage of the breathable gas.

According to a first embodiment, the adjustment means consist of a bush which is rotatably mounted in a sealed manner inside a hollow cylindrical element or air supply union, which forms part of the pressure reduction device, with an external part to said element or union consisting of a gripping and rotating control extension and a cylindrical internal part with a shell surface provided with one or more flow adjustment slots, having a predetermined opening and cooperating with an outlet for the breathable gas provided on said hollow cylindrical element.

Between said cylindrical element and said bush, it is possible to provide means, such as ribs or the like, and corresponding grooves, which allow the shifting in steps in one or both directions of rotation of said bush with respect to the hollow cylindrical element.

For example, a ratchet type rotation or similar is possible.

Alternatively or in combination with said means for rotation in steps, it is possible to provide abutment or end-of-stroke means which allow partial rotation of the bush around its own longitudinal axis.

According to a preferred embodiment to allow the rotation, in jerks for a certain angular stroke in both directions, of the bushing with respect to the hollow cylindrical element, in particular to allow the movement in jerks in several angular positions of the slots present on the bushing with respect to the breathable gas outlet opening present on the hollow cylindrical element, elastic snap-release locking means are provided in each of said angular positions.

Said means are constituted by an arc-like or C-shaped spring fixed coaxially to the bush with one of its terminal sections, in such a way as to rotate together with it but not to translate radially with respect to said bush, while the other terminal section of said C-shaped spring is free to oscillate in a radial direction with respect to the bush itself.

The spring substantially coaxially overlaps a circular crown of notches or radial recesses that delimits the inlet opening of the hollow cylindrical element. Said spring has on the extremity of the section that can be moved radially with respect to the bush, at least one element for removable engagement and retention of the bush in the predetermined angular positions, destined to be elastically snap-in and removable with a certain force, on two or more recesses radials distributed on an angular sector of the said crown.

At the end of the section constrained to the bushing there is at least one end-of-stroke element that allows the bushing to rotate on an arc of a predetermined length.

In particular, the end-of-stroke element consists of an internal radial tooth which is intended to engage in a peripheral recess provided on said crown, which peripheral radial recess has a predetermined angular extension and is delimited by collision walls radial teeth intended to cooperate with said radial tooth.

By then acting on the grasping and command extension of the bush, the bush itself rotates from one angular position to the other, integral with said spring, by sliding the engagement element from one recess to the next, until that the limit switch element does not abut against the collision wall which delimits the peripheral radial recess for displacement of the limit switch element.

According to a further embodiment, the flow adjustment means consist of a gas flow shut-off valve located in the bypass duct, which valve can be controlled from the outside thanks to manual gripping means that allow rotation. of the valve body or shutter inside said bypass duct.

This valve, which can be activated by the user, can totally or preferably partially obstruct the space inside the bypass duct and therefore allows to regulate the flow rate of the gas flowing inside the bypass duct, being It is possible to provide for said adjustment to take place continuously or in jerks.

The shut-off valve can be of the butterfly type or similar.

A movable deflector can be provided in the suction / exhalation port to facilitate inhalation and exhalation, which can be manually operated from the outside.

These and other characteristics and advantages of the present invention will become clearer from the following description of some executive examples illustrated in the attached drawings in which:

Fig. 1a shows a front view of a known second pressure reduction stage equipped with a bypass,

Fig. 1b shows a cut-away plan view of an embodiment of a known second pressure reduction stage provided with a bypass outside the casing,

Fig. 1c illustrates a partially sectioned top view of an embodiment of a known second pressure reduction stage provided with a bypass integrated in the casing,

fig. 2 illustrates a view of a second pressure reduction stage provided with a bypass and flow regulating means according to an embodiment of the present invention,

Fig. 3 illustrates a view of a second pressure reduction stage provided with a bypass and flow regulating means according to a further embodiment of the present invention,

Fig. 4 illustrates a top view of a second pressure reduction stage provided with a bypass and flow regulating means according to an embodiment of the present invention,

Figures 5a and 5b show a view of an embodiment of the flow regulating means according to the present invention,

Figures 6a, 6b, 6c illustrate the different positions of the flow adjustment means, made according to an embodiment, which can be moved between two extreme positions corresponding to the condition of maximum opening and maximum closing of the outlet opening to which it is connected the bypass duct,

figs. 7a, 7b illustrate an embodiment of the flow regulating means according to the present invention,

Figures 8a, 8b illustrate the different positions of the flow adjustment means, made according to a further embodiment, provided in the bypass duct, between two extreme positions corresponding to the condition of maximum opening and maximum closure of the bypass duct.

With reference to Figures 1a, 1b, 1c, they illustrate a second pressure reduction stage 1 for underwater use provided with a bypass duct 101, according to the known art.

The function of the second pressure reduction stage for underwater use is to reduce the pressure of the breathing gas coming from a first pressure reduction stage and deliver it to the ambient pressure depending on the depth in which the diver is.

A first pressure reduction stage for underwater use allows to reduce the high pressure of the air contained in the cylinder itself (200-300 bar) up to an intermediate pressure of 8/10 bar higher than the ambient one. The second stage, connected to the first stage, therefore allows a further reduction in pressure.

As illustrated in Figures 1b and 1c, said second stage 1 consists of a casing 106 which contains pressure-sensitive means for controlling the opening / closing of a valve of a device for reducing the pressure of a breathable gas conveyed in said device through a supply duct 103, from a first pressure reduction stage (not shown) connected to a source of breathable gas, generally a cylinder.

As is known, the second stage pressure reduction device comprises a hollow cylindrical element 107 or union, with an inlet opening 117 for the breathable gas which communicates, through a valve, with a connected gas supply conduit 103 to a first stage of pressure reduction (not shown).

As illustrated in Figure 1b, all or part of the hollow cylindrical element 107 can be provided, on an external side of the casing 106, as a cylindrical extension of the peripheral wall of the casing itself. Or, as illustrated in figure 1c, the hollow cylindrical element 107 can be provided integrated in the casing, realized as a hollow extension, of the casing itself, which extends in a radial direction, so that the inlet opening 117 of the breathable gas of the cylindrical hollow element 107 is made on the wall of the case 106 itself.

Therefore, for simplicity of presentation and description, in the text the expression â € œhollow cylindrical element or union 107â € means both a hollow cylindrical element 107 provided on the external side of the case 106, as illustrated in figure 1b, and an element hollow cylindrical 107 integrated in the casing 106, as illustrated in figure 1c, which appears as a hollow lateral extension of the casing 106 itself.

At the inlet opening 117 of the breathable gas, a sealing terminal can be provided, for example in the form of a bushing for the connection of said supply duct 103 with said hollow cylindrical element or union 107.

Inside the hollow cylindrical element 107 a shutter 108 of a valve seat 104 is slidably mounted, in particular a piston shutter with an enlarged head connected in one piece to a stem which engages in a hole provided on a wall opposite the breathable gas inlet 117.

The valve seat 104 consists of a radial narrowing, inside the hollow cylindrical element 107, which defines an opening, along the central longitudinal axis of said hollow cylindrical element 107, with sharp edges that can cooperate with the surface of the head of the obturator 108 in such a way as to ensure a perfect sealing of said seat 104 when the obturator is in the closed position, that is, it abuts against the valve seat 104.

A spring 109 pushes the shutter 108 with a predetermined force in a stable closing direction. The shutter 108 is articulated, in a known manner, to a lever 110 which is oscillating and is controlled by a deformable membrane 111 which forms a part of the external wall of the casing 106.

In the embodiment illustrated in figure 1c, inside the hollow cylindrical element 107, there is a lever-holder union indicated with the number 217, provided with an opening 227.

The box 106, through an opening, communicates with a suction / exhalation nozzle 102, through which the breathable gas inspired by the user is exhaled inside the case 106. The suction / exhalation nozzle is provided of a mouthpiece 105.

An exhaust outlet is provided on the casing 106 for the exhaled air which is fed into the casing 106 itself through the nozzle 102 and the intake / exhalation opening. The said outlet is equipped with a non-return valve, like a membrane, which opens with the increase in pressure inside the case 106 generated by the influx of gas in the exhalation phase and which is kept in closed condition by the very elasticity of the material with which the non-return valve is made.

During the suction phase, the depression generated inside the casing 106 causes the membrane 111 to push on the lever 110 which acts against the elastic means 109, ie the spring, and moves the shutter 108 away from the valve seat 104, in the open position, so that the gas under pressure, from the supply duct 103 can enter, from the inlet opening 117, through the valve seat, inside the hollow cylindrical element 107 of the reduction device and exit from an outlet opening 112, provided on the shell surface of said hollow cylindrical element 107, to which a dedicated supply conduit 101, so-called bypass conduit, is connected.

The pressure reduction device, having the function of lowering and regulating the pressure of the breathable gas, adapting it to the ambient one, therefore has a valve seat 104 interposed between an opening for the inlet of gas 117 at intermediate pressure (coming from from the first pressure reduction stage) and an outlet opening 112, for the reduced pressure gas.

Said bypass duct, connected to the outlet opening 112, carries the breathable gas directly into the intake / exhalation port 102, without the gas passing inside the casing 106.

As illustrated in the figures, for example in figure 1c, said gas outlet opening 112 towards the bypass duct 101 and therefore in the intake / exhalation port 102 consists of a lateral opening 112 provided in the casing wall of the element hollow cylindrical 107.

As is known, the bypass duct 101 can be external to the casing 106 (Figure 1b) or obtained as a piece in the thickness of the wall of the casing 106 of said second stage 1 (Figure 1c).

In the embodiments illustrated as prior art, in particular in figure 1b, said hollow cylindrical element 107 crosses the wall of the casing 106 in a single point at which it is tightly fixed to the casing 106 and is connected, with the end open, to the gas supply duct 103, while it has a length such as to terminate, with the other end, closed, inside the box 106 itself.

However, according to known embodiments, not shown, said hollow cylindrical element 107 can terminate, even with the end not connected to the gas supply duct 103, outside the case, by means of a terminal element which constitutes a pusher assembly axial manually controllable from the outside of the casing 106, which pusher assembly acts on the elastic means or on the spring 109 which in turn acts on the obturator 108 of the valve seat 104. As is known, said pusher assembly consisting of several elements coaxial and sealed together, for example by means of an o-ring, it has one end outside the case, which can be grasped by the user, such as a knob, and one end inside the case, abuts against a stop for the spring 109, axially sliding, in such a way that a rotation of the external part determines an axial translation of said abutment and therefore a different preload condition of the spring 109 on The shutter 108 of the valve seat 104.

According to the present invention, as illustrated in Figures 2 to 12, means are provided for regulating the incoming gas flow 2,3 and / or the gas flow passing through said bypass duct 101.

In particular, said means allow to control the flow rate of the breathable gas flow, coming from a first pressure reduction stage, which flows inside the bypass duct 101 and exits in the suction / exhalation port 102.

According to an embodiment illustrated in figures 2, 4, 5a, 5b, 6a, 6b, 6c, 7a and 7b, said adjustment means consist of a bush 2 which is rotatably mounted in a sealed manner inside said cylindrical element cable 107 with an external part 202 to said element 107, consisting of a gripping and rotating control extension 202, such as a radial extension in the form of a ring or an extension in the form of a lever, and an internal part 201 cylindrical, which cooperates with the hollow cylindrical element 107, having a shell surface provided with one or more flow adjustment slots 211, having a predetermined opening and cooperating with the outlet opening 112 for the gas flow provided on the shell surface of the hollow cylindrical element 107 of the reduction device.

In the embodiment of a second stage as illustrated in figure 1c, the bush 2 is provided rotatably mounted in a sealed manner inside said hollow cylindrical element 107, with the internal cylindrical part 201 of the bush 2 positioned between the internal wall of said element hollow cylindrical 107 and the outer wall of the lever-holder bushing 217.

As illustrated in figure 2, the radial grip and control extension can have a knurled surface to facilitate gripping or, as illustrated in figures 7a and 7b, it can be like a knob.

Once the bushing 2 is mounted coaxially in the cylindrical element 107 with a cutout 211 at least partially coinciding with the outlet opening 112 provided on the shell of said cylindrical element 107 and communicating with the bypass duct 101, and the supply duct 103 is coupled to the open end of said hollow cylindrical element 107, the gas can flow from the first pressure reduction stage connected to a source of breathable gas (obviously when the valve seat 104 is in the open condition ie when the obturator is axially spaced from said seat 104), in the bypass duct up to the suction / exhalation port 102.

It is possible to provide abutment or end-stroke means for angular displacement of the bushing 2 in such a way as to move the cut-out (s) 211 present on the cylindrical internal part 201 of the bushing 2 in different angular positions, between two extreme positions, with reference to the position of the outlet opening 112 in the hollow cylindrical element 107, which is obviously fixed.

Said means can avoid a 360 ° rotation of the bush 2, but allow a partial rotation, for a certain angular stroke, of said bush with respect to the hollow cylindrical element 7.

Said abutment or end-stroke means for angular displacement of the bush 2 can be constituted by one or more strikers, teeth or the like, provided on the surfaces of the bush 2 and of the cylindrical hollow element 107 and cooperating with each other, to have a correct relative angular positioning of the cutout (s) 211 provided on the cylindrical internal part 201 of the bushing 2, with the outlet opening 112 provided on the hollow cylindrical element 107.

Said abutment or end-stroke means for angular displacement of the bush 2 can be constituted by one or more strikers, teeth or the like, provided on the bush 2, in particular on the gripping and rotation control extension 202, and on the surface external of the casing 106, said means being cooperating with each other.

For example, it is possible to provide that said means are on the lid which covers and protects the deformable membrane 111.

For example, said means can be constituted by strikers provided on the external surface of the casing and / or of the cylindrical element 107 intended to cooperate with the external gripping part 202 of the bushing 2, made for example as a lever.

Said bushing 2 is therefore mounted coaxially superimposed at least partially inside, on one end of the cylindrical hollow element 107, so that the external part of the bushing 2 constituted by the gripping and rotation control extension 202 can also constitute an abutment abutment against the edge of the inlet opening of said hollow cylindrical element 107.

It is possible to provide that said external part 202 is either in the form of a ring or in the form of a lever integral with said internal cylindrical part 201, which external part 202 constitutes a grasping and angular displacement means of the bush 2 around its own axis, as shown in figure 4.

It is possible to foresee that the internal cylindrical part 201 has a smaller axial extension than the axial extension of the hollow cylindrical element 107.

Furthermore, the bushing 2 is mounted and the cylindrical internal part 201 has a length such as not to interfere with the pressure-sensitive means which control the opening / closing of the valve seat 104. In particular, said means for regulating the flow 2 are not they interfere with the operation of the shutter 108 which moves in the direction of departure and approach against the valve seat 104.

Said bushing 2 in engaged condition inside the hollow cylindrical element 107, has the outer shell surface of the cylindrical inner part 201 which extends substantially flush with at least a portion of the inner shell surface of said hollow cylindrical element 107 .

According to one embodiment, the bushing 2 is rotatably held against the internal wall of the hollow cylindrical element 107 thanks to sealing gaskets, for example thanks to one or more gaskets of the O-ring type, arranged parallel to each other in a certain distance in the axial direction on the cylindrical inner part 201 of the bushing 2.

The said gasket or seals can be housed in peripheral grooves on the shell surface of the cylindrical inner part 201 of the bushing 2 and / or in peripheral grooves on the inner shell surface of the hollow cylindrical element 107 which cooperates with the surface of said inner part cylindrical 201.

According to the present invention, said flow adjustment means 2 can be moved, by rotation on its own axis, between two different extreme positions corresponding to the condition of maximum opening and maximum or partial closure of the outlet opening 112 placed on the surface of the casing of the Hollow cylindrical element 107, which communicates with the bypass duct 101, and through which the air drawn in by the first pressure reduction stage comes out, through the supply duct 103 when the obturator 108 is spaced from the valve 104, i.e. when the valve is in the open condition.

According to an embodiment, between the hollow cylindrical element 107 and the flow regulation means 2, means are provided which allow the shifting in steps in one or both directions of rotation of said flow regulation means, in particular of the bushing 2, with respect to the hollow cylindrical element 107.

For example, as illustrated in Figure 5b, it is possible to provide on at least part of the outer shell surface of the cylindrical inner part 201 of the bushing 2, in contact with the inner surface of the shell of the hollow cylindrical element 107, one or more radial ribs which protrude outwardly from the outer shell surface of said cylindrical inner part 201 of bushing 2, and which cooperate with one or more corresponding engagement grooves provided on the inner shell surface of the hollow cylindrical element 107.

Alternatively or in combination, it is possible that said rib or ribs are provided on the portion of the shell surface of said hollow cylindrical element 107 which cooperates with said bush 2 and that the respective engagement grooves are on the outer shell surface of said part internal cylindrical 201 of the bushing 2.

Said ribs can have a sawtooth or triangular trapezoidal section, that is with at least one of the longitudinal sides of said ribs inclined with respect to the surface of the skirt, or rounded, so as to form an external recess surface which facilitates the positioning of said ribs ribs in the respective grooves and which facilitates rotation in at least one direction.

In fact, it is possible to obtain that the rotation takes place in one direction only by providing ribs that have only one inclined longitudinal side.

Preferably the rotation of the bush 2 with respect to the hollow cylindrical element 107 occurs in both directions thanks to the fact that both longitudinal sides of the ribs are inclined or thanks to the fact that said ribs have a rounded surface.

Thanks to said conformation and to a certain elastic flexibility of the material that constitutes said ribs, it is possible to engage said ribs in said grooves by means of a snap-fit, thanks to a relative rotation of the bush 2 with respect to the hollow cylindrical element 107.

Alternatively, the shifting in steps in one or both directions of rotation of said means for regulating the flow, in particular of the bushing 2 with respect to the hollow cylindrical element 107, can be obtained by means of one or more teeth and / or radial grooves provided on the annular abutment surface of the outer part 202 of the bushing 2, in the form of a ring 202, against the edge of the inlet opening 117 of the hollow cylindrical element 107, which teeth and / or grooves cooperate with corresponding grooves and / or radial teeth placed on said edge.

It is also possible to provide that the stepwise displacement in one or both directions of rotation of said flow regulating means, in particular of the bushing 2 with respect to the hollow cylindrical element 107, can be obtained by means, such as one or a plurality of strikers or the like, provided on the bushing 2, in particular on the gripping and rotation control extension 202, and on the outer surface of the body, said means cooperating with each other.

Or, if the command and gripping element 202 consists of a lever, it is possible to provide that said lever cooperates with the radial teeth and / or grooves provided on the edge of the entry opening 117 of the element hollow cylindrical 107.

According to a preferred embodiment illustrated in Figures 7a and 7b, the bush 2 can have the radial gripping and control extension 202 fixed in an element like a knob 212 which facilitates gripping and rotation of said bush 2 by the user.

As illustrated in Figures 7a and 7b, in order to allow the rotation in clicks for a certain angular stroke in both directions of the bush 2 with respect to the hollow cylindrical element 107, elastic snap-release means 5 are provided.

Said means consist of a spring 5 in the shape of an arc or C which overlaps a circular ring 7 of radial notches or recesses 701, 702 which delimits the inlet opening 117 of the hollow cylindrical element 107.

The spring 5 is fixed coaxially on the bushing 2 with one of its terminal sections, by means of two or more pins 501 intended to engage in corresponding holes 222 provided on the surface of the radial gripping and control extension 202 in contact with said spring 5.

The spring 5 can therefore rotate together with the bush 2 and has a terminal portion which cannot translate radially, due to the presence of the pins 501 and the holes 222, with respect to the bush 2 while the opposite terminal portion, not constrained to the bush 2, is free to translate radially with respect to said bushing 2. The spring 5 has at the end of the terminal portion free to translate radially with respect to the bushing 2, on its internal arched surface, a rounded element or tooth 502 for removable engagement and retention of the bushing 2 in the predetermined angular positions, while at the end of the section fixed to the bushing 2 there is a tooth or end-of-stroke element with trapezoidal section or similar 503.

Said engagement element 502 and said end-of-stroke element 503 are intended to engage respectively in two or more radial recesses with rounded surfaces 701 arranged on an angular sector of the crown and in a peripheral radial recess 702, with predetermined angular extension, being said recesses provided on the circular crown 7 which delimits the inlet opening 117 of the hollow cylindrical element 107.

The angular amplitude of the spring 5, the angular position of the stop element 503 and the angular position of the engagement element 502 with respect to the axis of rotation and the corresponding angular position of the recesses 701 and of the recess of limit switch 703 in which respectively the engagement element 502 and the limit switch element 503 are commensurate in such a way that when the engagement element 502 fits into the last recess 701 provided on the crown 7 the limit switch element 503 is in one of the two limit switch positions I and when the engagement element 502 fits into the last recess 701 in the opposite direction, the limit switch extension 503 is arrived in the opposite end position II. Figures 7a and 7b illustrate a sealing fitting in the form of a bushing 8 for connecting the gas supply duct 103 to the hollow cylindrical element or union 107.

Thanks therefore to the elasticity of the spring 5 it is possible to obtain the jerky rotation in both directions of the bush 2, fixed to a section of said spring 5, and its positioning in one, two or more angular positions in such a way as to bring the cutout (s) 211 of the bushing into a position offset or corresponding to the gas outlet opening 112.

According to an embodiment, it is possible to provide that said or said slots 211, provided on the cylindrical internal part 201 of the bushing 2, consist of two or more holes of different diameter, in particular one or more holes with increasing diameter, for example circular holes or elliptical, placed side by side along an arc of circumference on the outer surface of the cylindrical internal part 201 of said bush 2.

Alternatively, said slot consists of a single slot hole 211, with an increasing diameter in the direction of one end of said slot, i.e. a slot shaped like a drop or similar, placed along an arc of circumference on the surface of the shell of the cylindrical internal part 201 of said bush 2.

It is possible to provide that said or said slots 211 provided on the shell surface are substantially in a median position with reference to the axial extension of said internal cylindrical part 201.

According to one embodiment, the hole 211 with a larger diameter, if more holes are provided, or the part of the slot with a larger diameter, in the case where a single slot window is provided, has a size and / or shape corresponding to the outlet opening 112 to which the bypass duct is connected.

This allows that when said opening 211 and said outlet opening 112 are brought to coincide, the flow rate of the gas flow towards the suction / exhalation port 102 is maximum.

The hole 211 with a smaller diameter, if there are more holes, or the part of the slot with a smaller diameter, if a single slot is provided, has a size and / or shape that guarantees, when brought to coincide with the outlet opening 112, a minimum passage of gas towards the user's mouth which allows normal breathing in conditions of use of the second stage. This minimum range may be necessary when the user breathes on the surface through the second stage, while the maximum range may be necessary at greater depths and / or in conditions of breathlessness when the inhalation effort and the demand for breathing gas is high.

It is possible to provide any shape and size for said or said slots, such as for example the one shown in figure 5a, which can regulate the flow rate of the fluid by cooperating with the outlet opening to which the bypass duct 101 is connected.

Figures 6a, 6b, 6c illustrate the possible angular positions of the bushing 2 between the two extreme working positions, in particular between the position of total interruption of the gas flow towards the bypass duct and therefore towards the suction / exhalation union 102 , and the position of total opening of the bypass duct 101 which guarantees the maximum flow rate of the gas flow towards the suction / exhalation port 102.

The figures illustrate, by way of example, a bushing 2 with a slot 211 in the form of a slot with one of the ends of said slot thinned with respect to the other. In particular, the buttonhole consists of an elongated slot that ends at one end with a circular opening.

In figure 6a the bush 2 is rotated in such a way that the cutout 211 is completely offset with respect to the outlet opening 112, i.e. it does not coincide with said opening 112 so that said opening 211 remains closed by the casing wall of the part internal cylindrical 201 of the bushing 2 without cutout, and consequently the air fed towards the casing 106, through the hollow cylindrical element 107, cannot escape from the outlet opening 112, towards the bypass duct and the suction / exhalation nozzle 102.

In these conditions, air cannot flow into the user's mouth.

In figure 6b the bushing 2 is rotated so that a portion of the slot 211, in particular the portion with smaller dimensions, in the form of an elongated slot, coincides with the outlet opening 112 to which the bypass duct is connected 102. The outlet opening 112 is therefore partially closed and the outgoing gas flow towards the suction / exhalation port 102 is partialized.

In this case a fraction of the breathable gas fed to the case 106 can flow into the user's mouth passing directly from the supply duct 103 into the bypass duct 101 and from there into the intake / exhalation port 102.

In figure 6c the bush 2 is rotated so that a portion of the cutout 211, in particular the portion with larger dimensions, similar in shape and size to the outlet opening 112, coincides with said outlet opening 112 to which it is the bypass duct 102 is connected. The outlet opening 112 is then completely open and all the breathable gas entering the hollow cylindrical element 107 can freely flow through the bypass duct 101 into the suction / exhalation port 102. In these conditions the flow rate of the fluid is maximum.

As described above, it is possible to provide abutment means or limit switches which avoid the condition illustrated in figure 6a, i.e. the total closure of the outlet opening 112, so that during the inhalation phase, which leads to the opening of the seat valve 104, at least a minimum quantity of gas can flow into the user's mouth by partially closing the outlet opening 112.

According to a variant, it is also possible to provide that the adjustment means consist of a bush 2 with one or more openings placed on the surface of the shell of the cylindrical internal part 201 along its longitudinal axis and that said bush can translate along the axis longitudinal section of the hollow cylindrical element 107 between the two extreme positions of maximum opening and maximum or partial closure of the outlet 112 which communicates with the bypass duct 101.

From the above it is evident the ease and speed of assembly of the bushing 2 on a second pressure reduction stage 1 provided with a bypass duct 101.

The presence of the regulating means allows to adapt the second stage 1 to different conditions of use, in particular to different conditions of ambient pressure and / or to different pressure conditions of the breathable gas coming from the first pressure reduction stage, as well as to adapt the flow rate of the breathable gas and therefore the softness or hardness of the second stage to the wishes and needs of the user. This is made possible thanks to the cutout or slots 211 present on the adjustment bushing 2 which have different dimensions and / or a different conformation and / or a different position with respect to the outlet opening 112 to which the bypass duct is connected. .

According to a further embodiment illustrated in figures 3, 8a, 8b, the flow adjustment means can consist of a valve 3, which can be operated by the user, which can totally or partially obstruct the space inside the duct and therefore allows you to adjust the flow rate of the gas flowing inside the bypass duct, since it is possible to provide for this adjustment to take place continuously or in jerks.

The shut-off valve can be of the butterfly type or similar.

As shown in the figures, the flow shut-off valve 3, of the butterfly type, eccentric or similar, is placed on the bypass duct 101, and can be controlled from the outside thanks to manual grasping means that allow the rotation of the body. of the valve inside the said bypass duct 101.

As shown in the figures, the valve body or shutter member is a disk 301 which rotates around an axis perpendicular to the longitudinal axis of the bypass duct 101, connected by means of a shaft to a handwheel control element or to a lever 302 in so that the valve can be operated from the outside by the user, by hand.

The disc 301 can be rotated between two extreme positions of total opening or total or partial closure of the bypass duct 101.

It is possible to provide along the edge of the disc 301 a ring element or a plastic coating to ensure sealing when the larger surfaces of the disc are perpendicular to the direction of flow, in the closed condition of the bypass duct 101.

As described above for the bushing 2, the axial rotation, in one or both directions, of the obturator disc 301 can take place in steps thanks for example to the presence of cooperating teeth with respective seats placed on the control element 302 and / or on the Shaft, and on the surface of the bypass duct 101, outside or inside said duct 101.

It is possible to provide, as an alternative or in combination with said means that allow the rotation in steps, limit-stroke means that allow the movement of the shutter disc from a condition of maximum opening (with the surfaces of the disc parallel to the direction of flow) to a condition of total (with the surfaces of the disc 301 perpendicular to the direction of flow) or partial closure of the bypass duct 101, such as strikes provided on the outer wall of the duct 101 and intended to cooperate with the control element 302.

Said valve, opening and closing, allows the regulation of the flow by varying the flow rate of the breathable gas entering the suction / exhalation port 102: when it is completely open, i.e. when the surfaces of the disc 301 are parallel to the flow direction, the flow it will be maximum while rotating it creates a restriction in the bypass duct 101 which reduces the amount of air that can be sucked in through the intake / exhalation nozzle 102, until the flow inside the bypass duct 101 is completely blocked.

As in the case of the adjustment mechanism, by means of the bushing 2, it is possible to provide abutment means or limit switches positioned in such a way as to avoid rotation of the disk 301 until the bypass duct 101 is completely closed.

According to a further embodiment, it is possible to provide in the suction / exhalation mouthpiece 102 a mobile flow diverter 4, which acts on the Venturi effect, consisting of an external part like a lever 402 connected to an internal part 401 a vane guide, whose angular position with respect to the direction of the gas flow in the suction / exhalation port 102 is manually adjustable from the outside by the user.

Preferably the blade 401 is positioned inside and pivoted substantially in the center of the suction / exhalation mouthpiece 102 in such a way that the larger surface faces of said blade 401 extend along the length of the suction / exhalation mouth 102 on a plane parallel to the longitudinal axis of the union 102, considered in the common mode of use.

Said vane can be rotated around a vertical axis perpendicular to the longitudinal axis of the union 102, considered in the common mode of use, in such a way as to be able to be positioned at an angle inside said union.

The invention is not limited to the embodiments described above but variations and / or modifications can be made to the second stage object of the present invention without abandoning the inventive concept described and claimed.

Claims (17)

CLAIMS 1. Second stage of pressure reduction for underwater use (1) comprising: - a valve of a device for reducing the pressure of a respirable gas, which valve is interposed between a supply duct (103) and a suction / exhalation port (102) of said respirable gas, - a casing (106) which contains pressure-sensitive means for controlling the opening / closing of said valve, the suction / exhalation port (102) being connected to an opening on said casing (106) through which the breathable gas inspired by the user is exhaled in the box (106), and being said box equipped with an outlet for the exhaled air with a non-return valve, - a duct (101), so-called bypass duct, for feeding said breathable gas from the pressure reduction device directly into the suction / exhalation port (102), characterized in that means (2,3) are provided for regulating the inlet gas flow and / or the gas flow passing through said bypass duct (101). 2. Second stage (1) according to claim 1 characterized by the fact that said means for regulating the flow (2,3) can be moved between two different extreme positions corresponding to the condition of maximum opening and maximum or partial closure of a passage of breathing gas flow. 3. Second stage (1) according to claim 1 or 2 characterized by the fact that said flow adjustment means (2,3) terminate outside the casing (106) with manual control elements for moving the said adjustment means (2,3) between said two extreme positions. 4. Second stage (1) according to one or more of the preceding claims, characterized in that said adjustment means consist of a bush (2) which is rotatably mounted in a sealed manner inside a hollow cylindrical element (107) which constitutes part of the device for reducing the pressure of the breathable gas, which bush (2) has an external part (202) to said element (107), consisting of a gripping and rotating control extension (202), to as a ring or lever, and an internal cylindrical part (201), which cooperates with the hollow cylindrical element (107), the surface of said bush (2) being provided with one or more adjustment slots (211) of the flow, having a predetermined opening and cooperating with an outlet opening (112) for the gas flow provided on the shell surface of the said hollow cylindrical element (107) of the reduction device. 5. Second stage (1) according to claim 4 characterized in that said or said slots (211) consist of two or more holes of different diameter, in particular one or more holes with increasing diameter, such as circular or elliptical holes, placed side by side along an arc of circumference on the shell surface of the cylindrical internal part (201) of said bush (2). 6. Second stage (1) according to claim 4 characterized by the fact that said cutout (211) consists of a single slot hole (211), with an increasing diameter in the direction of one end of said slot, i.e. a slot in the form of a drop or the like, placed along an arc of circumference on the shell surface of the cylindrical internal part (201) of said bush (2). 7. Second stage (1) according to one or more of the preceding claims, characterized by the fact that there are provided abutment or end-of-stroke means, such as strikers, teeth or the like, for angular displacement of the bush (2) with reference to the position of the exit opening (112) of the hollow cylindrical element (107) in such a way as to move the cutout (s) (211) present on the cylindrical internal part (201) of the bushing (2) in different angular positions, between said two extreme positions . 8. Second stage (1) according to one or more of the preceding claims, characterized in that means are provided which allow the shifting in steps in one or both directions of rotation of said bush (2), with respect to the hollow cylindrical element ( 107). 9. Second stage (1) according to claim 8 characterized in that said means for the angular displacement in steps consist of one or more radial ribs, with one or both inclined longitudinal sides, which protrude outwards from at least part of the shell surface of said inner cylindrical part (201) of bushing (2) and cooperate with one or more engagement grooves provided on at least part of the inner shell surface of hollow cylindrical element (107) and / or vice versa. 10. Second stage (1) according to claim 8 characterized in that said means for the angular shifting in steps consist of one or more teeth and / or radial grooves provided on the edge of the inlet opening (117) of the Hollow cylindrical element (107) and cooperating with corresponding teeth and / or grooves provided on the annular abutment surface, against the edge of said opening (117), of the gripping and rotary control extension (202) in the manner of ring, or cooperating with the gripping and rotary control extension (202) as a lever. 11. Second stage (1) according to one or more of the preceding claims from 1 to 8, characterized by the fact that elastic snap-on removable locking means (5) are provided which allow the rotation in clicks in one or more angular positions and for a certain angular stroke, in both directions, of the bushing (2) with respect to the hollow cylindrical element (107). 12. Second stage according to claim 11 characterized by the fact that said means consist of an arc or C-shaped spring (5) which is substantially coaxially superimposed on a circular ring (7) of radial notches or recesses (701.702) which delimits the inlet opening (117) of the hollow cylindrical element (107), which spring (5) is fixed coaxially to the bushing (2) with one of its terminal sections in such a way that said terminal section cannot translate radially with respect to the bushing (2) while the opposite end portion is free to oscillate in a radial direction with respect to the bushing itself (2), said spring (5) being provided at the end of the terminal portion free to translate radially by at least one element ( 502) for engagement and retention of the bushing (2) in the predetermined angular positions which engages elastically snap and removably on two or more radial recesses (701) distributed on an angular sector of the det the crown (7) and being said spring (5) provided at the end of the terminal portion fixed to the bushing (2) with at least one end-of-stroke element (503) which engages in a peripheral radial recess (702) with predetermined extension radial and delimited by radial striking walls, being the angular width of the spring (5), the angular position of the limit switch element (503) and of the engagement element (502) with respect to the axis of rotation and the corresponding angular position of the radial recesses (701) and of the peripheral radial recess (703) commensurate so that when the engagement element (502) fits into the last radial recess (701) provided on the crown (7), the limit switch element (503) is in one of the two limit switch positions (I) and when the engagement element (502) fits into the last radial recess (701) in opposite direction, the limit switch element (503) has arrived in the opposite end position position a (II). 13. Second stage (1) according to one or more of the preceding claims 1 to 3 characterized by the fact that the flow regulating means consist of a flow shut-off valve (3), placed on the bypass duct, which can be activated by the User, which valve totally or partially obstructs the space inside the bypass duct and therefore allows you to adjust the flow rate of the passage gas inside the bypass duct. 14. Second stage (1) according to claim 13 characterized by the fact that the flow cut-off valve (3), placed on the bypass duct (101), is of the butterfly type or the like, and consists of a body of the valve or disc-like shutter member (301) which rotates around an axis perpendicular to the longitudinal axis of the bypass duct (101), connected to a handwheel or lever control element (302) so that the valve can be operated from the outside by the user. 15. Second stage (1) according to claim 13 or 14 characterized in that means are provided for axial rotation in steps, in one or both directions, such as teeth or the like cooperating with respective seats placed on the control element (302 ) and / or on the surface of the bypass duct (101), alternatively or in combination with limit switch means that allow the movement of the shutter disc (301) between a maximum opening position and a maximum or partial closing position of the bypass (101). 16. Second stage (1) according to one or more of the preceding claims, characterized in that a mobile flow diverter (4) is provided in the suction / exhalation mouthpiece (102) comprising an external control part (402) connected to a internal part (401) with vane guide, whose angular position with respect to the direction of the gas flow in the suction / exhalation port (102) is manually adjustable from the outside by the user. 17. Second stage (1) according to claim 16 characterized by the fact that the blade (401) is pivoted substantially in the center of the suction / exhalation mouthpiece (102) so that the larger surface faces of said blade (401) extend along the length of the suction / exhalation nozzle (102) on a plane parallel to the longitudinal axis of the nozzle (102), considered in the common mode of use, since said blade can be rotated around a vertical axis perpendicular to said axis length of the nozzle (102) so that it can be positioned at an angle inside the said intake / expiration nozzle (102).