The invention is situated in the field of surface combustion gas burners.
The term “gas burner”designates a burner supplied in fact with a pre-mixed gas-air mixture. In the description and claims that follow, the term “gap,” used for the sake of simplification, actually designates a pre-mixed gas-air mixture.
A so-called “surface combustion” burner designates, by contrast with a torch flame humor, a burner wherein combustion takes place on a combustion surface or combustion grid, through which the gas-air mixture is routed under pressure.
This type of burner finds particular but not exclusive application in gas water heaters. The burner generates combustion gases which heat the heat exchanger through which passes the fluid to be heated.
In this type of gas burner, the flame-holding performance on the combustion surface determines the quality of the combustion of the fuel employed (gas in this case), as well as the power variation range of the burner.
Moreover, the quality of this combustion, that is the greater or lesser emission of polluting gases into the atmosphere, depends on the flame-holding performance of a burner, on the shape of the burner and on the volume of the enclosure (or combustor) wherein the combustion takes place.
“Flame-holding” designates the ability of the base of the flame to remain in proximity to the combustion surface.
Two very widespread types of surface combustion burner are already known from the prior art.
The first type of burner includes a combustion surface (or combustion grid) consisting of a stainless steel sheet perforated with small holes of varying sizes, as well as with slits of varying dimensions, Such a burner is of Cylindrical Shape, for example. The particular association of small hole regions with it regions, the cross-sections whereof are therefore larger, makes it possible to hold the flame properly, but only for a very narrow range of power variation, that is on the order of 1 to 3.
This type of burner has the disadvantages mentioned hereafter.
When this burner is used at low power, that is with a low flow rate of the gas-air premix, its surface undergoes a very strong increase in temperature, (of several hundred degrees), connected with flame contact with the sheet, which causes flashbacks into the burner, which can even lead to destruction of the latter,
Conversely, when this burner is used at high power, there is a risk, of the flame separating from the surface of the burner, which occurs when the exit speed of the gas is considerably higher than the flame propagation speed, and this has the effect of causing considerable pollutant gas emissions, particularly of nitrogen oxides (NOx) and of carbon monoxide (CO),
Considering the aforementioned disadvantages, the range of usable power setting for a given burner is therefore rather limited.
The second known type of burner consists of a perforated steel sheet, covered with a layer of stainless steel fibers placed on the outer surface of the perforated sheet. This layer of fibers has a thickness on the order of 1 mm to 2 mm and plays the role of a rather high-performance flame-holder as well as the role of a thermal insulator to reduce the temperature rise of the perforated sheet and thus reduce the risk of flashback.
This type of burner allows a wider power variation range than the first type Of burner, that is on the order of 1 to 5, or even 1 to 10 depending on the texture of the steel fiber used. This steel fiber, however, is expensive, which increases the total cost of the burner
The present invention therefore has the purpose of providing a surface combustion gas burner which solves the aforementioned disadvantages and which in particular allows several goals to be attained simultaneously, to wit:
To this end, the invention relates to a surface combustion gas burner including a combustor grid consisting of a sheet made of metal or refractory material, perforated with a series of slits.
In conformity with the invention, said sheet includes a series of deflectors integral with said sheet and protruding from its outer face, each deflector extending longitudinally and laterally above the totality of the surface of a slit; each deflector includes a gas flow guiding part and a part connecting it to the sheet, said guiding part being spaced away from the sheet so as to form with it at least one lateral gas ejection opening; and said deflectors are arranged in pairs, so that their lateral gas ejection openings face one another.
Thanks to these features of the invention, the burner can be used at very high power without separation of the flame, and conversely at very low power without flashback, which guarantees its sturdiness and its longevity.
According to other advantageous and non-limiting characteristics of the invention, taken alone or in combination:
Other features and advantages of the invention will appear from the description which will now be given, with reference to the appended drawings which show, by way of indication but without limitation, several possible embodiments of it.
In these drawings:
A first embodiment of a gas burner according to the invention will, now be described with reference to
This burner includes a combustion grid. It is connected to means, not shown, a fan for example, configurated for delivering a gas-air mixture, natural gas with air for example, under pressure, to the inside of the burner. The gaseous mixture passes through the openings and ports of the grid and combustion is initiated on its outside face thanks to an ignition system known to the person skilled in the art.
This combustion grid consists of a sheet (or plate) 1 made of metal, of stainless steel for example, or of refractory material. These inner and outer faces are respectively labeled 11 and 12.
This sheet 1 is perforated with a series of slits 2, of generally rectangular shape, each slit 2 having two longitudinal edges 23, 24.
Each slit 2 is capped with a bridge 3 or “little bridge”, which is in one piece (formed integrally) with said sheet 1 and which protrudes from the outer surface 12 thereof.
As will be described later in more detail, the bridge 3 plays the role of a deflector for the gas passing through the sheet 1
Each bridge 3 consists of a strip of sheet metal curved or formed so that its concavity is oriented toward the slit 2. The bridge has a central part (portion) 30 and two ends 31, 32 which are attached respectively to the two ends 21 and 22 of the slit 2 above which this bridge extends longitudinally and laterally. The central part 30 constitutes a gas flow guiding part and the ends 31, 32 a connection part to the sheet 1.
Preferably, the slits 2 are made using appropriate punching dies, not shown in the figures for the sake of simplification.
Preferably, the width L1 of the bridge 3 is equal to the width L2 of the slit 2 above which it is positioned (see
The travel of the punching die defines the height H2 of a space 4, provided between the bridge 3 (more precisely its central part or portion 30) and the slit 2.
The spacing between the bridge 3 and the outer face 12 of the sheet 1 located in proximity to the bridge allows two openings (or holes) 40 and 40′ to be defined, called “lateral gas ejection openings,” on either side of the space 4 (see
These lateral gas ejection openings 40 and 40′ lie respectively in the planes P1 and P2 which are mutually parallel and also perpendicular to the plane P3 of the slit 2. In the remainder of the description and of the claims, this plane P3 of the slit 2 is taken to be at the outer face 12 of the sheet 1.
Advantageously, and as is better seen in
The different bridges 3 are therefore arranged in the form of lines 81 or row (horizontal in
The bridges 3 are arranged in pairs, the lateral openings 40, 40′ whereof face one another.
Also preferably, the bridges 3 in different lines 81 are aligned with a longitudinal axis X1-X′1 or X2-X′2 perpendicular to Y-U′ , so as to define a column of bridges 82 (vertical in
Advantageously but not compulsorily, the bridges 3 are arranged with a constant spacing E1, and E2 (E1=E2).
According to a simplified variant of the invention, the sheet or plate 1 is provided only with slits 2 and bridges 3. Advantageously, however, another type of perforation with a particular geometry is also practiced on the entire sheet 1.
These are ports 5 extending into discharging micro-tubes 6 which protrude from the outer face 12 of the sheet 1.
Preferably, the ports 5 are circular and the micro-tubes 6 are cylindrical, so that they have a central axis or axis of revolution Z-Z′ perpendicular to the sheet 1 (see in particular
The discharging micro-tubes 6 thus constitute gas micro-injectors. These micro-tubes 6 have the effect of considerably increasing the thickness of the sheet 1 at the location where they are formed.
The ports 5 and the micro-tubes 6 are obtained for example by drawing, which has the effect of stretching the material of the sheet.
Due to this, the outer diameter D1 of the base of these micro-tubes 6, at their interface with the outer face 12 of the sheet 1, is greater than their outer diameter at the tip, D2. The thickness of the wall of the micro-tube is thus frusto-conical.
The slits/bridges and the ports/micro-tubes can be arranged and grouped on the sheet 1 so as to form different patterns 7.
According to a preferred variant embodiment of the invention shown in
It is also possible to have only one micro-tube 6 or more than two between the two bridges 3.
Moreover, these patterns 7 can be arranged and repeated over the plate 1 so that the spacing E1 between the longitudinal axes X1-X′1 and X2 -X′2 respectively of the left 3a and right 3b bridges of a first pattern 7 is equal to the spacing E2 between the longitudinal axis x2-x′2 of the right bridge 3b of this pattern 7 and the longitudinal axis X1-X′1 of the left bridge 3a of a second adjoining pattern 7′ located to the right of the first pattern 7. In other words, the spacing E3 between two alignment axes X -X′ of micro-tubes 6 is twice the value of the spacing E1 between two, left 3a and right 3b in bridges of one and the same pair. This feature is not compulsory.
In the example shown in
However, as can be seen in
Other variant embodiments can also be contemplated. For example,
It will be noted that the dimensional proportions of the slits, bridges, ports openings and micro-injectors play a role in the desired result of improving combustion performance.
Thus preferably the ratio L1/H2 is at least equal to 0.5. Also preferably, the ratio H3/D is comprised between 0.2 and 2, more preferably equal to 1.
Other embodiments of the deflectors, other than the bridges 3, will now be described in connection with
According to a first embodiment shown in
A space 4′ is provided between the portion 30′ and the slit 2 and there is a single lateral gas ejection opening 41 between the portion 30′ and the sheet 1.
These two deflectors 3′ are positioned facing one another, so that their respective openings 41 are facing one another. When the micro-tubes 6 are present, the two deflectors 3′ are also advantageously parallel to the alignment axis X-X′ of said micro-tubes.
According to a second variant embodiment shown in
Finally, it will be noted that whatever the technique and/or means for producing the deflector(s) 3, 3′, 3″, these cover the totality of the surface area of the slit 2.
The view of
According to one preferred variant embodiment shown in
Advantageously, the axes X1-X′1 and X2 -X′2 of the bridges (and hence of the slits 2) are parallel to the axis of revolution of the cylindrical burner.
Finally, as shown as in
The operation of the burner conforming to the invention is the following.
As can be seen in
Moreover, the gas which leaves the slit 2 perpendicularly to the plane of the sheet 1 hits the deflector, more precisely its central gas flow guiding part 30, which extends above the entire surface area of said silt, so that it cannot escape perpendicular to the sheet 1.
For this reason, the escape of the gas occurs to either side of the bridges 3, through lateral gas ejection openings 40 and 40′.
Through the opening 40 with no micro-tube 6 in front of it, this gas escape occurs parallel to the outer face 12 of the sheet (arrow F1), or tangentially if the sheet 1 is curved (in the case of a cylindrical burner). This gas escape through the lateral as ejection opening 40 thus takes place perpendicularly to the axis of the gas jets (arrow F3) leaving the adjoining micro-tubes 6, or quasi-perpendicularly to this direction F3 if the gas escape is tangential.
Moreover, the gas leaving the opening 40′, located in front of a micro-tube 6, is also directed parallel to the face 12 or tangentially thereto then, once it hits the micro-tube 6, is then deflected outward (arrow F2), parallel to the jets leaving the micro-tubes 6 (arrows F3). In addition, and as can be seen in
Preferably, and as can be seen in
Thus the gas, which tends to be deflected in a direction parallel to the surface of the deflector that it covers, is guided (arrow F1) parallel to the sheet 1 (or tangentially thereto, if it is curved).
The generatrix G could also be quasi-parallel to the plane P3 (a slight angular variation is possible), provided that the major portion of the gas flow is guided as aforementioned.
The combustion zone in a line along the axis X-X′ receives not only the gas flow of the pairs of micro-tubes 6 but also the flow of gas leaving the bridges 3 located on either side. This combustion zone shown by the flame 91 in
It makes it possible to develop a strong flow through the micro-tubes 6 and the additional flows coming from the bridges 3 accentuate the adhesion of the flame to the tips of the micro-tubes 6 with an impressive performance, even for very large gas flow ranges.
Advantageously, these principal flow type combustion zones 91 are alternated with combustion zones 92 called, “secondary flow type,” which extend along axes X3-X′3 and which receive only the flow of gas of the bridges 3 (arrows F1 in
The face-to-face encounter of these to gas flows parallel or tangential to the wall of the sheet 1 and which come from the lateral openings 40 (see arrows F1), causes combustion near the outer face 12 of the sheet 1, in a zone free of perforations. The base 920 of this flame 92 is slightly separated from the face 12, because this face is free of the heavy flow of the micro-tubes 6. Moreover, the gas which circulates on the side of the inner face 11 of the combustion grid contributes to cooling this wall, which glows red only slightly.
This bidirectional distribution of the gases (arrows F1 and F3) at the surface of the sheet 1 of the combustion grid makes it possible to perfectly control the holding of the flame and thus allows combustion within a very large flow (and hence power) variation range (greater than 40), without flashback or separation flame.
For a given burner area, the transparency coefficient plays an important role in the behavior of the combustion that is obtained, depending on the gas flow for different desired ranges of power.
With prior art burners, the greater the coefficient of transparency, the higher the maximum power. However, the minimum power will also be high if flashbacks are to be avoided. For this reason, the range of per variation is reduced for a given burner.
On the contrary, with the present invention, it becomes possible to use the burner over a very large amplitude of power variation.
The operation described with the bridges 3 is the same with the hoods 3′ or the gills 3″. Thus, in the absence of micro-tubes 6 between the hoods or the gills, only secondary flow type combustion zones are created, and when they are present, principal flow type combustion zones are created.
To this excellent flame-holding performance is also added a very low pollution rate with a very low emission of carbon monoxide CO.
On this topic, reference is made to the curve of
The curve C1 was obtained with a prior art burner, the combustion grid whereof is a perforated sheet which had only a series of slits and ports but without bridges and without micro-tubes. It is observed that this CO emission curve rises progressively when the power is increased beyond 5 kW, this being so from 5 to 30 kW, thus confirming the decay in the cleanliness of combustion by separation of the flame (the CO value below 5 kW cannot be estimated because flashback occurs).
Conversely, the curve C2 shows the results obtained with the burner according to the invention having alternating patterns of dual micro-tubes and dual bridges, with the preferred dimensions given earlier. It is observed that the CO emission only varies from 0 ppm to 6 ppm for a power variation range from 1 to 30 kW. Other tests performed for NOx show that these are reduced by one-half with the burner according to the invention.
These results show distinctly the excellent flame-holding performance of the flame and the cleanliness of the combustion resulting therefrom.
One particular application of this type of burner relates to heat exchangers, and particularly those of domestic and industrial water heaters. It is possible to operate the burner according to the invention at low power, for example to produce hot water needed for central heating of a well-insulated house, and to operate it momentarily at very high powers in case of domestic hot water demand, with “flash” type production.
Other diverse and varied applications of this burner can be contemplated. Purely by way of illustration, it can be used, for example, in manufacturing lines for glass and for heat-treating it or even in cooking by surface combustion used in agri-food factories.
Number | Date | Country | Kind |
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1256467 | Jul 2012 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/064058 | 7/3/2013 | WO | 00 |