EP4184059A1 - Fuel boiler with pressure reduction device for flame ignition - Google Patents

Abstract

The invention relates to a fuel boiler (1) comprising:- a supply circuit (30) for a mixture of oxidizer and fuel, said supply circuit for a mixture comprising a drive device (20) mixture through the mixture supply circuit;- a burner (6) in fluid communication with the mixture supply circuit (30), the burner (6) comprising an ignition device (10) configured to ignite the mixture of oxidizer and fuel;- a combustion chamber (2) receiving the burner (6), characterized in that the supply circuit (30) of a mixture comprises a pressure reduction device ( 38) upstream of the burner, said pressure reduction device being selectively activatable.

Description

The present invention relates to a fuel-fired boiler and to a method for lighting such a boiler.

Known from the state of the art is a fuel boiler, in particular a gas boiler, comprising a hearth. This fireplace contains a burner designed to burn a gaseous premix.

The gaseous premix is produced by a mixer fed by an air supply conduit forming the oxidizer and by a gas supply conduit forming the fuel. A gas premix feed pipe fluidically connects the mixer to the burner. A fan arranged at the junction of the air, gas and premix supply ducts makes it possible to move the premix towards the burner.

The gas boiler conventionally comprises a pneumatic valve arranged to regulate the flow of gas circulating in the gas supply conduit. This pneumatic valve is equipped with a shutter housed inside the gas supply pipe and a pneumatic servo-regulator converting a supply pressure into a movement of the shutter.

The servo-regulator is supplied with a supply pressure such that the gaseous premix permanently has an excess of air of the order of 30%. Under these conditions, the quantity of polluting gases, such as nitrogen oxides or carbon oxides, produced by the combustion of the gaseous premix is minimized.

Such excess air in the premix gas poses a problem when igniting the premix gas. Indeed, this air/gas mixture may prove difficult to ignite under these conditions.

The ignition of the gaseous premix is not carried out with certainty and generally results in a phenomenon of chattering or momentary pumping generating acoustic discomfort for the user and possibly causing a safety of the boiler due to the absence of flame at the end of the ignition sequence. In addition, poor ignition of the premix can generate high transient concentrations of pollutants (NOx, CO, CO2, etc.) which can be very dangerous.

The phenomenon of “chattering” is characterized by combustion instability corresponding to an excitation of a natural mode of the boiler leading to a sequence of extinction and re-ignition of the flame (between 10 and 30Hz).

The “pumping” phenomenon is characterized as follows. During ignition, a rapid variation in pressure in the hearth of the boiler occurs due to the variation in flame surface and therefore in the energy released by this flame. The pressure wave thus generated rises in the mixer as well as in the gas and air supply lines. This pressure wave disrupts the normal operation of the various components of the boiler, in particular of the fan and of the pneumatic valve arranged in the gas supply line. The ratio between the quantity of air and the quantity of gas, in other words the richness or the excess of air in the mixture, is thus disturbed by this pressure wave which can cause a phenomenon of total or partial extinction of the flame. This pumping phenomenon can be occasional or repetitive.

These "pumping" and "chattering" phenomena are incompatible with the normative requirements and the expected quality of the boiler.

There is therefore a need for a fuel-fired boiler making it possible to improve the ignition phase of the flame, in particular by reducing the phenomena of surging and chattering on ignition.

• un circuit d'alimentation d'un mélange de comburant et de combustible, ledit circuit d'alimentation d'un mélange comprenant un dispositif d'entraînement du mélange au travers du circuit d'alimentation du mélange ;
• un brûleur en communication de fluide avec le circuit d'alimentation d'un mélange, le brûleur comprenant un dispositif d'allumage configuré pour allumer le mélange de comburant et de combustible ;
• une chambre de combustion recevant le brûleur,

dans lequel le circuit d'alimentation d'un mélange comprend un dispositif de diminution de pression en amont du brûleur, ledit dispositif de diminution de pression étant sélectivement activable.For this, the invention proposes a fuel boiler comprising:

• a circuit for supplying a mixture of oxidant and fuel, said circuit for supplying a mixture comprising a device for driving the mixture through the circuit for supplying the mixture;
• a burner in fluid communication with the mixture supply circuit, the burner comprising an ignition device configured to ignite the mixture of oxidizer and fuel;
• a combustion chamber receiving the burner,

wherein the mixture supply circuit comprises a pressure reduction device upstream of the burner, said pressure reduction device being selectively activatable.

The pressure reduction device makes it possible to generate a pressure reduction upstream of the burner. In other words, the pressure reduction device is configured such that its activation causes a pressure reduction in comparison with a pressure value in a deactivated state of the pressure reduction device. When this pressure reduction device is activated when the flame is ignited, this pressure reduction is such as to dampen the effect of the pressure waves generated by the ignition of the flame. Thus, the ignition of the flame is made more stable which allows the mixture to maintain its ratio. Therefore, the pressure upstream of the burner is higher when the pressure reduction device is deactivated compared to the pressure upstream of the burner when it is activated. The pressure reduction device thus makes it possible to limit or even eliminate the “pumping” phenomenon.

It has also been observed that the pressure reduction device makes it possible to limit or even eliminate the “chattering” phenomenon. It is very likely that this is due to the modification of the natural mode of the boiler when the pressure reduction device is activated, which is thus no longer energized during ignition.

The pressure reduction device therefore makes it possible to limit, or even eliminate, the phenomena of “pumping” and “chattering” in the activated state, without causing a drop in pressure in the deactivated state of the pressure reduction device. Thus, the operation of the boiler is not penalized when the pressure reduction device is deactivated.

The activation of the pressure reduction device is preferably carried out upstream of the ignition of the flame. For this, the activation is programmed to occur during or before a start-up phase of the fan preceding the ignition of the flame. The activation of the pressure reduction device upstream of the ignition of the flame also allows to anticipate any instability due for example to the activation of the pressure reduction device and to ensure the good quality of the mixture for ignition. Alternatively, the activation can be carried out simultaneously with the ignition of the flame.

The activation of the pressure reduction device is preferably maintained for a predetermined time after ignition of the flame in order to ensure that the flame ignition process is stable. Even more preferably, the power of the boiler is reduced after the ignition phase of the flame. This predetermined time is determined in particular so as to deactivate the device for reducing the pressure after the ignition of the flame when the power of the boiler is lower. The main interest of this technique is to be able to go down to a very low charge rate so that the deactivation of the device is smoother and therefore more stable. This predetermined time can be a few seconds, for example less than 10 seconds. Preferably, this predetermined time is greater than 10 seconds, for example between 10 and 50 seconds.

The pressure reduction generated by the pressure reduction device can be generated by an active member, for example a compressor, or else by a passive member, such as a member inducing a pressure drop.

The term "selectively activatable" means that the pressure reduction device can be controlled to reduce the pressure upstream of the burner. The control can for example be carried out remotely by a controller of the boiler. The activation of an active member corresponds to the starting of the member, for example of the compressor to generate the pressure reduction. The activation of a passive member corresponds to the positioning of the passive member so as to induce the pressure drop, for example by placing an obstacle in a pipe or by modifying the orientation of an obstacle in said pipe. .

According to one embodiment of the fuel boiler, the pressure reduction device comprises a pressure drop device capable of generating a pressure drop of a fluid passing through said pressure drop device when said pressure reduction device is activated.

• par un fluide à une première valeur de pression lorsque ledit dispositif de diminution de pression est désactivé,
• par un fluide à une deuxième valeur de pression inférieure à la première valeur de pression lorsque ledit dispositif de diminution de pression est activé.

According to one embodiment of the fuel boiler, the pressure reduction device defines a first fluid circulation zone and a second fluid circulation zone, said pressure drop member being arranged in the second circulation zone so that the burner is powered:

• by a fluid at a first pressure value when said pressure reduction device is deactivated,
• by a fluid at a second pressure value lower than the first pressure value when said pressure reduction device is activated.

According to one embodiment of the fuel boiler, said pressure reduction device comprises a directional member configured to direct the fluid supplying the pressure reduction device towards the second circulation zone in order to supply the burner with a fluid at the second pressure when said pressure reducing device is activated.

According to one embodiment of the fuel boiler, the pressure reduction device comprises a first circulation pipe forming said first circulation zone and a second circulation pipe forming said second circulation zone, the first and second circulation pipes being distinct from each other.

According to one embodiment of the fuel boiler, the pressure reduction device comprises a circulation pipe forming the first and second circulation zones.

• une position d'ouverture permettant au fluide de circuler au travers de la section de passage, ladite section de passage formant la première zone de circulation, et
• une position de fermeture dans laquelle la section de passage est au moins partiellement fermée permettant au fluide de circuler au travers d'un orifice formant la deuxième zone de circulation.

According to one embodiment of the fuel-fired boiler, the directional member comprises a closing wall of a passage section of the circulation pipe, said closing wall being movable between:

• an open position allowing the fluid to circulate through the passage section, said passage section forming the first circulation zone, and
• a closed position in which the passage section is at least partially closed allowing the fluid to circulate through an orifice forming the second circulation zone.

According to one embodiment of the fuel boiler, said orifice forming the second circulation zone is through the closing wall.

According to one embodiment of the fuel boiler, the pressure drop member comprises an activatable holding member to hold the closure wall in the closed position, the closure wall being configured to be maintained in the position opening under the action of the fluid flowing through the passage section.

According to one embodiment of the fuel boiler, the directional member is one of a solenoid valve, a damper, a pivot valve, a motorized valve, a sliding valve and a shutter.

According to one embodiment of the fuel boiler, the circuit for supplying a mixture comprises an oxidant supply circuit, a fuel supply circuit and a circuit for mixing the oxidant and the fuel in fluid communication , at a first end, with the oxidant and fuel feed circuits, and, at a second end, with the burner.

According to one embodiment of the fuel boiler, the pressure reduction device is arranged in the oxidant supply circuit. This makes it easier to manage the tightness of the pressure reduction device because the tightness requirement for the oxidizer is lower than for the fuel, which can prove to be dangerous. In addition, it is thus possible to arrange electrical components at the level of the pressure reduction device without any particular precaution, whereas it is preferable to avoid, or difficult, to implement such components in contact with a fuel. Furthermore, the oxidizer supply circuit is generally more accessible, which facilitates installation and maintenance of the pressure reduction device.

Alternatively, the pressure reduction device can be arranged at the level of the circuit for mixing the oxidizer and the fuel, for example downstream of the fan. Still alternatively, the pressure reduction device can be arranged in the fuel supply circuit.

• générer une circulation d'un mélange de combustible et de comburant à l'intérieur du circuit d'alimentation de mélange à l'aide du dispositif d'entrainement,
• activer le dispositif de diminution de pression de manière à générer une diminution de la pression du mélange en amont du brûleur,
• allumer le mélange de comburant et de combustible à l'aide du dispositif d'allumage.

The invention also proposes a method for lighting a fuel boiler, comprising the following steps:

• generate a circulation of a mixture of fuel and oxidizer at inside the mixing feed circuit using the driving device,
• activate the pressure reduction device so as to generate a reduction in the pressure of the mixture upstream of the burner,
• ignite the mixture of oxidizer and fuel using the ignition device.

According to an embodiment of the ignition method, in which the pressure reduction device is activated before or during the ignition of the mixture of oxidant and fuel.

According to one embodiment of the ignition method, the latter further comprises the deactivation of the pressure reduction device after the ignition of the mixture of oxidant and fuel.

According to one embodiment of the ignition method, the step of activating the pressure reduction device comprises moving the closure wall into the closed position so as to direct the fluid flowing through the pressure reduction device of pressure through the orifice forming the second circulation zone.

Brief description of the drawings

• [Fig. 1] représente schématiquement une vue d'ensemble d'une chaudière comprenant un circuit d'alimentation d'un mélange de comburant et de combustible et d'un foyer alimenté par ce mélange.
• [Fig. 2] représente un diagramme illustrant un procédé d'allumage d'une flamme dans le foyer de la chaudière, ce procédé comprenant une étape d'activation d'un dispositif de diminution de pression.
• [Fig. 3] représente schématiquement un premier mode de réalisation de l'organe de diminution de pression dans un état activé.
• [Fig. 4] représente schématiquement le premier mode de réalisation de l'organe de diminution de pression dans un état désactivé représenté en figure 3.
• [Fig. 5] représente un deuxième mode de réalisation de l'organe de diminution de pression dans lequel un orifice formant un organe de perte de charge est formé sur une paroi d'obturation déplaçable entre des positions de fermeture et d'ouverture de la section de passage de la conduite de circulation.
• [Fig. 6] représente le deuxième mode de réalisation de l'organe de diminution de pression représenté en figure 5 dans lequel l'orifice formant un organe de perte de charge est formé sur une paroi différente de la paroi d'obturation.

The accompanying drawings illustrate the invention:

• [ Fig. 1 ] schematically represents an overall view of a boiler comprising a circuit for supplying a mixture of oxidizer and fuel and of a hearth fed by this mixture.
• [ Fig. 2 ] represents a diagram illustrating a method of lighting a flame in the hearth of the boiler, this method comprising a step of activating a pressure reduction device.
• [ Fig. 3 ] schematically represents a first embodiment of the pressure reduction member in an activated state.
• [ Fig. 4 ] schematically represents the first embodiment of the pressure reduction member in a deactivated state represented in picture 3 .
• [ Fig. 5 ] represents a second embodiment of the pressure reduction member in which an orifice forming a pressure drop member is formed on a movable closure wall between closed and open positions of the passage section of the circulation pipe.
• [ Fig. 6 ] represents the second embodiment of the pressure reduction member shown in figure 5 wherein the orifice forming a pressure drop member is formed on a different wall from the closure wall.

Description of embodiment(s)

The inventive concept is described more fully below with reference to the accompanying drawings, in which embodiments of the inventive concept are shown. In the drawings, the size and relative sizes of the elements may be exaggerated for purposes of clarity. Like numbers refer to like elements throughout the drawings. However, this concept of the invention can be implemented in many different forms and should not be construed as being limited to the embodiments set forth herein. Instead, these embodiments are provided so that this description is complete, and communicates the scope of the inventive concept to those skilled in the art.

Reference throughout the specification to "an embodiment" means that a particular feature, structure, or feature described in connection with an embodiment is included in at least one embodiment of the present invention. Thus, the appearance of the phrase "in one embodiment" at various places throughout the specification does not necessarily refer to the same embodiment. Further, the particular functionalities, structures, or features may be combined in any suitable manner in one or more embodiments. Further, the term "comprising" does not exclude other elements or steps.

The present invention is illustrated with the aid of the figures which show an example of a fuel boiler, here gas. More generally, the boiler can relate to any type of fuel such as, for example, fuel oil, natural gas, hydrogen (H ₂ ) or even propane (LPG).

There figure 1 represents a fuel boiler 1 comprising a hearth 2, or a combustion chamber. Hearth 2 contains a heat exchanger 4 connected to a heating network (not shown).

The hearth 2 contains a burner 6. This burner 6 is equipped with a ramp 8 adapted to diffuse a gaseous premix inside the hearth 2. The burner 6 is equipped with an ignition electrode 10, or ignition device. ignition, suitable for igniting the gaseous premix. The burner 6 is finally equipped with an ionization electrode 12 adapted to detect a flame produced by the combustion of the gaseous premix. Alternatively, the burner 6 can be equipped with any means making it possible to detect a flame produced by the combustion of the gaseous premix. This means is for example an optical sensor, an oxygen sensor or even a temperature sensor.

Boiler 1 further comprises a circuit 30 for supplying a mixture of oxidant and fuel. The oxidant is preferably air, either taken from the ambient air around the boiler 1 or else coming from a specific air supply line. The fuel can be one of natural gas, propane (LPG), hydrogen (H ₂ ) or fuel oil.

The supply circuit 30 comprises an oxidizer supply circuit 32, a fuel supply circuit 34 and a circuit 36 for mixing the oxidizer and the fuel. The mixing circuit 36 is in fluid communication, at a first end, with the oxidizer 32 and fuel 34 supply circuits, and, at a second end, with the burner 6.

The mixing circuit 36 includes a mixer 16 and a gas premix supply conduit 14 fluidly connecting the burner 6 to the mixer 16. This mixer 16 is supplied by an air supply pipe 18 of the oxidant supply circuit 32 and by a gas supply pipe 21 from the fuel supply circuit 34. The gas supply pipe 21 can be fluidically connected to a gas distribution network or to a cylinder (not shown).

The supply circuit 30 comprises a device for driving the mixture through the supply circuit 30, here the fan 20. The fan 20 is placed in the mixing circuit 36 in the example illustrated. So In general, the fan 20 can be placed either in the combustion supply circuit 32 or the mixing circuit 36. The fan 20 makes it possible on the one hand to suck air and fuel into the duct 14 and to on the other hand to drive the gaseous premix from the mixer 16 to the burner 6. The fan 20 also makes it possible to generate a sufficient vacuum at the level of the mixer 16 to drive the fuel and generate the gaseous mixture.

The mixer 16 can be a venturi effect mixer. The mixer 16 may comprise a body 22 equipped with a calibrated orifice 24. An end portion 21a of the conduit 21 opens into the body 22 downstream of the calibrated orifice 24. The end portion 21a is equipped with a calibrated orifice 26.

Boiler 1 may also include a pneumatic valve 28 arranged to regulate the flow of gas circulating in gas supply line 21. Pneumatic valve 28 is equipped with a shutter 31 housed inside conduit 21. shutter 31 is movable in a plurality of positions so as to modulate the passage section of the gas supply pipe 21. The pneumatic valve 28 also comprises a pneumatic servo-regulator 33 adapted to convert a supply pressure into a displacement shutter 31.

The shutter 31 and the servo-regulator 33 are configured in such a way that the supply pressure of the servo-regulator 33 makes it possible to control the fuel passage section (duct 21) so as to ensure operation at constant richness.

The supply circuit 30 further comprises a pressure reduction device 38 upstream of the burner 6. Thus, the pressure reduction device 38 is configured to induce a pressure reduction in the supply circuit 30, ie between the burner 6 and inputs to the oxidizer 32 and fuel 34 supply circuits. In particular, the pressure reduction device 38 is configured to induce a pressure reduction 38 capable of damping the effect of the pressure waves generated by the ignition of the flame. Thus, the pressure reduction device 38 is configured to induce upstream of the burner 6 a predetermined pressure reduction. This decrease in Pressure is applied from pressure reducing device 38 to fan 20.

The pressure reduction device 38 is preferably arranged in the oxidant supply circuit 32. Alternatively, the pressure reduction device 38 can be arranged in the fuel supply circuit 34 or the mixing circuit 36 .

The pressure reduction device 38 is selectively activatable. In other words, the pressure reducing device 38 has an activated state in which the pressure reducing device 38 induces a predetermined pressure reduction and an off state in which the pressure reducing device 38 does not induce a pressure reduction. such predetermined decrease in pressure.

The activation of the pressure reduction device 38 is preferably programmable so as to be able to determine a moment at which to activate the pressure reduction device 38. It is for example very advantageous to be able to activate the pressure reduction device before or during the ignition of the flame to stabilize this ignition phase.

You can see on the picture 2 a graphical representation of one embodiment of a flame ignition phase and the activation of the pressure reduction device 38.

The graph of the picture 2 comprises three curves evolving as a function of time: a first curve 100 of the power of the boiler, a second curve 102 of the speed of the fan and a third curve 104 of the flow of fuel, here gas. The y-axis corresponds to a percentage ranging from 0 to 100% of the maximum capacity of boiler power, fan speed or fuel flow, respectively.

In the embodiment shown in the picture 2 , the boiler start-up process comprises five phases: a shutdown phase 110, a pre-ventilation phase 120, an ignition phase 130 of the flame, a stabilization phase 140 and a modulation phase 150 or functioning. The stabilization phase 140 is optional.

During the stopping phase 110, the first 100, second 102 and third 104 curves are at 0%. The boiler is thus stopped or on stand-by.

The fan speed is increased during the pre-ventilation phase 120 up to a predetermined pre-ventilation value. The fuel flow remains at 0%.

When the fan speed reaches the predetermined pre-ventilation value, the flame ignition phase can be initiated. For this, the ignition device is turned on and the gas flow is increased. Thus, the supply of energy from the activation of the ignition device in the presence of the gas mixture generates a flame. When the flame appears, the power of the boiler increases. The ignition phase 130 ends when the flame is detected, for example by the ionization electrode 12. This supply of energy coming from the ignition device is for example an electric arc.

Once the flame has been detected, a stabilization phase 140 can be carried out in which the speed of the fan is reduced to reduce the power of the boiler down to a predetermined stabilization value. This stabilization makes it possible to stabilize the flame before the modulation phase 150 of the boiler or the power of the boiler is modulated according to the setpoint parameters or the user's need for heating. This stabilization phase 140 is optional so that the modulation phase 150 can be implemented as soon as the flame is detected.

The pressure reduction device 38 is activated at the time of the launch of the ignition phase 130 or before. In particular, the pressure reduction device 38 can be activated during or before the pre-ventilation phase 120. This makes it possible to guarantee the correct positioning of the pressure reduction device 38 before the ignition of the flame. The benefit of the pressure reduction device is thus improved. To further guarantee the correct positioning of the pressure reduction device 38, the latter can also be activated upstream of the pre-ventilation phase 120.

The pressure reduction device 38 is deactivated at the moment of detection of the flame or after this detection to allow stabilization of the flame before deactivation. This stability is all the more increased as the boiler output is low. Therefore, it is advantageous to deactivate the pressure reduction device 38 during or at the end of the stabilization phase 140 when the boiler power is reduced.

The pressure reduction device 38 preferably comprises a pressure drop device capable of generating a pressure drop in the pipe receiving it, here the air supply pipe 18. The pressure drop device is configured to induce a pressure drop when said pressure reduction device 38 is activated. This pressure drop member can be in the form of a calibrated orifice, an obstacle or else a geometry inducing a pressure drop (e.g. an elbow).

The pressure drop member may also include a pressure drop adjustment device. It is thus possible to vary the value of the pressure drop upstream of the burner 6. This adjustment can for example be achieved by providing a variation in the geometry of the pressure drop member, such as an angle variation for an elbow or a variation of the section of an orifice.

The operating principle of the pressure drop device is described with reference to the figures 3 and 4 . Examples of embodiments of such a pressure drop device using the same operating principle are then described with reference to the figures 5 and 6 .

There picture 3 shows the pressure reducing device 38 in its activated state and the figure 4 shows this same pressure reducing device 38 in its deactivated state.

The pressure reduction device 38 defines a first fluid circulation zone 40 and a second fluid circulation zone 42 . The head loss member 44 is placed in the second circulation zone 42. The head loss member 44 is shown here in the form of a calibrated orifice.

The pressure reduction device 38 also includes a directional member 46 configured to direct the fluid supplying the pressure reduction device 38 towards the second circulation zone 42. The directional member 46 can be one of a solenoid valve, a damper , a clapper swivel, a motorized valve, a slide valve and a shutter. In particular, the directional member 46 is configured to direct the fluid towards the second circulation zone 42 when said pressure reduction device 38 is activated. This redirection can for example be carried out by obstructing the first circulation zone 40. Thus, the fluid is forced to circulate through the pressure drop member 44 arranged in the second circulation zone 42 so as to undergo a pressure drop. . When the pressure reduction device 38 is deactivated, the directional member 46 allows the fluid to circulate through the first circulation zone 40 without undergoing pressure drop induced by the pressure drop member 44. In parallel, a small portion of the fluid can be caused to circulate through the pressure drop member 44.

Burner 6 is thus supplied with a fluid at a first pressure value when said pressure reduction device 38 is deactivated and with a fluid at a second pressure value lower than the first pressure value when said pressure reduction device is activated. The pressure of the fluid exiting the pressure reducing device 38 is thus reduced in its activated state compared to its deactivated state.

In a first embodiment according to the figures 3 and 4 , the pressure reduction device 38 comprises a first circulation pipe forming the first circulation zone 40. The pressure reduction device 38 also comprises a second circulation pipe forming the second circulation zone 42. The first and second circulation pipes circulation are here distinct from each other. In other words, one of the first and second circulation lines does not include the other. The term “pipe” is understood to mean a portion of tube whose length is equal to or greater than a maximum transverse dimension of the fluid passage section of the tube, for example the diameter when the tube is of circular section.

According to a second embodiment using the same operating principle as the first embodiment, the pressure reduction device 38 may comprise a single circulation pipe forming the first 40 and second 42 circulation zones. Examples of such an embodiment using a single circulation pipe are for example illustrated in figures 5 and 6 .

In this second embodiment, the directional member 46 comprises a closing wall 48 of a passage section 50 of the circulation pipe 52. The passage section 50 forms the first circulation zone 40. The wall of closure 48 is movable between an open position allowing the fluid to flow through the passage section 50 and a closed position in which the passage section 50 is at least partially closed. In this closed position the fluid can circulate through an orifice 54 forming the second circulation zone 42.

The closing wall 48 preferably extends transversely to the axis of extension of the circulation pipe 52 when it is in the closed position.

This orifice 54 also forms the pressure drop member 44. This orifice 54 can be formed on the closing wall 48, as in the example of the figure 5 , or on another wall inside the circulation pipe 52, as in the example of the figure 6 . This wall forming the orifice 54 can be a wall transverse to the axis of extension of the circulation pipe 52.

The orifice 54 can be a calibrated orifice, a cutout in a wall or else a space formed between the closing wall 48 and an internal wall of the circulation pipe 52. The orifice 54 is preferably of circular section. Alternatively, the orifice 54 is of any shape making it possible to induce the predetermined pressure drop.

The pressure reduction device 38 preferably comprises a holding member 56 that can be activated to hold the closure wall 48 in the closed position and/or the open position. This holding member 56 comprises for example at least one electromagnet 58 cooperating with a ferromagnetic element 60. The closure wall 48 can be configured to be held in the open position under the action of the fluid flowing through the section passing. In the latter case, the holding member 56 can only maintain the closed position.

To obtain a more stable operation of the closure wall 48, the holding member 56 is preferably configured to maintain each of the closed and open positions. For this, the holding member 56 can include at least two electromagnets. It is possible to place an electromagnet 58 at the level of the wall transverse to the axis of extension of the circulation pipe 52 and an electromagnet 48 on an internal wall of this circulation pipe 52 facing the closing wall 48 when in the open position. The closing wall 48 preferably carries the ferromagnetic element 60 intended to cooperate with the electromagnet(s) 58.

Claims (14)

Fuel boiler (1) comprising: - a supply circuit (30) for a mixture of oxidizer and fuel, said mixture supply circuit comprising a drive device (20) for the mixture through the mixture supply circuit, the supply circuit (30) of a mixture comprising an oxidant supply circuit (32), a fuel supply circuit (34) and a mixing circuit (36) of the oxidant and the fuel; - a burner (6) in fluid communication with the supply circuit (30) of a mixture, the burner (6) comprising an ignition device (10) configured to ignite the mixture of oxidant and fuel, the oxidant and fuel mixing circuit (36) being in fluid communication, at a first end, with the oxidant (32) and fuel (34) supply circuits, and, at a second end, with the burner (6); - a combustion chamber (2) receiving the burner (6),
characterized in that the supply circuit (30) of a mixture comprises a pressure reduction device (38) upstream of the burner, the said pressure reduction device being selectively activatable and arranged in the oxidizer supply circuit (32). Fuel boiler (1) according to claim 1, in which the pressure reduction device (38) comprises a pressure drop member (44, 54) able to generate a pressure drop of a fluid passing through said loss member load (44, 54) when said pressure reducing device (38) is activated. A fuel boiler (1) according to claim 2, wherein the pressure reducing device (38) defines a first fluid circulation zone (40) and a second fluid circulation zone (42), said pressure loss member load (44, 54) being arranged in the second circulation zone (42) so that the burner (6) is supplied: - by a fluid at a first pressure value when said pressure reduction device (38) is deactivated, - by a fluid at a second pressure value lower than the first pressure value when said pressure reducing device (38) is activated. A fuel-fired boiler (1) according to claim 3, wherein said pressure reducing device (38) comprises a directional member (46) configured to direct the fluid supplied to the pressure reducing device (38) towards the second circulation zone (42) to supply the burner (6) with a fluid at the second pressure when said pressure reducing device (38) is activated. A fuel boiler (1) according to claim 4, wherein the pressure reducing device (38) comprises a first circulation line forming said first circulation area (40) and a second circulation line forming said second circulation area ( 42), the first and second circulation lines being separate from each other. A fuel boiler (1) according to claim 4, wherein the pressure reducing device (38) comprises a circulation line (52) forming the first and second circulation zones. Fuel boiler (1) according to Claim 6, in which the directional member (46) comprises a closing wall (48) of a passage section (50) of the circulation pipe (52), said wall of shutter (48) being movable between: - an open position allowing the fluid to circulate through the passage section (50), said passage section (50) forming the first circulation zone (40), and - a closed position in which the passage section (50) is at least partially closed allowing the fluid to circulate through an orifice (54) forming the second circulation zone (42). Fuel boiler (1) according to Claim 7, in which the said orifice (54) forming the second circulation zone (42) is through the closing wall (48). Fuel-fired boiler (1) according to claim 7 or 8, in which the pressure drop member (44, 54) comprises a holding (56) which can be activated to hold the closure wall (48) in the closed position and/or the open position. A fuel boiler (1) according to any one of claims 4 to 9, wherein the directional member (46) is one of a solenoid valve, a damper, a swing valve, a motorized valve, a slide valve and a shutter. Method of lighting a fuel boiler (1) according to any one of the preceding claims, comprising the following steps: - generating a circulation of a mixture of fuel and oxidizer inside the mixture supply circuit (30) using the drive device, - activating the pressure reduction device (38) so as to generate a reduction in the pressure of the mixture upstream of the burner (6), - ignite the mixture of oxidizer and fuel using the ignition device (10). Ignition method according to claim 11, wherein the pressure reducing device (38) is activated before and/or during the ignition of the mixture of oxidizer and fuel. A method of ignition according to claim 11 or 12, further comprising deactivating the pressure reducing device (38) after ignition of the mixture of oxidizer and fuel. Ignition method according to one of claims 11 to 13 in combination with a boiler according to claim 7, in which the step of activating the pressure reduction device (38) comprises moving the closing wall ( 48) in the closed position so as to direct the fluid circulating through the pressure reduction device (38) through the orifice (54) forming the second circulation zone (42).

Images