ES2749052T3 - An integrated system for regulating and mixing oxidizer and fuel for a burner - Google Patents

Abstract

An integrated system (100) for regulating and mixing oxidizer and fuel for a burner, comprising: a valve (1) for the fuel comprising an inlet passage (8) and an outlet passage (80) for the fuel; ventilation means (40) comprising a first inlet (41) for the oxidizer, a second inlet (54) for the fuel and an outlet connectable to the burner; the second inlet (54) for the fuel is connected to the outlet passage of the valve (1) to receive the fuel that passes through the valve (1): the valve (1) comprises a valve phase comprising a shutter (11) interposed between the inlet passage (8) and the exit passage (80) and movable along a movement axis (12), between an open position, to allow the passage of the fuel, and a position closing to block the passage of fuel; the valve (1) also comprises a unit (15) to move the shutter (11) functionally associated with the shutter (11) to move it from the closed position to the open position; characterized in that the valve phase comprises means (60) for holding functionally active positions between a fixed area (9) of the valve (1) and the plug (11) and that can be configured between an activation condition during which they hold the shutter (11) in an open position, and a deactivated position; during the activation condition, the means (60) for holding in position are configured to act on the shutter (11) when the latter is in an intermediate position between the open position and the closed position; the unit (15) for moving the shutter (11) is configured to move the shutter (11) from the open position to the intermediate position; and characterized in that it comprises a unit (63) for detecting oxidizer along the first inlet (41) configured to detect the presence of oxidizer in transit along the first inlet (41); the system (100) comprises means for activating the means (60) for holding in position functionally connected to the unit (63) to detect the oxidizer and configured to activate the means (60) for holding in position when the unit (63) stops detecting oxidizer detects the presence of oxidizer in transit along the first inlet (41).

Description

DESCRIPTION

An integrated system for regulating and mixing oxidizer and fuel for a burner

Technical field

This invention relates to an integrated system for regulating and mixing oxidizer and fuel for a burner.

More specifically, the integrated system is defined by the set of a valve body for the fuel and a fan for the oxidizer. In more detail, the integrated system according to this invention is directed to the sector of preparing a mixture between fuel and oxidizer to be fed to a burner.

More specifically, the system is dedicated to the mixture between air (as an oxidizer) and gas (as a fuel). Background of the Art

According to the prior art represented, for example, by the content of US patent document 8596957, the valve body extends between an inlet passage and an outlet passage for the gas. The fan comprises an inlet where gas and air are combined and an outlet connectable to the burner. More specifically, the gas outlet passage is placed in fluid communication with the fan inlet in such a way that the latter can receive the gas to mix with the air.

More specifically, the valve body comprises at least one valve phase (usually two valve phases) which, in turn, comprises a plug interposed between the inlet passage and the outlet passage and movable along an axis of movement, between an open position, to allow the passage of gas, and a closed position to block the passage of gas.

The valve body also comprises a unit for moving the plug functionally associated with the plug to move it from the closed position to the open position and vice versa.

Preferably, electromagnetic systems are used to move the shutter. In these electromagnetic systems, the plug is moved by an electromagnetic attraction between a ferromagnetic part, usually mounted on the plug, and an electromagnetic circuit associated with the valve frame.

In this way, when the system is activated, it is supplied to the fan and the shutter is opened in such a way as to make the mixture of air and gas. It should be noted that, during a system operating condition, the shutter is kept in the open position thanks to the constant presence of the electromagnetic field. This prior art, however, is not without its drawbacks.

More specifically, the main drawback is linked to the fact that the movement of the shutter is independent of the operation of the fan. Consequently, if the fan is stationary (for example, because it has been clogged or due to a malfunction of the control system), the shutter could be in the open position, passing gases that would accumulate inside the fan.

This accumulation of gas can become dangerous both for the next fan start (the burner would be supplied with an excessive amount of fuel) and for the environment in which the system is positioned since the gas could escape.

The same situation could occur if the air inlet duct or the smoke outlet duct (flue gas duct) is completely or partially obstructed. Indeed, in that case, there is not enough air flow to guarantee correct mixing and subsequent combustion.

Other examples of prior art systems for regulating and mixing oxidizer and fuel for a burner are shown in patent documents EP2442028 and US 2010/314469.

Intention of the invention

In this situation, the intention of this invention is to provide an integrated system for regulating and mixing oxidizer and fuel for a burner that overcomes the aforementioned drawbacks.

In particular, the intention of this invention is to provide an integrated system for regulating and mixing oxidizer and fuel that allows an increase in the level of safety in situations where there is not sufficient flow rate of the oxidizer present.

Another intention of this invention is to provide an integrated system for regulating and mixing oxidizer and fuel that allows to automatically establish safe conditions for the system in situations where there is not sufficient flow rate of the oxidizer present.

The stated intentions are substantially achieved by an integrated system for regulating and mixing oxidizer and fuel as described in the appended claims.

Brief description of the drawings

Additional characteristic features and advantages of this invention will emerge more clearly from the detailed description of various preferred, but not exclusive, embodiments of an integrated system for regulating and moving oxidizer and fuel illustrated in the accompanying drawings, in which:

Figure 1 is an axonometric view of the integrated system according to this invention;

Figure 2 is an axonometric view of the valve of the integrated system illustrated in Figure 1;

Figure 3a is a side view of the valve illustrated in Figure 2;

Figure 3b is a front cross-sectional view of the valve of Figure 3 along axis A-A;

Figure 4 is an axonometric view of a cross section of the valve of Figure 3 along axis A-A in a first stage of operation;

Figure 5 is an axonometric view of a cross section of the valve of Figure 3 along axis A-A in a second stage of operation;

Figure 6 is an axonometric view of a cross section of the valve of Figure 3 along axis A-A in a third stage of operation;

Figure 7 is an axonometric view of a cross section of the valve of Figure 3 along axis A-A in a fourth stage of operation;

Figure 8 is an axonometric view of a detail of the valve illustrated in Figures 4, 5, 6, 7.

Description of the preferred embodiments

With reference to the accompanying drawings, numeral 100 denotes in its entirety an integrated system 100 for regulating and mixing oxidizer and fuel for a burner according to the present invention.

More specifically, system 100 comprises a valve 1 for fuel that extends between a fluid inlet conduit 2 and a fluid outlet conduit 3 along a main path. This main path also defines the main direction of propagation of the fluid.

In more detail, inlet duct 2 has a relative end piece defined by an inlet passage 8. In addition, outlet duct 3 defines an outlet passage 80. In addition, system 100 comprises ventilation means 40 preferably defined by a fan. These ventilation means 40 comprise a first inlet 41 for the oxidizer, a second inlet 54 for the fuel and an outlet 55 connectable to the burner to supply the latter with the mixture of fuel and oxidizer. Preferably, outlet passage 80 surrounds first inlet 41 and second inlet 54.

Preferably, the first inlet 41 and the second inlet 54 are defined by a single opening made in the ventilation means 40. In other words, the oxidizer and fuel enter the ventilation means 40 through the single opening.

Additionally, the outlet passage of valve 1 is connected to the second inlet 54 (or to the single opening) for the fuel in such a way as to receive the fuel that passes through the valve 1.

As shown in Figure 1, valve 1 is mounted directly on the ventilation means 40 in such a way as to form a single body integrated with it.

Preferably, system 100 comprises removable connection means 56 positioned between ventilation means 40 and valve 1 to connect them together.

In detail, the removable connection means 56 comprise a perforated flange 57 formed on an outer wall of valve 1, corresponding holes 58 internally threaded and made in the ventilation means 40 and connecting elements 59 (preferably screws and / or bolts) partially threaded and each inserted through perforated flange 57 and threaded into a corresponding hole.

Preferably, the perforated flange 57 has elongated slotted holes in such a way as to facilitate the correct positioning of the valve 1 in the ventilation means 40 to fix independently of the type and / or profile of the latter.

It should be noted that valve 1 extends between a relative bottom wall 9 and a relative top wall 10 opposite the bottom piece along the axis of movement 12 described below.

Additionally, valve 1 comprises at least one valve phase which in turn comprises a plug 11 interposed between inlet passage 8 and outlet passage 80 and movable along a movement axis 12, between an open position , to allow the passage of fuel, and a closed position to block the passage of fuel.

In detail, valve 1 has an opening 6 interposed between inlet 8 and outlet 80. More specifically, plug 11 operates in opening 6 to allow or block the transit of fuel. In other words, the shutter 11 abuts against the opening 6 to close it during the closed position, and is spaced from the opening 6 during the open position.

More specifically, the opening 6 extends along a respective extension axis 12 substantially parallel to the axis of movement 12. For this reason, for the sake of simplicity, the extension axis has been labeled with the same reference as the axis of movement 12 (numeral 12). It should be noted that the extension axis 12 of the opening 6 is substantially transverse (preferably orthogonal) to the main part of the path with respect to the inlet duct 2. In this way, so that the gas passes from the inlet duct 2 through opening 6 should rotate through a right angle.

Valve 1 also comprises a unit 15 for moving shutter 11 functionally associated with shutter 11 to move it from the closed position to the open position.

In the preferred embodiment, the movement unit 15 is a rod 16 that extends between a respective operating zone 17 that can be coupled to the shutter 11 to move it and a respective driving zone 18 opposite to the operating zone 17.

It should be noted that the rod 16 is movable along the axis of movement 12 in a first direction 19 to move the shutter 11 from the closed position to the open position. The first direction 19 is preferably directed towards the ventilation means 40. More specifically, the operating area 17 of the rod 16 has a thrust end 20 oriented towards the shutter 11 and which can be bumped against it to push it from the closed position to the opening position.

More specifically, rod 16 is movable from an initial position, where it is spaced from shutter 11 along axis of motion 12 (and shutter 11 is in the closed position), to an interceptor position of shutter 11, where it is in contact with the shutter 11 (and the shutter is in the closed position), to an intermediate position where the shutter 11 is in the intermediate position.

In this way, the movement unit 15 pushes the shutter 11 from the closed position to the intermediate position.

In more detail, the plug 11 comprises a plate that extends at right angles to the axis of extension of the opening 6. Additionally, the plug 11 comprises an annular sealing gasket 14 positioned on the plate and oriented to the opening 6 and formed similar to the edge of the opening 6 in such a way as to close the passage during the closed position of the shutter 11.

Additionally, valve 1 comprises means 42 to drive rod 16 associated with drive zone 18 of rod 16. More specifically, means 42 to drive rod 16 are positioned in a service compartment 43 of valve 1 made in top wall 10.

It should be noted that the upper wall 10 delimits a valve body and the service compartment 43 is positioned outside the valve body. In an alternative embodiment not illustrated in the accompanying drawings, the service compartment 43 is within the valve body.

More specifically, the means 42 for driving the rod 16 are configurable between a rest condition, a first operating condition and a second operating condition. During the idle condition, the first shutter 11 is in the closed position and the push end 20 of the rod 16 is spaced from the shutter 11. During a first operating condition, the rod 16 moves along the direction movement 12 in the first direction 19 in such a way as to move the shutter 11 towards the upper wall 9 (to move it from the closed position to the intermediate position).

More specifically, the drive means 42 comprise an electromagnetic element 44 for moving rod 16 along the first direction 19 or along the second direction 21. The electromagnetic element 44 is inserted into the service compartment 43 and associated with the drive area 18 of the rod 16. In other words, the rod 16 passes through the bottom wall 910 and is partially inserted into the service compartment Still more specifically, the electromagnetic element 44 comprises a magnet 45 fixed in position with respect to the rod 16 and an electromagnetic circuit 46 connected to the drive zone 18 of the rod 16. In other words, the electromagnetic circuit 46 moves relative to the magnet 45 approaching or moving away from it. Preferably, the electromagnetic circuit 46 is movable (by moving the rod 16), depending on the direction of the electric current, from the idle condition to the first operating condition or to the second operating condition and vice versa.

Additionally, the electromagnetic circuit 46 comprises an electricity supply cable 47 that extends inside the service compartment 43 towards a hole put in communication between the service compartment 43 and the exterior of the valve 1 for connection to an electrical power source .

The power cable 47 is positioned between the top wall 10 and the rest of the electromagnetic circuit 46 and is wound in a spiral in such a way as to reduce interference with the rest of the electromagnet circuit 46 during the movement of the latter. Preferably, the electromagnetic circuit 46 is of the voice coil type.

Furthermore, the valve 1 comprises first elastic means 34 positioned between the shutter 11 and the lower wall 9 of the valve 1. The first elastic means 34 extend during the closed position of the shutter 11 and compress during the open position of the shutter. 11 in such a way as to facilitate the return of the shutter 11 from the open position to the closed position. Furthermore, the first elastic means 34 are advantageously configured to keep the shutter 11 abutting against the rod 16 during the passage from the closed position to the open position. Preferably, the first elastic means 34 are positioned in contact with the plug 11 in a suitable recess formed on the plug 11 and which faces the bottom wall 9 of valve 1.

In the preferred embodiment, the first elastic means 34 comprise a helical spring.

Furthermore, the valve phase comprises means 60 for holding in a functionally active position between a fixed area of valve 1 and shutter 11 and that can be configured between an activation condition during which they hold shutter 11 in an open position, and a deactivation position. During the activation condition, the holding-in-place means 60 is configured to act on the shutter 11 when the latter is in an intermediate position between the open position and the closed position.

In other words, while the movement unit 15 moves the shutter 11 from the open position to the intermediate position, the means 60 for holding in position act on the shutter when the latter is in the intermediate position to move it to the open position. in such a way as to keep the valve phase open.

Preferably, the means 60 for holding in position are of the magnetic type and define a magnetic field of attraction that extends from the open position to the intermediate position of the shutter 11.

In detail, the holding means 60 are positioned between a fixed area and the shutter 11 and are configurable between an active condition and an inactive condition.

The fixed area is preferably defined by the closing wall 9 of the valve 1 that delimits the valve 1 at the rear with respect to the plug 11.

Preferably, a first part 61 of the position holding means 60 is positioned on the closure wall 9 of the valve 1 while a second part 62 of the position holding means 60 is positioned on the shutter 11. The shutter 11 is movable from the intermediate position to the open position along an approach direction to the closing wall 9.

More specifically, the first part 61 of the position holding means 60 comprises a magnet 37. The second part 62 of the position holding means 60 incorporates the shutter. Additionally, the second part 62 of the position holding means 60 comprises a magnet and / or ferromagnetic material associated with the shutter 11. Preferably, the second part 62 of the position holding means 60 comprises the ferromagnetic material. This magnet 37 is positioned on the closure wall 9 and the ferromagnetic material is positioned on the shutter 11. As already mentioned, the ferromagnetic material could be incorporated in the shutter 11.

In this way, magnet 37 generates a magnetic field involving the ferromagnetic material present in shutter 11 to attract shutter 11 towards closure wall 9. In an alternative embodiment not illustrated in the accompanying drawings, magnet 37 could be positioned on the shutter 11 while the ferromagnetic material and / or the magnet could be positioned on the closure wall 9.

During the active condition the holding means 60 is configured to attract the shutter 11 towards the closing wall 9 when the shutter 11 is moving from the closed position to the open position and when the distance between the shutter 11 and the wall The closing 9 is less than the distance between the shutter 11, in the closed position, and the closing wall 9. In other words, the holding means 60 are configured to act on the shutter 11 only after the latter has started to move from the closed position to the open position. In even other words, the holding means 60 act when the distance between the shutter 11 and the closing wall 9 is less than a predetermined minimum distance. In effect, the holding means 60 are configured to generate a magnetic field that can move the shutter 11 only when the latter is at a distance from the closing wall 9 less than the distance between the shutter 11 during the rest position and the closing wall 9. The distance is the predetermined minimum distance mentioned above.

Advantageously, this configuration of the holding means 60 makes it possible to reduce the amount of energy required to fully move the shutter 11 from the closed position to the open position, because the generated magnetic field can only operate at distances of less than the distance default minimum (or at most equal to this).

In other words, the holding means 60 is configured to act on the shutter 11 when the latter is in an intermediate position located between the open position and the closed position. This intermediate position corresponds to the aforementioned predetermined minimum distance from the closing wall 9.

In still other words, the movement unit 15 of the shutter 11 is configured to bring the shutter 11 from the open position to the intermediate position. In this sense, the holding means 60 define a magnetic field of attraction that extends from the aperture to the intermediate position of the shutter 11. In other words, the magnetic field of extension extends to cover the intermediate position. More specifically, the magnetic field of attraction has a predetermined attractive force to the intermediate position and not to the shutter closed position.

In other words, the magnetic field of attraction cannot move the shutter 11 when the latter is positioned in the closed position. In this way, it is possible to generate a magnetic field (defined by the holding means 60) that has reduced intensity and, consequently, that has reduced energy waste.

In accordance with the invention, system 100 comprises a unit 63 for detecting oxidizer along first inlet 41 configured to detect the presence of oxidizer in transit along first inlet 41.

Alternatively, if the first inlet 41 is attached to the second inlet 54 through the single opening, as described above, the unit 63 for detecting the oxidizer is positioned in the single opening.

In addition, system 100 comprises means for activating means 60 for holding in position functionally connected to unit 63 to detect the oxidizer and configured to activate means 60 for holding in position when unit 63 for detecting oxidizer detects the presence of oxidizer in transit along the first entrance 41.

In this way, when the detection unit 63 detects the transit of the oxidizer the shutter 11 is kept in the open position (following the movement of the movement unit to move the shutter 11 from the closed position at least to the intermediate position ) whereas if the detection unit 63 does not detect the transit of the oxidizer the shutter 11 cannot be kept in the open position and returns to the closed position.

More specifically, detection unit 63 comprises any apparatus that can detect the passage of oxidizer into ventilation means 40. In the preferred embodiment illustrated in the accompanying drawings purely by way of example, detection unit 63 comprises an exposed rotor 64 to the oxidizer in transit along the first inlet 41 in such a way as to be moved by the passage of the oxidizer to detect the passage of the oxidizer. In more detail, rotor 64 (more clearly shown in figure 8) rotates about a relative axis of rotation under the action of the oxidizer moving towards the ventilation means 40.

Preferably system 100 comprises a communication compartment 65 shared between the first inlet 41, the second inlet 54 and the outlet passage and positioned between the valve 1 and the ventilation means 40. The detection unit 63 is positioned in the compartment Communication 65.

In addition, rotor 64 is located in proximity to plug 11. Preferably, rotor 64 is located on one side of closure wall 9 opposite the position of plug 11 outside valve 1.

Additionally, in the preferred embodiment, the means 60 for holding in place are of the magnetic type and the first part 61 and / or the second part 62 define the aforementioned magnetic field of attraction. More specifically, the first part 61 of the holding-in-place means 60 is associated with the shutter 11 while the second part 62 of the holding-in-place means 60 is incorporated into the rotor 64.

Advantageously, in this way an energy saving is guaranteed thanks to the fact that the holding means 60 are configured to keep the shutter 11 in the open position thanks to the presence of the magnetic attraction field (generated due to the passage of oxidizer) without additional waste of electricity (due, for example, to the feeding of an electromagnet as in traditional systems).

Furthermore, the second part 62 of the means for holding in place is positioned in a zone of the rotor 64 and the first part 61 of the means for holding in position is positioned in a shutter zone 11. In this way, the zone rotor 64 and shutter area 11 can be aligned or deviated from each other depending on the rotation of the rotor 64. Indeed, the first part 61 and / or the second part 62 of the means 60 for holding in position are offset, at least partially, with respect to the axis of movement 12 (in the case of the first part 61) or with respect to the axis of rotation (in the case of the second piece 62).

Preferably, the axis of rotation is aligned with the axis of movement 12 and is positioned as an extension thereof.

Rotor 64 is rotatable about the axis of rotation from a start position to an end position along a predetermined angular curve.

During the initial position, the second part 62 of the holding means 60 and the first part 61 of the holding means 60 move relative to the magnetic field of attraction in such a way as to deactivate the means 60 for holding in place. Indeed, the two pieces do not attract each other magnetically.

In other words, the first part 61 of the holding means 60 and / or the second part 62 of the holding means 60 moves relative to the magnetic field of attraction.

Preferably, the shutter 11 has at least one recess 66 that defines a spacing from the second part 62. Furthermore, the second part 62 is positioned in the recess 66 in such a way that the magnetic field made from the second part 62 does not influence the shutter 11. In other words, the distance between the second part 62 and the shutter 11 in the inner recess 66 is greater than a radius of action of the magnet within which the latter has a sufficient force of movement to attract the shutter 11.

On the other hand, during the final position, the second part 62 of the holding means 60 and the first part 61 of the holding means 60 align with the magnetic field of attraction in such a way as to activate the means 60 for holding in position. In effect, the two pieces attract each other magnetically.

In other words, the first part 61 of the holding means 60 and / or the second part 62 of the holding means 60 are positioned within the magnetic field of attraction.

The second part 62 does not align with the recess 66 and is aligned with the remaining part of the shutter 11 unaffected by the recess 66 such that the magnetic field made by the second part 62 influences the shutter 11. In other words, the distance between the second part 62 and the shutter 11 is less than a radius of action of the magnet within which the latter has a force of movement sufficient to attract the shutter 11.

As already mentioned, rotor 64 is configured to move from the initial position to the final position under the action of the oxidizer in transit along the first inlet 41. The system 100 comprises a return spring 72 operatively connected between the fixed area and rotor 64 and configured to return the latter from the final position to the initial position. Preferably, in the accompanying drawings it is possible to see that the second part 62 comprises two magnets aligned with two respective recesses 66 of the shutter.

Furthermore, system 100 comprises an additional inlet 67 for the oxidizer positioned in fluid communication with the ventilation means 40 and a separating baffle 68 movable along a movement axis between a rest position in which the additional inlet closes. 67 for the oxidizer and an operating position where it opens the additional entry 67 for the oxidizer.

More specifically, the separator baffle 68 is directly exposed to the flow of oxidizer that passes along the first inlet 41 in such a way as to move from the rest position to the operating position according to the increase or decrease in the flow rate of the oxidizer acting on the separator baffle 68. In other words, the separator baffle 68 is movable from the rest position to the operating position when the flow rate of the oxidizer exceeds a predetermined flow rate value.

Alternatively, since the unit 63 for detecting the oxidizer is configured to measure the flow rate of the oxidizer along the first inlet 41, the separator baffle 68 is connected to the detection unit 63 and is movable from the rest position to the operating position with the increase in the flow rate of the oxidizer measured by the detection unit 63.

Furthermore, the system 100 comprises elastic return means 69 interposed between the separator baffle 68 and a fixed area of the integrated system 100 for the return of the separator baffle 68 from the operating position to the rest position. Preferably, the fixed area of the integrated system 100 is oriented to one side of the spacer baffle 68 opposite the support means 60.

The elastic return means 69 also defines a partial contrast force against the force exerted by the oxidizer on the spacer baffle 68.

Preferably, the elastic return means 69 is of variable resistance type in such a way as to increase the degree of resistance during movement of the spacer baffle 68 from the rest position to the operating position.

Advantageously, the separator baffle 68 makes it possible to increase the supply of oxidizer to the ventilation means 40 as a function of the flow rate of the oxidizer.

As shown in the accompanying drawings, the spacer baffle 68 occupies the entire cross section of the first inlet 41. Accordingly, the spacer baffle 68 has a through hole 70 for transit of the oxidizer to the ventilation means 40. Preferably, the rotor 64 comprises a central body 71 positioned on the axis of rotation partially inserted in the through hole 70 during the rest position of the spacer baffle 68. In this way, the through hole 70 is restricted by the presence of the central body 71 of the rotor 64. In other words, the central body 71 of the rotor 64 positioned within the through hole 70 defines a neck for the oxidizer in transit.

If the first inlet 41 and the second inlet 54 are joined in the single opening, the through hole 70 defines a passage for the transit of the fuel and for the oxidizer. In that case, the spacer baffle 68 is positioned in the single inlet opening.

Additionally, the additional inlet 67 is combined in the single inlet opening made in the ventilation means 40.

Preferably, as shown in the accompanying drawings, the axis of movement 12, the axis of rotation, and the axis of movement are aligned along a common direction.

Relative to the ventilation means 40, these comprise an axial extraction fan at the first inlet 41 and the second inlet 54 and a radial extraction fan at the outlet.

Additionally, it should be noted that in the attached drawings valve 1 comprises an additional phase located downstream of opening 6. In this sense, valve 1 has an additional opening 7 located downstream of opening 6, according to the main path, and extending along a respective extension axis 52 positioned transversely to the extension axis 12 of the opening 6. Preferably, the extension axis 52 of the additional opening 7 is positioned at right angles to the extension axis 12 of the opening 6.

In this way, once the gas has passed through the opening 6 it must rotate through approximately a right angle to leave from the additional opening 7. More specifically, the additional phase comprises an intermediate chamber 5 interposed between the two phases and forming a communication space. More specifically, the intermediate chamber 5 is positioned between the opening 6 and the additional opening 7.

It should also be noted that the intermediate chamber 5 extends away from the opening 6 to the upper wall 10 that delimits the intermediate chamber 5.

Additionally, valve 1 comprises an additional plug 13 operatively associated with the additional opening 7 and movable between a closed position and an opening position of the additional opening 7 along the direction of movement 12 transverse to the main path. Preferably, the additional shutter 13 is positioned above the opening 6 along the extension axis 53. In contrast, the shutter 11 is positioned below the opening 6 along the extension axis 53.

More specifically, the shutter 11 and the additional shutter 13 overlap each other along the direction of movement 12. In other words, the shutter 11 moves in the end region 8 of the inlet duct 2, while the additional shutter 13 moves it moves inside the intermediate chamber 5. In any case, the additional shutter 13 is movable along the direction of movement 12. In other words, the additional shutter 13 moves along the same direction of movement 12 of the shutter 11. In even other words, the shutter 11 and the additional shutter 13 move coaxially even independently relative to the direction of movement (as will be explained in more detail below).

As already mentioned, the rod 16 is movable along the direction of movement 12 according to a second direction 21 opposite to the first direction to move the additional shutter 13 from the closed position to the open position in such a way that the movement of a shutter 11 is independent of the movement of the other shutter 13. In other words, the movement of the shutter 11 is independent of the movement of the additional shutter 13. Indeed, this independence of movements is given by the fact that to move A shutter 11 requires rod 16 to move in a direction opposite to movement for additional shutter 13. Thus, it should also be noted that the time that shutter 11 remains in the closed position is independent of the time that the additional shutter 13 in the closed position.

In more detail, the rod 16 is inserted through a through hole 22 present in the additional shutter 13. In other words, the rod 16 passes through the additional shutter 13. It should be noted that the through hole 22 of the additional shutter 13 has wider than the respective width of the rod 16 (measured perpendicular to the direction of movement 12) in such a way as to leave a clearance 33 between the additional plug 13 and the rod 16 for the passage of the fluid when the plug 11 is open and the additional shutter 13 is closed. Furthermore, the clearance 33 allows the rod 16 to slide relative to the additional shutter 13 such that the rod 16 can be moved independently of the movement of the additional shutter 13.

Furthermore, the movement unit 15 comprises pulling means 23 fixed to the operating area 17 of the rod 16 to pull the additional shutter 13 from the closed position to the open position. In more detail, the traction means 23 comprise a stop fixed to the operating area 17 of the rod 16 and projecting laterally thereto. More specifically, the stop protrudes laterally a length greater than the space between the additional shutter 13 and the rod 16 in a direction perpendicular to the direction of movement 12 in such a way as to pull the additional shutter 13 during the movement of the rod 16 according to the second direction 21. Preferably, the stop is a washer attached to rod 16 in a suitable seat. Alternatively, the stop can be defined by a suitable protrusion formed on the profile of the rod 16. In addition, the valve 1 comprises first sealing means 24 and second sealing means 25 positioned between the additional plug 13 and the additional opening 7. The second sealing means 25 are spaced from the first sealing means 24 along a direction away from the first sealing means 24.

It should be noted that the intermediate chamber 5 has a widening in the additional opening 7. In other words, at the height of the additional opening 7, according to the direction of movement 12, there is the widening.

More specifically, the widening of the intermediate chamber 5 defines a space for disconnection of the additional shutter 13 placed in fluid communication with the additional opening 7.

It should be noted that the intermediate chamber 5 has a first passage 27 defined between the additional opening 7 and the disconnection space and a second passage 28 defined between the upper wall 10 and the disconnection space. Consequently, the first sealing means 24 operate on the first passage 27, while the second sealing means 25 operate on the second passage 28 in such a way that the gas does not pass (during the closing position of the additional shutter 13) to the disconnect space.

Furthermore, the second sealing means 25 comprise a first part 29 connected to the intermediate chamber 5 and a second part 30 connected to the additional shutter 13. The first and second parts 30 of the second sealing means 25 have an annular extension around the shutter additional 13.

It should be noted that the second step 28 is defined between the intermediate chamber 5 and the additional shutter 13 in the second sealing means 25.

In the preferred embodiment illustrated in the accompanying drawings, the first part 29 and the second 30 of the second sealing means 25 comprise a single body and are connected together by a flexible U-shaped area. Furthermore, in this preferred embodiment, the first sealing means 24 and second part 30 of second sealing means 25 comprise separate bodies.

Furthermore, the intermediate chamber 5 comprises a transitory space 32 that extends away from the first sealing means 24 and from the shutter 11. The transitory space 32 is in fluid communication, during the closing position of the additional shutter 13, with the remainder of intermediate chamber 5 through clearance 33. More specifically, transient space 32 extends from top wall 10 to second passage 28.

In this way, after the shutter 11 is opened, the gas flows through the clearance 33 in such a way as not to exert pressure on the additional shutter 13 along the second direction 21. In other words, the thrust of the gas it is dispersed through the gap 33 and by the passage of the gas in the transitory space 32.

Furthermore, the valve 1 comprises second elastic means 38 positioned between the additional shutter 13 and the upper wall 10 of the intermediate chamber 5. The second elastic means 38 extend during the closed position of the additional shutter 13 and compress during the stop position. opening the additional shutter 13 in such a way as to facilitate the return of the additional shutter 13 from the open position to the closed position. Furthermore, the second elastic means 38 are designed to keep the additional shutter 13 in the closed position. It should be noted that the second elastic means 38 extend within the intermediate chamber 5 and, in detail, in an interior cavity 39 of the additional shutter 13. Indeed, the additional shutter 13 is substantially U-shaped where the opening in this way The U-shape is directed towards the upper wall 10. The shape of the additional plug 13 forms the interior cavity 39 in which the second elastic means 38 are at least partially positioned. In other words, the second elastic means 38 extend along the direction of movement 12. More in detail, the second elastic means 38 are positioned around the rod 16. Preferably, the second elastic means 38 comprise a coil spring inside the rod 16 passes through. Thus, the spring also extends into the inner cavity 39 of the additional plug 13.

Furthermore, it should be noted that both embodiments of the valve 1 comprise third elastic means 49 positioned between a wide area of the rod 16 positioned in the inner cavity 39 and a contact surface of the additional plug 13 that delimits the inner cavity 39 along the direction of movement 12 according to the first direction 19. The wide area of the rod 16 defines a stage for retaining the third elastic means 49 in such a way as to lock them in position. Advantageously, the third elastic means 49 allow the pushing means 23 to be kept in contact with the additional shutter 13 during the closed position.

In relation to the operation of this invention, it can be derived directly from the previous description.

More specifically, the unit 63 for detecting the transit of the oxidizer activates the means 60 for holding in position to keep the shutter 11 in the open position when there is passage of the oxidizer (Figure 5).

In the particular embodiment illustrated in the accompanying drawings where the detection unit 63 comprises a rotor 64, the transit of the oxidizer moves the rotor 64 so that, thanks to the movement of the latter, the system 100 understands that it is possible to keep the shutter open 11 to supply fuel.

In this way, in the absence of transit of oxidizer towards the ventilation means 40, the rotor 64 stops deactivating (preferably returns to its initial position) the means 60 for holding it in place. In this way, the shutter 11 may not remain locked in the open position and returns to the closed position stopping the flow of fuel and thus putting system 100 in a safe condition (Figure 4).

Furthermore, during operation of the system 100 with oxidizer transit and with the shutter 11 in the open position, it is possible to open an additional air passage by moving the separator baffle 68 that is sensitive to the flow rate of the oxidizer (Figure 7). In practice, the separator baffle 68, under the action of the pressure of the oxidizer, moves to open the additional air passage. In this way, when the flow rate of oxidizer increases beyond a certain limit, system 100 allows to increase the supply of oxidizer.

Finally, the opening of the additional valve phase (figure 6) ensures the specified safety in relation to valves that handle combustible fluids.

More specifically, the opening of valve 1 comprises an opening of the first phase and an opening of the additional phase.

In order to open the first phase it is necessary to move the rod 16 along the first direction 19 using a command suitable to the electromagnetic circuit 46 in such a way as to move the shutter 11 from the closed position to the open position. During this movement (or before) the magnetic attraction means 36 are activated (thanks to the movement of the rotor 64) in such a way as to complete the movement of the shutter 11 from the closed position to the open position. More specifically, the magnetic attraction means 36 attracts the shutter 11 towards the closing wall 9 in such a way as to definitively open the first phase. In other words, the movement of the shutter 11 occurs at two successive points in time: during a first instant, the rod 16 moves the shutter 11 close to the closing wall 9; during a second instant, the magnetic attraction means 36 complete the movement of the shutter 11 towards the closing wall 9.

After the shutter 11 is opened, the magnetic attraction means 36 is kept active in such a way that the shutter 11 remains in the open position. During the opening movement of the shutter 11, the first elastic means 34 are compressed while the second elastic means 38 keep the shutter 13 in the closed position.

Once the plug 11 is opened, the gas enters through the opening 6 into the intermediate chamber 5 and penetrates the clearance 33 reaching the transient space 32. However, until the additional plug 13 is opened, the gas is locked inside of the intermediate chamber 5 (and in the transient space 32) thanks to the presence of the first sealing means 24 and the second sealing means 25.

The rod 16 is then moved from the first operating condition to the second operating condition, in the second direction 21. In this way, the pulling means 23 associated with the operating area 17 of the rod 16 move the additional shutter 13 from the closed position to the open position generating a passage for the gas from the clearance to the outlet duct 3. During this movement, the second elastic means 38 are compressed. After the additional plug 13 is opened, gas can pass through valve 1.

The present invention achieves the stated intentions.

More specifically, this system makes it possible to increase the level of safety in situations in which there is not sufficient flow of oxidizer since the means to hold in position at least one of the valve phases are deactivated in the absence of passage of the oxidizer. Consequently, if the ventilation means are blocked or the inlet for the oxidizer is obstructed, valve 1 closes automatically.

Additionally, when the shutter is in the open position, the hold-in-place means holds it in that position only with the transit of oxidizer toward the ventilation means.

Furthermore, when the flow rate of oxidizer increases beyond a certain limit, the system allows to increase the supply of oxidizer by moving a separator baffle that allows opening an additional opening passage.

It should also be noted that this invention is relatively easy to implement and that the cost of implementing the invention is relatively low.

Claims (15)

1. An integrated system (100) for regulating and mixing oxidizer and fuel for a burner, comprising: a valve (1) for the fuel comprising an inlet passage (8) and an outlet passage (80) for the fuel; ventilation means (40) comprising a first inlet (41) for the oxidizer, a second inlet (54) for the fuel and an outlet connectable to the burner; the second inlet (54) for the fuel is connected to the outlet passage of the valve (1) to receive the fuel that passes through the valve (1): the valve (1) comprises a valve phase comprising a shutter (11) interposed between the inlet passage (8) and the outlet passage (80) and movable along a movement axis (12), between a open position, to allow the passage of fuel, and a closed position to block the passage of fuel; the valve (1) also comprises a unit (15) to move the shutter (11) functionally associated with the shutter (11) to move it from the closed position to the open position; characterized in that the valve phase comprises means (60) for holding functionally active positions between a fixed area (9) of the valve (1) and the plug (11) and that can be configured between an activation condition during which they hold the shutter (11) in an open position, and a deactivated position; during the activation condition, the means (60) for holding in position are configured to act on the shutter (11) when the latter is in an intermediate position between the open position and the closed position; the unit (15) for moving the shutter (11) is configured to move the shutter (11) from the open position to the intermediate position; and characterized in that it comprises a unit (63) for detecting oxidizer along the first inlet (41) configured to detect the presence of oxidizer in transit along the first inlet (41); the system (100) comprises means for activating the means (60) for holding in position functionally connected to the unit (63) to detect the oxidizer and configured to activate the means (60) for holding in position when the unit (63) stops detecting oxidizer detects the presence of oxidizer in transit along the first inlet (41). The system (100) according to claim 1, characterized in that the means (60) for holding in position are of the magnetic type and define a magnetic field of attraction that extends from the open position to the intermediate position of the shutter ( eleven). The system (100) according to claim 2, characterized in that a first part (61) of the means (60) for holding in position is positioned on the shutter (11) while a second part (62) of the means (60) to hold it in position it is positioned on a closing wall (9) of the valve (1) spaced from the plug (11); the shutter (11) is movable from the intermediate position to the open position along an approach direction to the closing wall (9). The system (100) according to claim 2 or 3, characterized in that the first part (61) of the means (60) for holding in position comprises a magnet (37); the second part (62) of the means (60) for holding it in place comprises a magnet and / or ferromagnetic material associated with the shutter (11). The system (100) according to any one of the preceding claims, characterized in that the unit (63) for detecting oxidizer comprises a rotor (64) exposed to the oxidizer in transit along the first inlet (41) in such a way as to be moved by the passage of the oxidizer to detect the passage of the oxidizer. The system (100) according to claim 5, characterized in that it comprises a communication compartment (65) shared between the first entrance (41), the second entrance (54) and the exit passage. 7. The system (100) according to claim 6, characterized in that the detection unit (63) is positioned in the communication compartment (65). The system (100) according to any one of claims 5 to 7 when it depends on claim 2, characterized in that a first part (61) of the means (60) for holding in position is positioned on the shutter (11) while a second piece (62) of the means (60) for holding it in place is incorporated in the rotor (64); the first piece (61) and / or the second piece (62) define the magnetic attraction field. 9. The system (100) according to claim 8, characterized in that the second part (62) of the means (60) for holding in position is positioned in an area of the rotor (64) and the first part (61) of the means (60) for holding it in position is positioned in an area of the shutter (11); the rotor (64) is rotary about an axis of rotation that passes through the axis of movement (12) from a starting position to an ending position along a predetermined angular curve; During the initial position, the second part (62) of the holding means (60) or the first part (61) of the holding means (60) are positioned outside at least part of the magnetic field of attraction in such a way as to deactivate the means (60) for holding in position; during position Finally, the second part (62) of the holding means (60) and the first part (61) of the holding means (60) are positioned within at least part of the magnetic field of attraction in such a way as to activate the means (60) for holding in position. The system (100) according to claim 9, characterized in that the rotor (64) is configured to move from the initial position to the final position under the action of the oxidizer in transit along the first inlet (41); the system (100) comprises a return spring (72) operatively connected to the rotor (64) and configured to return the latter from the final position to the initial position. The system (100) according to any one of the preceding claims, characterized in that the first inlet (41) and the second inlet (54) are combined in a single inlet opening made in the ventilation means (40). 12. The system (100) according to any one of the preceding claims, characterized in that it comprises an additional inlet (67) for the oxidizer positioned in fluid communication with the ventilation means (40) and a separating deflector (68) movable to along an axis of travel between a rest position in which the additional inlet (67) for the oxidizer closes and an operating position in which it opens the additional inlet (67) for the oxidizer. 13. The system (100) according to claim 12, characterized in that the separator baffle (68) is directly exposed to the flow of oxidizer that passes along the first inlet (41) in such a way as to move from the position of rest to the operating position according to the increase or decrease in the flow rate of the oxidizer acting on the separator baffle (68). 14. The system (100) according to claim 13, characterized in that it comprises elastic return means (69) associated with the separator baffle (68) for the return of the latter from the operating position to the rest position; the elastic return means (69) define a partial contrast force against the force exerted by the oxidizer on the separating baffle (68). 15. The system (100) according to any one of claims 12 to 14, characterized in that the spacer baffle (68) occupies the entire cross section of the first inlet (41); the separating baffle (68) has a through hole (70) for the transit of the oxidizer towards the ventilation means (40).