[0001] The present invention relates to a heat exchanger, in particular for a gas boiler
used to produce hot water, and to a gas boiler for producing hot water provided with
said heat exchanger.
[0002] The invention is particularly suitable for use in condensation boilers, to which
reference is made in the following description purely by way of example.
[0003] A gas boiler for producing hot water (for a sanitary water system and/or for a heating
system) normally comprises a gas burner and at least one heat exchanger in which the
combustion fumes produced by the burner transfer heat to circulating water.
[0004] Condensation boilers condense the steam in the combustion fumes and also transfer
the latent heat in the fumes to the water. The exchange of heat between the fumes
and the water and the condensation of the fumes can be performed in separate heat
exchangers or in a single heat exchanger which provides solely for heat exchange in
a first portion and for both heat exchange and fume condensation in a second portion.
[0005] In particular, the condensation boilers of the known type are provided with heat
exchangers comprising a casing through which the fumes flow and housing a coiled pipe
through which the water flows; the fumes flow between the turns of the pipe, over
the outer surface of the pipe and transfer heat to the water flowing along the pipe.
[0006] A known method for improving heat exchange efficiency consists of providing the outer
surface of the coiled pipe with various types of fins. However, finned pipes are relatively
complex and expensive to produce, and are not entirely satisfactory in terms of heat
exchange efficiency.
[0007] The purpose of the present invention is to provide a heat exchanger for a gas boiler
for producing hot water that overcomes the drawbacks described above in a simple and
inexpensive manner, both in terms of functionality and construction.
[0008] In particular, one purpose of the invention is to provide a heat exchanger that is
extremely efficient in terms of heat exchange and that is also simple and inexpensive
to produce.
[0009] According to the present invention a heat exchanger is produced as set forth in claim
1.
[0010] The invention will now be described in detail in the following non-limiting embodiments,
with reference to the accompanying drawings in which:
- figure 1 is a schematic and partially cross-sectional view, with some parts removed
for the sake of clarity, of a gas boiler for producing hot water provided with a heat
exchanger according to the invention;
- figure 2 is a schematic perspective view of a portion of a pipe used in the heat exchanger
of figure 1;
- figure 3 is an enlarged-scale view of a detail of the heat exchanger of figure 1;
- figure 4 is an enlarged-scale view of the detail shown inside a circle in figure 3.
[0011] In figure 1, reference number 1 indicates, as a whole, a gas boiler for producing
hot water, in particular a condensation boiler; it is, however, understood that the
invention may be applied to other kinds of boilers; the boiler 1 may be used to produce
hot water for a sanitary water system and/or to supply a heating system.
[0012] The general structure of the boiler 1 is essentially known and only the essential
components thereof are described below; the boiler 1 comprises an outer structure
2, which is of a known type and only schematically illustrated in figure 1, in which
are housed a gas burner 3, a heat exchanger 4, a conduit 5 to supply an air/gas mixture
to the burner 3, an exhaust pipe 6 for the combustion fumes produced in the burner
3, and a water circuit 7 for the water to be heated, which is only partially illustrated.
[0013] The burner 3 is arranged inside the heat exchanger 4 and generates a flame 8 which
burns the air/gas mixture supplied by the supply conduit 5; in the heat exchanger
4, the combustion fumes generated by the burner transfer heat to the water flowing
in the circuit 7. The burner 3, of a type that is substantially known, is for example
essentially cylindrical and has a cylindrical side wall provided with holes (not illustrated)
for emitting the air/gas mixture and feeding the flame 8.
[0014] The heat exchanger 4 is essentially cylindrical in shape and extends along an axis
A; the heat exchanger 4 comprises a casing 11 through which the combustion fumes flow,
a pipe 12 along which the water in the circuit 7 flows, and a baffle 13 or other equivalent
diverting means for directing the combustion fumes along a fixed path, schematically
illustrated by the arrow in figure 1, inside the casing 11.
[0015] The casing 11 comprises an essentially cylindrical side wall 14 arranged about the
axis A and two walls 15, 16 of opposite ends, essentially parallel to one another
and perpendicular to the axis A. The wall 15 supports the supply conduit 5 and the
burner 3; the wall 16 supports the exhaust pipe 6. The burner 3 extends centrally
inside the casing 11 essentially along the axis A and thus coaxially to the heat exchanger
4 and is provided with one end 17 fitted to the wall 15 and one free end 18, opposite
the fitted end 17.
[0016] The pipe 12 is arranged inside the casing 11 and is coiled about the axis A so as
to form a succession of adjacent turns 20 arranged so as to be essentially parallel
along the axis A in proximity to the side wall 14; the pipe 12 extends along a longitudinal
axis C (curved) coiled about the axis A and is provided with a side wall 21, having
an outer side surface 22 and an inner side surface 23, and two opposite ends provided
with respective fittings 25 for connecting the pipe 12 to the water circuit 7.
[0017] The coiled pipe 12 delimits inside the casing 11 a radially internal zone 26 and
a radially external zone 27 arranged coaxially in relation to one another.
[0018] The baffle 13 is arranged so as to be essentially perpendicular to the axis A in
the casing 11 and specifically in the zone 26; the baffle 13 faces the free end 18
of the burner 3 and is arranged radially inside the pipe 12; the baffle 13 divides
the zone 26 into two chambers 28, 29 aligned along the axis A; the chamber 28, adjacent
to the wall 15, houses the burner 3 and also acts as a combustion chamber; the chamber
29, adjacent to the wall 16, is connected to the exhaust pipe 6.
[0019] As shown in detail in figures 2-4, the cross-section 32 of the pipe 12 (perpendicular
to the longitudinal axis C of the pipe 12), which is preferably constant, comprises
at least one outwardly concave portion 33 and one outwardly convex portion 34 opposite
the concave portion 33.
[0020] It is however understood that the cross-section of the pipe 12 may differ from that
illustrated, for example it could be essentially round, oval, elliptical, quadrangular
or polygonal, with rounded edges and/or corners, etc., and may even not have any outwardly
concave portions.
[0021] In the example that is illustrated, each turn 20 comprises a concave surface portion
35 and a convex surface portion 36 of the surface 22 of the pipe 12, arranged on opposite
sides of a central plane P of the turn 20 essentially perpendicular to the axis A.
[0022] Adjacent turns 20a, 20b, (shown for example in figure 3) face one another parallel
to the axis A so that the concave portion 33 of one turn 20a faces the convex portion
34 of the adjacent turn 20b; thus, the concave surface portion 35 of a turn 20a also
faces the convex surface portion 36 of the adjacent turn 20b.
[0023] The turns 20 are arranged in succession along the axis A and are axially separated
by respective gaps 40 defining essentially radial channels 41 through which the combustion
fumes flow between the radially internal zone 26 and the radially external zone 27.
[0024] The outer surface 22 of the pipe 12 is longitudinally grooved (on all or part of
the surface), being provided with a plurality of longitudinal grooves 42 parallel
to one another and to the longitudinal axis C of the pipe 12.
[0025] In particular, at least the facing surface portions 35, 36, which delimit the channels
41, of adjacent turns 20 are provided with grooves 42. Adjacent turns 20 are thus
provided with respective facing surface portions 35, 36 provided with respective pluralities
of opposing longitudinal grooves 42; the grooves 42 of adjacent turns 20 provided
on the facing surface portions 35, 36 protrude radially towards one another and may
essentially be aligned with respect to one another, or staggered with respect to one
another.
[0026] The grooves 42, for example evenly spaced with respect to one another, may be arranged
solely on the facing surface portions 35, 36, and/or on other preferential surface
portions of the surface 22, for example surface portions facing the burner 3 and thus
facing the axis A, or essentially on the entire surface 22.
[0027] The grooves 42 are separated from one another by respective projecting parts 43 which
protrude from the surface 22; each projecting part 43 is essentially perpendicular
to the surface 22 and the projecting parts 43 are thus arranged radially or in a crown
about the axis A on the surface 22.
[0028] Note that the known heat exchangers comprising a coiled pipe are provided with conventional
fins the dimensions of which are generally comparable with the cross-dimensions of
the pipe; however, according to the present invention, the surface 22 of the pipe
12 is only grooved, that is, it is provided with grooves 42 the depth of which is
significantly less than the dimensions of the pipe 12; in other words, unlike with
conventional fins, the height of the projecting parts 43 that delimit the grooves
42 is significantly less than the dimensions of the pipe 12.
[0029] The depth of the grooves 42 is preferably not more than approximately 5 mm.
[0030] Each groove 42 is delimited by a pair of lateral sides 45, essentially parallel to
the longitudinal axis C of the pipe 12; in the example that is illustrated, the sides
45 converge towards a rounded base 46 of the groove 42; it is understood that the
shape of the grooves 42 may differ from that described herein and illustrated merely
by way of example. For example, the sides 45 could be essentially parallel to one
another, and could be essentially flat or even curved; the base 46 could be square-cornered,
or even essentially flat. Basically, the cross-section of the grooves may be essentially
triangular with a square-cornered or rounded vertex, essentially trapezoidal, rectangular
or generally quadrangular or polygonal, with curved sides and/or square or rounded
corners, etc., or a complex shape optimized to generate turbulence suitable to improve
heat exchange efficiency.
[0031] The grooves 42 may all be essentially identical to one another in terms of their
shape and dimensions, or may have different shapes and/or dimensions according to
the part of the surface 22 on which they are arranged.
[0032] Optionally, as illustrated by means of the dashed line and only partially in figure
3, the inner surface 23 of the pipe 12 is also longitudinally grooved (on all or part
of the surface), and is in turn provided with a plurality of longitudinal inner grooves
44 parallel to one another and to the longitudinal axis C of the pipe 12, identical
in terms of geometry and dimensions to the grooves 42. The inner surface 23 may also
be grooved (provided with grooves 44) on its entire inner perimeter or only on predefined
preferential areas.
[0033] The pipe 12 is preferably made of metal, for example aluminium; preferably, but not
necessarily, the pipe 12 is manufactured by means of an extrusion process; in this
case, the grooves 42 and/or the grooves 44 are most advantageously produced directly
during the pipe 12 extrusion process.
[0034] The boiler 1 provided with the heat exchanger 4 works in essentially the same way
as similar boilers.
[0035] The combustion fumes generated by the burner 3 in the chamber 28 flow from the chamber
28 to the radially external zone 27, between the turns 20 of the pipe 12 through the
channels 41 in a radially external direction and transfer heat to the water flowing
along the pipe 12; the combustion fumes thus flow past the baffle 13 over the side
wall 14 of the casing 11, and then flow back between the turns 20 of the pipe 12 in
a radially internal direction through the channels 41, complete the transfer of heat
to the water in the pipe 12 and then flow into the exhaust pipe 6.
[0036] The advantages of the present invention are clear from the above description.
[0037] Firstly, the heat exchanger 4 achieves high heat exchange efficiency, due to the
presence of the grooves 42 and/or of the grooves 44, which increase the heat exchange
surface, generate surface turbulence which improves heat exchange and prolong the
time for which the combustion fumes remain in contact with the side wall 21 of the
pipe 12.
[0038] Efficiency is further increased due to the particular geometry of the cross-section
32 and in particular of the channels 41 through which the combustion fumes flow.
[0039] The heat exchanger 4 is both simple and inexpensive to produce, particularly since
the pipe 12 can be obtained directly by means of an extrusion process, during which
the grooves 42, 44 can also be produced.
[0040] Lastly, it is understood that numerous modifications and variations may be made to
the heat exchanger and to the gas boiler described and illustrated herein without
departing from the scope of the attached claims.
1. Heat exchanger (4) for a gas boiler for producing hot water, comprising a casing (11)
through which combustion fumes flow and which extends along an axis (A), and a pipe
(12) along which water flows, said pipe (12) being arranged in the casing (11) and
extending along a longitudinal axis (C) coiled about the axis (A) in order to form
a succession of turns (20); the heat exchanger being characterized in that the pipe (12) has an outer surface (22) that is longitudinally grooved.
2. Heat exchanger according to claim 1, characterized in that the outer surface (22) of the pipe (12) is provided with a plurality of longitudinal
grooves (42) essentially parallel to the longitudinal axis (C) of the pipe (12).
3. Heat exchanger according to claim 2, characterized in that the grooves (42) are only arranged on preferential surface portions (35, 36) of the
outer surface (22), or essentially on the entire outer surface (22).
4. Heat exchanger according to one of the previous claims, characterized in that adjacent turns (20) are provided with respective facing surface portions (35, 36)
which are provided with respective pluralities of opposing longitudinal grooves (42).
5. Heat exchanger according to claim 4, characterized in that the grooves (42) provided on the facing surface portions (35, 36) of adjacent turns
(20) protrude radially towards one another and are essentially aligned with respect
to one another, or staggered with respect to one another.
6. Heat exchanger according to one of the previous claims, characterized in that the outer surface (22) of the pipe (12) is provided with grooves (42) having a depth
of not more than approximately 5 mm.
7. Heat exchanger according to one of the previous claims, characterized in that the pipe (12) has a longitudinally grooved inner surface (23).
8. Heat exchanger according to claim 7, characterized in that the inner surface (23) is grooved on its entire inner perimeter or only on predefined preferential parts.
9. Gas boiler (1) for producing hot water, in particular a condensation boiler, characterized in that it is provided with a heat exchanger (4) according to any one of the previous claims.