Field of the invention.
[0001] The present invention relates to a premix burner for combustion of premixed gas-air
mixtures.
Background of the invention.
[0002] Premix burners are well known to the state of the art. Some of these premix burners
comprise a tubular burner body. Such a burner is described in US5022352, where it
is used to heat the water of e.g. a central heating system. GB 1 258 784 and FR 2
676 269 also disclose such burners.
[0003] Such premix burner comprising a tubular burner body, preferably made out of steel
plate, having along its tubular burner body at least one, but usually several matrixes
of burning slots and/or holes. The tubular burner body is closed at one side by a
so-called end cap. When the end cap is not provided with burner slots, the premix
burner as known in the art may show some defects after a certain period of use.
[0004] Nowadays, the working conditions of premix burners in general become more severe,
due to higher requirements of the burning circumstances. Premix burners nowadays are
to be able to modulate the air-gas throughput over a wider range. Especially, premix
burners have to be able to burn very low amounts of air-gas mixtures. Hence, during
a low throughput of air-gas mixture, the combustion is situated very close to the
tubular burner body. The lower the throughput, the closer the flame front is situated
near the tubular burner body. A part of the combustion energy will heat the tubular
burner body and the end cap, so causing thermal expansion of both tubular burner body
and end cap. Especially when the end cap is not provided with burner slots (hereafter
referred to as "impermeable end cap") difference in thermal expansion may occur between
both elements, being end cap and tubular burner body, due to e.g. different temperatures
of both elements, or different thermal expansion coefficients of both elements. The
tubular body is heated to higher temperature levels, due to a closer flame front,
and is so subject of more severe thermal stresses. This difference may cause thermal
cracks, especially at the welding zone of both elements.
Summary of the invention.
[0005] It is a subject of the present invention to provide tubular burner bodies, which
are able to resist better the severe thermal expansions at the connection between
tubular burner body and impermeable end cap, both parts made out of metal, usually
steel plate.
[0006] According to the present invention, a premix burner comprises a tubular burner body,
an impermeable end cap and possibly a diffusion system, located inside the tubular
burner body. The tubular burner body comprises at least one matrix of burning slots
and/or holes on its surface. Premix air-gas mixture is blown into the tubular burner
body via an appropriate inlet, usually at the lower side of the tubular burner body.
Since the tubular burner body is closed at the other side by the impermeable end cap,
the air-gas mixture is forced to flow, possibly via an air-gas diffuser, through the
burning slots and/or holes, where combustion takes place.
[0007] According to the present invention, it was found that the risk on thermal cracks
may be avoided to a large extend, by welding an impermeable end cap to the longitudinal
end of the tubular burner body (to be closed by this impermeable end cap) of which
the surface of the impermeable end cap is at least partially curved, whereas the bending
radii of each point on the impermeable end cap surface is larger than 3 times the
metal thickness of the impermeable end cap material.
[0008] Preferably, radii larger than 4 times the metal thickness of the impermeable end
cap material are used. An additional advantage of these large radius or radii, is
that internal stresses in the impermeable end cap, due to the shaping of the impermeable
end cap, are reduced to a minimum.
[0009] The border of the impermeable end cap and the longitudinal end of the tubular burner
body has to engage closely.
[0010] Preferably, but not exclusively, this impermeable end cap is to be welded to the
longitudinal end in such a way that the curvature of the impermeable end cap surface
extends outwards of the tubular burner body. Hereafter, extending outwards from the
tubular burner body is referred to as "convex". The impermeable end cap is welded
to the longitudinal end over the impermeable end cap's lower border. The impermeable
end cap may also be connected to the tubular burner body, having a curvature extending
inwards to the tubular burner body. Hereafter, extending outwards from the tubular
burner body is referred to as "concave".
[0011] The impermeable end cap may be curved over its whole surface, having bending radii
larger than 3 times the metal thickness of the impermeable end cap material. However,
the bending radius may differ for each point of the surface of the impermeable end
cap. Preferably, the impermeable end cap is only bent at the outer border of the impermeable
end cap, where the end cap is connected to the tubular burner body. In the inner part
or zone of the surface of the impermeable end cap, the impermeable end cap is preferably
substantially flat, having a bending radii being substantially infinite. "substantially
infinite" is to be understood as larger than 10 times the maximum distance between
to points of the border of the impermeable end cap.
[0012] When, according to the present invention, such impermeable end cap is welded to the
longitudinal end of the tubular burner body, with a concave or convex curvature, the
relatively large radius or radii will enable the impermeable end cap to compensate
the difference in thermal expansion between tubular burner body and impermeable end
cap, during combustion of combustible gas/air mixture at the burner slots, by slightly
changing the radius or radii. This slight change prevents the occurrence of too large
stresses over the welding between tubular bumer body and impermeable end cap. As a
result, thermal cracks may be avoided.
[0013] The tubular burner body and the impermeable end cap are made out of metal, e.g. metal
or steel plate, preferably stainless steel. Preferably the same material is used for
both elements. Metal thickness' of both tubular burner body and impermeable end cap
ranging from 0.2 to 1.5 mm may be used, preferably ranging from 0.2 to 1mm, such as
0.3mm, 0.5mm, 0.6mm, 0.8mm or 1 mm.
Tubular burner body may be provided by different techniques. Usually, a tubular burner
body is provided by rolling a tube out of a perforated metal plate. The tube is closed
by welding the plate edges in axial direction, e.g. by laser of TIG-welding.
[0014] Usually, the impermeable end cap is pressed out of metal plate.
[0015] The lower border of the impermeable end cap and the longitudinal end of the tubular
burner body may be welded to each other in several different ways, depending on the
dimensions of the lower border of the impermeable end cap as compared to the circumference
to the longitudinal end of the tubular bumer body, either when the curvature is used
in a concave or convex way.
[0016] In case the inner side of the lower border of the impermeable end cap engages the
outer side of the longitudinal end of the tubular burner body, both impermeable end
cap end tubular burner body are preferably spot welded or laser welded to each other.
[0017] In case the outer side of the lower border of the impermeable end cap engages the
inner side of the longitudinal end of the tubular burner body, both impermeable end
cap end tubular burner body are preferably spot welded or laser welded to each other.
[0018] In case the lower border of the impermeable end cap has essentially the same circumference
as the longitudinal end of the tubular burner body, laser welding or TIG-welding welds
the impermeable end cap and tubular burner body. They are so-to-say welded face to
face, without an overlap of material of the impermeable end cap and the tubular burner
body.
[0019] A person skilled in the art understands that a large range of dimensions, both of
diameter and height of the premix burner may be obtained. Usually, the diameter is
larger than 0.5cm, preferably it ranges from 2.5 to 25 cm, most usually however it
ranges between 6 to 8 cm. A height of the tubular burner body preferably ranges from
10 to 50 cm, most usually in the range of 10 to 20. Even so, the tubular burner body
is not to be understood as having a circular cross-section when cut longitudinally.
Other cross sections may be used, such as elliptic or oval cross sections.
[0020] Such premix burners as subject of the invention may be used in heating devices, heating
water or air, e.g. central heating systems and boilers.
Brief description of the drawings.
[0021] The invention will now be described into more detail with reference to the accompanying
drawings wherein
- FIGURE 1 shows schematically a premix burner as subject of the invention .
- FIGURE 2 is a radial cut of a tubular burner body, being part of a premix burner as
subject of the invention.
- FIGURE 3 is an impermeable end cap, being part of a premix burner as subject of the
invention.
- FIGURE 4a is an axial cut of detail A out of FIGURE 1.
- FIGURE 4b is an axial cut of an alternative embodiment of the present invention.
- FIGURES 5a, 5b, 5c and 5d show different welding possibilities to connect an impermeable
end cap and a tubular burner body as subject of the invention.
- FIGURES 6a, 6b, 6c, 6d and 6e show different impermeable end cap surfaces as subject
of the invention.
Description of the preferred embodiments of the invention.
[0022] A part of a premix bumer, to which the present invention relates, is shown in FIGURE
1. A tubular burner body 11 is closed at its longitudinal end 12 with an impermeable
end cap 13, having a convex curvature. Both elements, being impermeable end cap 13
and tubular burner body 11, are welded to each other in a welding zone 14. Premix
air-gas mixture is provided by a known mixing system to an appropriate inlet system
15. The premix air-gas mixture is forced through the burning slots and/or holes 16,
which are provided in the tubular burner body 11. Leaving the burning slots and/or
holes 16, the premix air-gas mixture is subjected to combustion.
[0023] A longitudinal cut II' at the longitudinal end 12 of the tubular burner body is shown
in FIGURE 2. The longitudinal end 12 has an inner circumference 21 and an outer circumference
22. The material thickness of the tubular bumer body is indicated by T1. An impermeable
end cap 13 is shown into more detain in FIGURE 3. The impermeable end cap 13 comprises
a lower border 31, which has an inner side 32 and an outer side 33. According to the
invention, the impermeable end cap surface 34 is curved. The impermeable end cap has
a material thickness as indicated by T2.
[0024] The thickness' T1 and T2 may be different, but an equal thickness is preferred in
the range of 0.2 to 1.5mm e.g. in the range 0.4 to 1 mm, most preferably 0.6mm. A
preferred embodiment of a premix bumer as shown in FIGURE 1 has a tubular burner body
height between 10 and 14cm, e.g. 12 cm and a diameter of the tubular burner body of
7cm. Most preferably, tubular burner body and impermeable end cap are made out of
stainless steel alloy.
[0025] An axial cut of detail A of FIGURE 1 is shown in FIGURE 4a. Again, an impermeable
end cap 13 and a tubular burner body 11 are welded to each other in the welding zone
14. This welding zone has a thickness D. At least a part of the impermeable end cap
surface 34 is curved, with a bending radius R. Preferably this curved part of the
impermeable end cap surface is located near the welding zone 14. The curvature of
the impermeable end cap surface extends outward from the tubular burner body (as indicated
with flash 41).
[0026] An alternative axial cut of another embodiment of a premix burner as subject of the
invention is shown in FIGURE 4b. An impermeable end cap with a curvature extending
inwards the tubular burner body (as indicated with flash 42) is shown.
[0027] For the embodiments as shown in FIGURE 4a and 4b, a radius in the range of 2mm to
10mm is preferred, depending on the material thickness of the impermeable end cap.
For a most preferred embodiment, with an impermeable end cap material thickness T2
of 0.6mm, a radius not smaller than 2.5mm is preferred.
[0028] As is illustrated in FIGURE 5a, 5b and 5c, there are different ways to weld impermeable
end cap 13 and tubular burner body 11 to each other. In FIGURE 5a, the inner side
32 of the curved impermeable end cap 13 engages the outer circumference 22 of the
tubular burner body 11. The impermeable end cap surface is a convex way. The welding
zone 14 is characterized by an overlap of both impermeable end cap and tubular burner
body over a distance D. Preferably D is kept smaller than 6mm. This welding may be
done by spot welding, however preferably laser welding is used.
[0029] In FIGURE 5b, the outer side 33 of the curved impermeable end cap 13 engages the
inner circumference 21 of the tubular burner body 11. The impermeable end cap surface
is a convex way. The welding zone 14 is characterized by an overlap of both impermeable
end cap and tubular burner body over a distance D. Preferably D is kept smaller than
6mm. This welding may be done by spot welding, however preferably laser welding is
used.
[0030] Best results however are obtained by welding impermeable end cap and tubular burner
body "face-to-face" as shown in FIGURE 5c. In this case, the lower border 31 of impermeable
end cap 13 and the longitudinal end 12 of tubular bumer body 11 have essentially the
same circumference. They are places one to the other and are welded together by TIG-welding,
but preferably by laser welding. An extra advantage of this connection is that at
the welding zone 14, which thickness is usually less 6mm, there is no overlap of two
layers of material (one from the impermeable end cap, the other from the tubular burner
body). Preferably, laser welding techniques are used to connect impermeable end cap
and tubular burner body face-to-face. Using this technique, the thickness D of the
welding zone 14 is reduced to a minimum. When the premix burner is heated due to combustion
of a low rate of premix air-gas mixture, the difference in thermal expansion is only
due to the difference in thermal expansion on tubular burner body and impermeable
end cap.
[0031] In FIGURE 5d, the outer side 33 of the curved impermeable end cap 13 engages the
inner circumference 21 of the tubular burner body 11. The impermeable end cap surface
is a concave way. The welding zone 14 is characterized by an overlap of both impermeable
end cap and tubular burner body over a distance D. Preferably D is kept smaller than
6mm. This welding may be done by spot welding, however preferably laser welding is
used.
[0032] In the cases as shown in FIGURE 5a, FIGURE 5band FIGURE 5d, there is an extra additional
thermal expansion difference, caused by the presence of a zone where two layers of
material are present.
[0033] A lot of different curvatures are possible, as some examples are shown in FIGURE
6a and 6b. FIGURE 6a shows an impermeable end cap 13, which has an elliptic curvature.
In each point of the impermeable end cap surface, a different radius may occur. An
alternative is shown in FIGURE 6b, where an impermeable end cap 13 has a substantially
flat zone 61, and a zone 62 at the border of the impermeable end cap which is curved
inwards the tubular body of the premix burner as subject of the invention. The bending
radii in the zone 61 and 62 are larger than 3 times the thickness of the impermeable
end cap material. In zone 61, the bending radii are substantially infinite, at least
larger than 10 times the diameter 63 of the circular impermeable end cap. It is clear
that the tubular burner body has a diameter, which is essentially identical to the
diameter 63.
[0034] It is also understood that, in case the tubular body does not have a circular cross-section,
the border of the impermeable end cap and the longitudinal end of the tubular burner
body have to engage closely. One understands that in this case, of zone 61, the bending
radii are substantially infinite, at least larger than 10 times the largest distance
between two points of the border of the impermeable end cap.
[0035] FIGURE 6c, FIGURE 6d and FIGURE 6e show an impermeable end cap 13, which has a W-like
shape. In FIGURE 6c here, only a part 64 of the en cap 13 is curved, and this curvature
is extending outwards from the tubular burner body 11. In FIGURE 6d, a large part
of the impermeable end cap 13 is concave. FIGURE 6e shows an impermeable end cap which
is partially convex (65) and partially concave (66)
[0036] A person skilled in the art understands that above given examples are not meant to
be restrictive, nor that the tubular burner body has to have a circular radial cut.
1. A premix burner comprising a tubular burner body (11) and an impermeable end cap (13),
said impermeable end cap closing said tubular burner body, said impermeable end cap
being welded to said tubular burner body, said impermeable end cap having an impermeable
end cap surface (34), said impermeable end cap surface being at least partially curved,
each point of said impermeable end cap surface having a bending radius R and a material
thickness T, said each R being larger than 3xT.
2. A premix burner as in claim 1, wherein said curvature of impermeable end cap surface
(34) being at least partially concave.
3. A premix burner as in claim 1, wherein said curvature of impermeable end cap surface
(34) being at least partially convex.
4. A premix burner as in claim 1, wherein said curvature of impermeable end cap surface
(34) being at least partially concave and partially convex.
5. A premix burner as in claim 1 to 4, said impermeable end cap surface (34) having a
zone being substantially flat.
6. A premix burner according to claim 4, said impermeable end cap surface (34) having
a zone (61) being substantially flat, said bending radii in said substantially flat
zone being larger than 10 times the maximum distance between two points of the border
of said impermeable end cap.
7. A premix burner as in claim 1 to 6, wherein said impermeable end cap (13) comprises
a lower border (31), said tubular burner body (11) comprising a longitudinal end (19),
said lower border and longitudinal end being welded to each other without overlap.
8. A premix burner as in claim 1 to 7, wherein said impermeable end cap (13) and said
tubular burner body (11) being welded to each other by laser welding.
9. A premix burner as in claim 1 to 7, wherein said impermeable end cap (13) and said
tubular burner body (11) are welded to each other by spot welding.
10. A premix burner as in claim 1 to 7, wherein said impermeable end cap (13) and said
tubular burner body (11) are welded to each other by TIG-welding.
11. A premix burner as in claim 1 to 10, said tubular burner body (11) having a height
in the range of 10 to 50 cm.
12. A premix burner as in claim 1 to 11, said tubular burner body (11) having a circular
cross-section, having a diameter in the range of 0.5 to 25cm.
13. Use of a premix burner as in claim 1 to 12 in a central heating or water heating system.
1. Vormischbrenner, der einen röhrenförmigen Brennerkörper (11) und eine undurchlässige
Endkappe (13) umfasst, die den röhrenförmigen Brennerkörper verschließt, wobei die
undurchlässige Endkappe mit dem röhrenförmigen Brennerkörper verschweißt ist und eine
undurchlässige Endkappenfläche (34) aufweist, welche zumindest teilweise gekrümmt
ist, wobei jeder Punkt der undurchlässigen Endkappenfläche einen Biegeradius R und
eine Materialdicke T aufweist, wobei R jeweils größer ist als 3xT.
2. Vormischbrenner nach Anspruch 1, bei dem die Krümmung der undurchlässigen Endkappenfläche
(34) zumindest teilweise konkav ist.
3. Vormischbrenner nach Anspruch 1, bei dem die Krümmung der undurchlässigen Endkappenfläche
(34) zumindest teilweise konvex ist.
4. Vormischbrenner nach Anspruch 1, bei dem die Krümmung der undurchlässigen Endkappenfläche
(34) zumindest teilweise konkav und teilweise konvex ist.
5. Vormischbrenner nach einem der Ansprüche 1 bis 4, bei dem die undurchlässige Endkappenfläche
(34) einen im Wesentlichen flachen Bereich aufweist.
6. Vormischbrenner nach Anspruch 4, bei dem die undurchlässige Endkappenfläche (34) einen
im Wesentlichen flachen Bereich (61) aufweist, wobei die Biegeradien in dem im Wesentlichen
flachen Bereich größer sind als das Zehnfache des maximalen Abstands zwischen zwei
Punkten des Rands der undurchlässigen Endkappe.
7. Vormischbrenner nach den Ansprüchen 1 bis 6, bei dem die undurchlässige Endkappe (13)
einen unteren Rand (31) umfasst, wobei der röhrenförmige Brennerkörper (11) ein Längsende
(19) umfasst und der untere Rand und das Längsende ohne Überlappung miteinander verschweißt
sind.
8. Vormischbrenner nach den Ansprüchen 1 bis 7, bei dem die undurchlässige Endkappe (13)
und der röhrenförmige Brennerkörper (11) durch Laserschweißen miteinander verschweißt
sind.
9. Vormischbrenner nach den Ansprüchen 1 bis 7, bei dem die undurchlässige Endkappe (13)
und der röhrenförmige Brennerkörper (11) durch Punktschweißen miteinander verschweißt
sind.
10. Vormischbrenner nach den Ansprüchen 1 bis 7, bei dem die undurchlässige Endkappe (13)
und der röhrenförmige Körper (11) durch WIG-Schweißen miteinander verschweißt sind.
11. Vormischbrenner nach den Ansprüchen 1 bis 10, bei dem der röhrenförmige Brennerkörper
(11) eine Höhe in einem Bereich von 10 bis 50 cm aufweist.
12. Vormischbrenner nach den Ansprüchen 1 bis 11, bei dem der röhrenförmige Brennerkörper
(11) einen kreisförmigen Querschnitt mit einem Durchmesser in einem Bereich von 0,5
bis 25 cm aufweist.
13. Verwendung eines Vormischbrenners nach den Ansprüchen 1 bis 12 in einer Zentralheizung
oder in einem Wasserheizsystem.
1. Brûleur à prémélange comprenant un corps de brûleur tubulaire (11) et un capuchon
d'extrémité imperméable (13), ledit capuchon d'extrémité imperméable obturant ledit
corps de brûleur tubulaire, ledit capuchon d'extrémité imperméable étant soudé audit
corps de brûleur, ledit capuchon d'extrémité imperméable présentant une surface de
capuchon d'extrémité imperméable (34), ladite surface de capuchon d'extrémité imperméable
étant au moins partiellement courbe, chaque point de ladite surface de capuchon d'extrémité
imperméable présentant un rayon de courbure R et une épaisseur de matière T, ledit
chaque R étant plus grand que 3xT.
2. Brûleur à prémélange selon la revendication 1, caractérisé en ce que ladite courbure de la surface de capuchon d'extrémité imperméable (34) est au moins
partiellement concave.
3. Brûleur à prémélange selon la revendication 1, caractérisé en ce que ladite courbure de la surface de capuchon d'extrémité imperméable (34) est au moins
partiellement convexe.
4. Brûleur à prémélange selon la revendication 1, caractérisé en ce que ladite courbure de la surface de capuchon d'extrémité imperméable (34) est au moins
partiellement concave et partiellement convexe.
5. Brûleur à prémélange selon l'une quelconque des revendications 1 à 4, ladite surface
de capuchon d'extrémité imperméable (34) présentant une zone substantiellement plate.
6. Brûleur à prémélange selon la revendication 4, ladite surface de capuchon d'extrémité
imperméable (34) présentant une zone (61) substantiellement plate, lesdits rayons
de courbure dans ladite zone substantiellement plate étant supérieurs à dix fois la
distance maximale entre deux points du bord dudit capuchon d'extrémité imperméable.
7. Brûleur à prémélange selon l'une quelconque des revendications 1 à 6, caractérisé en ce que ledit capuchon d'extrémité imperméable (13) comprend un bord inférieur (31), ledit
corps de brûleur tubulaire (11) comprenant une extrémité longitudinale (12), lesdits
bord inférieur et extrémité longitudinale étant soudés l'un à l'autre sans recouvrement.
8. Brûleur à prémélange selon l'une quelconque des revendications 1 à 7, caractérisé en ce que ledit capuchon d'extrémité imperméable (13) et ledit corps de brûleur tubulaire (11)
sont soudés l'un à l'autre par soudage au laser.
9. Brûleur à prémélange selon l'une quelconque des revendications 1 à 7, caractérisé en ce que ledit capuchon d'extrémité imperméable (13) et ledit corps de brûleur tubulaire (11)
sont soudés l'un à l'autre par soudage par points.
10. Brûleur à prémélange selon l'une quelconque des revendications 1 à 7, caractérisé en ce que ledit capuchon d'extrémité imperméable (13) et ledit corps de brûleur tubulaire (11)
sont soudés l'un à l'autre par soudage TIG.
11. Brûleur à prémélange selon l'une quelconque des revendications 1 à 10, ledit corps
de brûleur tubulaire (11) présentant une hauteur située dans la plage de 10 à 50 cm.
12. Brûleur à prémélange selon l'une quelconque des revendications 1 à 11, ledit corps
de brûleur tubulaire (11) présentant une section transversale circulaire, présentant
un diamètre situé dans la plage de 0,5 à 25 cm.
13. Utilisation d'un brûleur à prémélange selon l'une quelconque des revendications 1
à 12, dans un système de chauffage central ou dans un système de chauffe d'eau.