KR20130100302A - An air-gas mixer device for premix combustible gas burners - Google Patents

Abstract

A fan unit (6) having an impeller (7) with radial blades (8) driven about an axis of rotation (X), an axial suction section (9), and a radially opposite transfer section (10); A first duct (15) coaxial with the axis of rotation (X), having a distal end (15a) converging in the vicinity of the suction section (9); A tubular second duct 16 coaxial with the first duct 15 having a minimum cross section; Blades (8) protruding from the base surface (12) of the impeller, each blade (8) having a leading edge (13) disposed in the suction section (9); There is provided a mixing device for a combustible gas burner comprising a fan housing manifold (11) having a front surface profile (14) disposed in front of the blades (8) of the impeller and spaced from the blades (8). The device also includes an appendage 20, which protrudes away from the axis X from the converging first duct 15 and is disposed outside the duct 15a. , Jointly defined by the distal end of the converging first duct 15, the extension of the portion 15a towards the base surface 15, the leading edges 13, and the front surface profile 14.

Description

An air-gas mixer device for premix combustible gas burners

The present invention relates to a mixing apparatus for a premixed gas burner having the configuration described in the preamble of claim 1 which is the main claim of the present application.

The present invention is particularly relevant to, but is not limited to, the technical field of domestic boilers, which are designed for space heating and / or water heating.

In this field, household boilers must meet various requirements related to the convenience and safety of the user. Safety requirements include providing action in response to any disturbances that may occur in the outlet flue.

Boilers are usually thought of as systems in which gas and cold water are input and combustion products and hot water are produced by the combustion of gas and air. Combustion by-products are discharged through ducts or corollas, which deliver the combustion by-products outside the building where they are installed to the outside environment.

The corolla is usually in the form of a cylindrical tube, one end of which is connected to the combustion chamber and the other end of which is connected to an outer terminal. Since the distal end is in an external environment, it may be obstructed or blocked by external obstacles such as birds or nests that are carried by the wind and land on the distal end. In such a state, ie with the end blocked, the boiler must be operated or the boiler must be switched off with the carbon monoxide output reduced below the limits set by regulation.

The combustion process in the boiler takes place in a combination of combustible gas and air, which is supplied to the inside of the plant by a fan. Intake air flows into the mixer before it reaches the fan, creating a vacuum, thereby drawing in combustible gas. In a compact system, the mixer is made in the form of a converging duct, and a vacuum is formed at the portion with the smallest cross section. Gas is injected into the flow of air through the duct coaxial with the converging duct.

In systems that do not need to be compact, a diffused duct having a length at least equal to the length of the converging duct is provided downstream of the minimum cross-sectional section.

The amount of gas drawn by the vacuum is controlled by a gas valve, which maintains a constant gas to air ratio even as the fan's rotational speed changes.

If the discharge corridor fails, the flow of air supplied by the fan is reduced even if the fan speed remains the same, and thus the gas flow rate is also reduced.

In an ideal system, the gas to air ratio should be kept constant when the air flow rate drops below the initial required flow rate. This continues the combustion process, keeps carbon monoxide emissions within the limits, and turns the boiler off below a predetermined fire level.

The boiler has a reference limit in which the ionization current in the flame is set on the electronic circuit board of the boiler because the flame can no longer be held stable, or the safety system of the boiler detecting the presence of the flame by means of electrodes. By measuring lower, it is turned off because it operates to close the gas valve.

Mixer systems with only converging ducts as described above typically do not work satisfactorily when the coronal failure occurs. As the ducts fail, the gas-to-air ratio increases, resulting in carbon monoxide far exceeding the limits set by regulation.

In the known system described above, the gas to air ratio increases when there is a failure in the corolla. The increase in the ratio is due to the increase in the amount of gas injected due to the increase in the degree of vacuum. This phenomenon occurs due to the different fluid dynamic conditions created in the region of the aperture (suction section) of the impeller. Under these conditions, a vortex occurs about an axis that is coaxial with the axis of rotation of the impeller, and recirculation occurs between the inlet and outlet of the blade channel.

The present invention provides an air-gas mixing device of the type described above, which is designed to overcome the limitations of the prior art described above in terms of structure and function.

This object is achieved by the air-gas mixing device of the present invention as described in the appended claims.

Other features and advantages of the present invention will become apparent from the following detailed description with reference to the accompanying drawings, in which preferred embodiments of the invention are intended for guidance but not limiting of the invention.
1 is a schematic diagram of a plant in which an apparatus according to the invention is used.
2 is a schematic view of an axial cross section of a mixing device according to the prior art.
3 is a schematic view of an axial cross section of a device according to the invention.
4 and 5 are schematic diagrams illustrating different variant embodiments, in which an axial cross section of the detail of FIG. 3 is shown.
6 is a schematic front view of the device according to the invention shown in the figures.
7 is a detailed perspective view of another exemplary embodiment of the device according to the invention.

Referring to FIG. 1, reference numeral 1 denotes a boiler with a combustible gas burner in which air and gas are premixed, which boiler is used, for example, to heat the environment 2. A combustion chamber (not shown) is connected via a combustion fume outlet duct 3 to a discharge terminal 4 (shown schematically) disposed outside of the environment.

The boiler 1 comprises a burner fed with a combustible air-gas mixture, which is premixed in a mixing device 5 which is schematically shown, for example, as a configuration known in FIG. 2. do. The mixing device comprises a fan unit 6 with an impeller 7, the impeller being driven around the axis of rotation X, the impeller having a transfer section radially opposite the axial suction section 9. Radial blades 8 extending between 10 are provided. The impeller 7 is accommodated in an enclosure 11, in which sections 9, 10 are formed.

Each of the impeller blades 8 protrudes from the base surface 12 of the impeller and extends transverse to the axis X and has one edge 13 in the suction section 9, the adjacent edges of which The pair forms the mouth or leading edge of the corresponding blade channel, which blade channel extends between pairs of adjacent blades along the extension of the blades between the sections 9, 10.

Within the manifold 11 containing the impeller 7 is formed a front surface facing the sides of the blades axially opposed to the base surface 12, the profile of which is in the axial cross section of FIG. 2. It is indicated by the number 14.

The mixing device comprises a tubular duct 15 which is designed to direct air at the intake section 9 of the fan where air sent to the burner is led by the fan, upstream of the intake section, the duct being a shaft ( It has a distal end 15a arranged coaxially with X) and converging towards the suction section 9, the free end of which has a minimum cross section. The converging geometry in this section creates a vacuum, which draws a flow of gas, which is coaxial with the duct 15 but at least partially tubular in the duct 15. Guided through the second duct 16. Alternatively, the duct 16 may extend outside the duct 15.

The amount of gas drawn by the vacuum is controlled by a gas valve (not shown) in a conventional manner, which maintains a constant gas to air ratio even as the fan's rotational speed changes.

According to the main feature of the present invention, the device 1 further comprises at least one attachment in the form of a stator blade element 20, which stator blade element extends outwardly and axially from the lateral profile of the duct 15. It protrudes away from (X).

Referring to FIG. 3, when the middle section of the blade element 20 is shown in the plane of the axial cross section in the figure (the plane of the drawing page), the blade element is a region defined jointly by the following elements. (Indicated by dashed lines in the drawing).

The profile of the distal end of the converging duct 15,

An extension line parallel to the axis X from said distal end to a point near the surface 12,

Part of the base surface 12 of the impeller, adjacent the corresponding blade edges 13,

The corresponding leading edge 13 of the blade channel, and

The surface profile 14 of the impeller housing manifold 11, which is disposed forward with respect to the blades 8 in proximity to the corresponding edges 13.

In the confined region indicated as dashed lines in FIGS. 3 to 5, the at least one blade element 20 at least partially occupies the region while away from the blades of the impeller to prevent interference with the blades. It may extend from the lateral profile of the converging element.

4 and 5, alternative configurations of the area defining the blade element 20 are shown, depending on the different front profile of the manifold 11.

More specifically, the blade element 20 has a plate-like shape with opposing faces 20a defining a lateral thickness 20b.

In an exemplary embodiment, the stator blade element 20 extends radially about the axis of rotation X, and the opposing faces 20a of the stator blade element 20 are flat. As will be readily appreciated, other shapes or arrangements are possible. The number and angular arrangement of the blade elements 20 can also vary.

In the further exemplary embodiment shown in FIG. 7, four blade elements 20 are provided, which are arranged at circumferentially equal angular spacings. The blade elements extend radially with a flat surface profile having a rectangular geometry.

Preferably, each of the blade elements 20 has a thickness 20b, which is greater than 0.2 mm, preferably 1 mm, and the converging duct 15 has a thickness 21 of less than 3 mm at the end with the smallest cross section. Having a wall.

The functions of the stator blade element according to the invention are described in detail below.

When the corolla is at least partially obstructed, the gas to air ratio tends to increase. This increase is due to the increase in vacuum followed by the amount of gas injected. This phenomenon occurs due to the different hydrodynamic conditions created in the region of the impeller's aperture. Under these conditions, vortices are generated about an axis that is coaxial with the axis of rotation X, and recirculation occurs between the inlet and outlet of the blade channel. Providing at least one accessory or blade 20 disposed in the aforementioned area tends to counteract such hydrodynamic action of the combustible mixture, which leads to improved performance in the coronary failure state. That is, the air-to-gas ratio tends to decrease as the fault increases, so the boiler is safely turned off.

The above described approach allows the compact configuration of the mixer to be maintained and also reduces the gas to air ratio since the flames tend to extinguish without producing carbon monoxide due to instability when the gas to air ratio is reduced. It becomes a safety parameter.

Accordingly, the present invention solves the problems of the prior art described above and provides the advantages as described above over known solutions.

Claims (7)

An impeller 7 with radial blades 8 driven around the axis of rotation X, an axial intake section 9, and a radially opposite delivery section; A fan unit 6 having 10);
A first duct (15) coaxial with the axis of rotation (X), having a terminal portion (15a) that converges in the vicinity of the suction section (9) for supplying a flow of air to the suction section; One, the first duct 15;
On the upstream side of the fan intake section 9, a flow of gas is supplied at the end of the converging portion 15a with a minimum cross section so that the flow of air is mixed with the flow of gas, and coaxial with the first duct 15. A tubular second duct 16;
Blades 8 of the impeller protruding from the base surface 12 of the impeller, each of which has a leading edge 13 disposed in the suction section 9, the leading edges being Blades 8, which form mouths of corresponding blade channels between adjacent pairs of blades extending between the suction section 9 and the transfer section 10 of the fan; And
A fan housing manifold (11) having a front surface profile (14) disposed in front of the impeller blades (8) and spaced from the impeller blades (8); , A mixing device for a combustible gas burner,
The mixing device for the combustible gas burner includes at least one appendage projecting from the converging first duct 15 in a direction far from the axis X and disposed outside the first duct 15a; Wherein the at least one accessory comprises: a distal end of the converging first duct 15; An extension of the distal end 15a towards the base surface 12 of the impeller at the side of the impeller base surface 12 closer to the leading edges 13 of the blades; Leading edges 13 of the blades; And a front surface profile 14 of the fan housing manifold 11 disposed in front of the blades 8 of the impeller near the corresponding leading edges 13 of the blades. Mixing device for combustible gas burner, characterized in that the spread. The method of claim 1,
The at least one accessory (20) has a shape in the same way as a stator blade element. The method of claim 1,
Mixing apparatus for combustible gas burners, wherein at least one blade element (20) has a shape similar to a plate. The method according to claim 2 or 3,
Said at least one blade element (20) extends radially from the axis of rotation (X) and has flat and opposite faces (20a). 5. The method according to any one of claims 2 to 4,
The mixing device for combustible gas burners comprises at least four blade elements (20) arranged circumferentially at regular angular intervals. The method of claim 5,
Mixing apparatus for combustible gas burners, each of said blade elements (20) having a square flat profile. The method according to claim 6,
Each of the blade elements 20 has a thickness greater than 0.2 mm measured between the opposing faces 20a and the converging duct 15 has a thickness of less than 3 mm at the end with the smallest cross section. Mixing device for gas burners.

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