[0001] The present invention relates to a set of cold metal section bars which are convertible
into thermally-broken section bars suitable for cold door and window frames and for
thermally-broken (insulated) door and window frames.
[0002] During the course of the present description and of the claims, the expression "cold
section bars" is used to indicate section bars that are not thermally insulated while
the expression "thermally-broken section bars" stands for thermally insulated section
bars.
[0003] Various kinds of section bars are currently on the market:
a) so called cold or whole section bars, constituted by section bars made wholly of
metal, without thermal insulation;
b) so called whole section bars with a thermal screen, constituted by section bars
made wholly of metal to which insulating elements are applied, generally in plastic,
on the external part of the frame, so as to form a barrier to the exchange of heat;
c) thermally-broken or insulated section bars, comprising insulating elements interposed
between elements of external and internal metal section bars.
[0004] Thermally-broken section bars, in turn, can be of different type.
[0005] One type of thermally-broken section bar is obtained from two metal section bars,
one internal and the other external, extruded separately, that are joined together
by means of hars of insulating material inserted in specially-provided seats and then
clamped through a rolling process.
[0006] These thermally-broken section bars have several drawbacks.
[0007] Tolerances and parallelisms between the two internal and external elements are difficult
to obtain and to check, as they are section bars extruded separately, thus, easily,
imperfections occur in joining the two elements together.
[0008] Moreover, the two internal and external elements can have a non-uniform anodization
and their aging can also be non-uniform.
[0009] Another type of thermally-broken section bar is obtained from a whole metal section
bar provided with a tubular casing that connects the elements of the internal and
external metal section bars, extruded in one single piece. During the production step
of the section bars, polyurethane foam is injected into the tubular casing and the
metal walls of the tubular casing connecting the elements of internal and external
metal section bars are then removed, by means of a cutting operation, so that the
two internal and external elements remain connected together only through the injected
polyurethane foam.
[0010] This thermally-broken section bar does not have the drawbacks of the section bar
with separate internal and external elements, but it does require a laborious and
expensive manufacturing process, that cannot be executed by an assembler of door and
window frames, due to the complexity of the operations of injecting foam into the
tubular casing and of subsequently cutting the walls connecting the internal and external
section bar elements.
[0011] Attempts have been made tending to transform a cold section bar into a thermally-broken
section bar, but the results attained so far have not been satisfactory.
[0012] The object of the present invention is a set of flexible section bars constituted
by whole metal section bars, extruded in one single piece, that can be used as cold
section bars and can be converted into thermally-broken section bars with simple operations,
that may also be executed outside the production line of the section bars, thus that
can also be executed by an assembler of door and window frames when it becomes necessary
to manufacture a thermally-broken section bar, rather than a cold section bar.
[0013] Another object of the present invention is a set of section bars that have an optimum
conformation both as cold metal section bars and as thermally-broken section bars,
obtained by the transformation of the cold metal section bars.
[0014] According to the invention, the abovementioned objects are attained with a set of
cold metal section bars which are convertible into thermally-broken section bars,
particularly for door and window frames, each comprising an element of internal metal
section bar and an element of external metal section bar connected together by means
of connecting walls, characterized in that
said connecting walls are made of metal and comprise teeth linked to said elements
of internal and external section bars by means of weakening lines suitable for making
them deformable, and strips connected to said deformable teeth by means of further
weakening lines suitable for making them removable, the thickness of said strips being
less than the thickness of said teeth,
said elements of internal and external section bar are provided with longitudinal
recesses each formed by one of said deformable teeth, by at least one rigid ridge
substantially parallel to said teeth and by a back wall connecting one tooth and one
ridge, and
said element of external section bar comprises at least one abutment fin connected
to at least one of said back walls by means of a connecting tang protruding outward,
so as to form a chamber for aeration and for collection of water in the proximity
of said fin and to minimize the transmission of deformations from said teeth to said
fin.
[0015] According to a preferred embodiment, said element of internal section bar is provided
with at least two longitudinal recesses arranged at a distance greater than that at
which two corresponding longitudinal recesses of the element of external section bar
are arranged and said removable strips are inclined with respect to said back wall,
converging toward said element of external section bar, so as to carry any water and
condensate toward said collection chamber.
[0016] According to another preferred embodiment, said abutment fin has a substantially
convex wall, so that deformations of said teeth involve only variations in the curvature
of the fin.
[0017] The abovementioned objects are also attained with a set of thermally-broken section
bars, particularly for door and window frames, each comprising an element of internal
metal section bar and an element of external metal section bar connected together
by means of insulating bars housed in matching longitudinal recesses of an element
of internal section bar and of an element of external section bar, characterized in
that
said longitudinal recesses are each formed by a deformable tooth, by at least one
rigid ridge substantially parallel to said tooth and by a back wall connecting one
tooth and one ridge, said tooth being connected to the respective element of internal
and external metal section bar by means of a weakening line suitable for making it
easier to fold them over extremities of said insulating bars, so as to clamp them
in said recesses leaving an air space between them, and
said element of external section bar comprises at least one abutment fin connected
to at least one of said back walls by means of a connecting tang protruding outward,
so as to form a chamber for aeration and for collection of water in the proximity
of said fin and to minimize the transmission of deformations from said tooth to said
fin.
[0018] Preferably, said insulating bars are arranged inclined with respect to said back
wall, converging towards said element of external section bar, so as to carry any
water and condensate toward said collection chamber.
[0019] With the set of section bars according to the invention there is the great advantage
of being able to produce unified section bars, that have an optimized conformation
as regards weight, strength and performance, both when they are utilized as cold section
bars and when they are utilized, after an easy and simple conversion, as thermally-broken
section bars.
[0020] In fact, the transversal resistant cross-section of the cold section bars is dimensioned
so that a reduced resistant cross-section of the removable strips, due to a lesser
thickness than that of the teeth, is substantially compensated by that of the rigid
ridges. The weight of the material that is removed and discarded in the case of transformation
into thermally-broken section bars is thus reduced to a minimum.
[0021] In thermally-broken section bars, the ridges, together with the teeth, form longitudinal
recesses suitable for housing insulating bars, keeping them at a distance from one
another, so that they remain separated by an air space and an effective thermal insulation
is obtained.
[0022] Moreover, the operations of conversion can also be executed outside the plant that
manufactures the section bars, by an assembler of door and window frames when it becomes
necessary to install a thermally-broken door and window frame. The conversion requires
very simple interventions, that consist in the insertion of insulating bars in the
matching longitudinal recesses of the elements of internal and external section bar,
in the removal of the strips cutting them along their respective weakening lines and
in folding the teeth with respect to the respective weakening lines, so as to firmly
fasten ends of the insulating bars in the corresponding longitudinal recesses.
[0023] Another advantage of the set of unified section bars, made according to the invention,
is represented by the possibility of carrying toward draining holes water and condensate
that may infiltrate inside the door and window frames both in the case of cold door
and window frames and in the case of thermally-broken door and window frames. Carrying
is executed through the inclined arrangement of the removable strips, converging toward
the element of external section bar in cold section bars, and through the inclined
arrangement of the insulating bars, that also converge toward the element of external
section bar in thermally-broken section bars.
[0024] Moreover, the substantially convex shape of the abutment fin introduces a good margin
of tolerance against possible deformations caused by the bending of the teeth, because
the deformations involve only variations in the curvature of the fin, that can be
discerned by the naked eye only with difficulty. Thus the convex shape is also favourable
from an aesthetic viewpoint.
[0025] Further advantages of the set of section bars according to the invention are represented
by the low costs of extrusion and by the substantial reduction of storage stocks.
In addition, parallelisms and tolerances between the two internal and external elements
of the thermally-broken section bars are easy to obtain and to check, risks of imperfections
in joining the two elements together are reduced and their anodization and aging are
uniform.
[0026] Features and advantages of the invention will now be illustrated with reference to
embodiments of the invention represented as non-limiting examples in the enclosed
figures, wherein:
Figs. 1, 3, 5, 7, 9 and 11 are top plan views of a first, second, third, fourth, fifth,
sixth cold metal section bar, respectively, according to the invention;
Figs. 2, 4, 6, 8, 10 and 12 are top plan views of a first, second, third, fourth,
fifth, sixth thermally-broken section bar, respectively, according to the invention,
obtained from the section bars of Figs. 1, 3, 5, 7, 9 and 11, respectively;
Fig. 13 shows on an enlarged scale strips, teeth and insulating bars of the section
bars of Figs. 1-12;
Figs. 14 and 15 are partial views in a transversal cross-section of door and window
frames with movable panes made with the cold section bars of Figs. 1 and 3 and with
the thermally-broken section bars of Figs. 2 and 4, respectively;
Figs. 16 and 17 are partial views in a transversal cross-section of door and window
frames with several movable panes made with the cold section bars of Figs. 3 and 7
and with the thermally-broken section bars of Figs. 4 and 8, respectively;
Fig. 18 is a partial view in a transversal cross-section of a frame made with cold
section bars of Fig. 3 and provided with a cross-beam formed by the cold section bar
of Fig. 11;
Fig. 19 is a cross-sectional view in an enlarged scale of a seat and of a stem of
a screw of the cross-beam of Fig. 18.
[0027] There is indicated as a whole with 1 in Fig. 1 a cold metal section bar having a
transversal cross-section substantially in the shape of a "Z", made by extrusion,
preferably in an aluminium alloy. The section bar 1 comprises an element of internal
section bar 7 and an element of external section bar 8 connected by means of connecting
walls 9. The connecting walls 9 are formed by deformable longitudinal teeth 11 and
by removable longitudinal strips 12 having a thickness that is less than the thickness
of the teeth 11. The strips 12 are connected to the teeth 11 by means of longitudinal
weakening lines 13 suitable for making it easier to cut them; the teeth 11 are connected
to the elements of internal section bar 7 and of external section bar 8 by means of
weakening lines 14 suitable for making it easier to bend them, as also shown in Fig.
13.
[0028] The elements of internal section bar 7 and of external section bar 8 are provided
with rigid ridges 15 substantially parallel to the teeth 11, that with back walls
16 and with the teeth 11 form longitudinal recesses 18. The recesses 18 belonging
to the element of internal section bar 7 are arranged at a distance greater than that
at which the recesses 18 belonging to the correspondng element of external metal section
bar 8 are arranged and, thus, the strips 12 are inclined with respect to the back
walls 16 and converge toward the element of external section bar 8, so as to carry
water and condensate toward a chamber 19 for aeration and collection of water and
condensate.
[0029] The element of external section bar 8 comprises an abutment fin 21 formed by a substantially
convex wall, so that deformations of the teeth 11 involve only variations in the curvature
of the fin. The fin 21 is provided with a "C"-shaped seat 22 suitable for housing
a seal and an alignment bracket, not shown. The fin 21 is linked to the back walls
16 by means of a connecting tang 23 protruding outward, with which it forms the abovementioned
chamber 19, so as to minimize the transmission of deformations from the teeth 11 to
the fin 21. With the fin 21 there is integral a resting tang 31.
[0030] The element of internal section bar 7 is formed by a tubular casing 24, having a
substantially rectangular transversal cross-section, with which there is integral
an abutment fin 25, provided with a C-shaped seat 26 for a seal. In the tubular casing
24 there is a C-shaped seat 27 suitable for housing a hinged element or a glass-holding
section bar, a U-shaped seat 28, suitable for housing a seal or a self-tapping screw,
as shown in Fig. 19.
[0031] From the section bar 1 it is possible to obtain a thermally-broken section bar, similar
to that indicated in Fig. 2 as a whole with 10, wherein the parts like to those of
section bar 1 are indicated with the same reference numbers.
[0032] In order to make the thermally-broken section bar 10, a pair of insulating bars 29
is inserted into the matching recesses 18 of the section bar elements 7 and 8, as
shown in Fig. 13, and the strips 12 are then cut from the teeth 11, so as to divide
the element of internal section bar 7 from the element of external section bar 8.
Moreover, the deformable teeth 11 are folded with respect to the weakening lines 14,
so as to clamp the extremities of the insulating bars 29 in the recesses 18, as shown
in Fig. 2, leaving an air space 17 between the bars. The bars 29 are inclined like
the strips 12, converging toward the element of external section bar 8 and their extremities
29a have a trapeze-like shape, on which the teeth 11 are folded. The insulating bars
29 are preferably made of polyamide reinforced with glass fibres.
[0033] The section bars 1 and 10 have an optimized conformation both as cold section bars,
and as thermally-broken section bars, as regards weight, resistance, performance.
In fact the transversal cross-section of the cold section bars resistant to operational
stresses is obtained by reducing the resistant cross-section of the removable strips,
as their thickness is less than that of the teeth, and substantially compensating
it with that of the rigid ridges. The weight of the material that is removed and discarded
in the case of the conversion in thermally-broken section bars is thus very small.
In the thermally-broken section bar 10 the pair of insulating bars 29, separated by
an air space 17, allows an effective thermal insulation to be obtained.
[0034] When it becomes necessary to install a thermally-broken section bar, an assembler
of door and window frames can convert the cold section bar 1 into the thermally-broken
section bar 10 with few and simple operations, thus outside the production line of
the section bars.
[0035] The unification of the section bars, as has been said, allows extrusion costs and
storage charges to be reduced to a minimum. Other advantages are represented by the
easy obtaining and checking tolerances and parallelisms between the two elements of
internal and external section bar 7 and 8 of the thermally-broken section bars, by
the minimization of risks of imperfections in joining the two internal and external
elements together and by the uniformity of treatment of surface finishing and of aging
of the two elements.
[0036] There is shown in Fig. 3 a cold metal section bar 2 having a substantially Z-shaped
transversal cross-section, wherein the parts like or corresponding to those of the
section bar 1 of Fig. 1 are indicated with the same reference numbers.
[0037] The abutment fin 21 of the section bar 2 is provided with the resting tang 31 and
with a bent extremity 32. The tubular casing 24 has a C-shaped seat 33 suitable for
housing a hinge element or for joining up with another section bar, and a resting
tang 34.
[0038] There is shown in Fig. 4 a thermally-broken section bar 20 obtained from the section
bar 2 with the same operations described earlier with reference to the conversion
of the cold section bar 1 into the thermally-broken section bar 10. The parts like
to those of the section bars 2 and 10 are indicated with the same reference numbers.
[0039] There are shown in Figs. 5 and 6 a cold metal section bar 3 and a thermally-broken
section bar 30 obtained from the section bar 3 having a substantially Z-shaped transversal
cross-section. In the section bars 3 and 30 the parts like or corresponding to those
of the section bars 2 and 20 are indicated with the same reference numbers. The element
of external section bar 8 has a tubular casing 35 to which there are integral the
tang 23 and two rigid ridges 15 that, with the back walls 16 and the deformable teeth
11, form the recesses 18.
[0040] There are shown in Figs. 7 and 8 a cold metal section bar 4 and a thermally-broken
section bar 40 obtained from the section bar 4 having a substantially inverted L-shaped
transversal cross-section. The parts like or corresponding to those of the section
bars 1, 10 and 3, 30 are indicated with the same reference numbers. With the tubular
casing 24 there are integral resting tangs 36 suitable for engaging with another section
bar and a double-C seat 37 for a hinge element, for a clamping rod (bolt) of a movable
part and for a supplementary lock match. In the tubular casing 35 there is a resting
seat 38 suitable for engaging with another section bar.
[0041] There are shown in Figs. 9 and 10 a cold metal section bar 5 and a thermally-broken
section bar 50 obtained from the section bar 5 having a substantially inverted L-shaped
transversal cross-section. The parts like or corresponding to those of the section
bars 7 and 8 are indicated with the same reference numbers. With the tubular casing
35 there is integral a bracket tang 39.
[0042] There are shown in Figs. 11 and 12 a cold metal section bar 6 and a thermally-broken
section bar 60 obtained from the section bar 6 having a substantially T-shaped transversal
cross-section. The parts like or corresponding to those of the section bars 1 and
10 are indicated with the same reference numbers.
[0043] In Fig. 14 there is represented diagrammatically a cold door and window frame with
a side hung pane comprising a fixed frame 41 made with section bars 1 and a movable
frame 42 made with section bars 2. There is indicated with 43 a sealing gasket housed
in the seat 28, that makes abutment against the tang 34 of the section bar 2.
[0044] In Fig. 15 there is represented diagrammatically a thermally-broken door and window
frame with a side hung pane comprising a fixed frame 44 made with section bars 10
and a movable frame 45 made with section bars 20.
[0045] In Fig. 16 there is represented diagrammatically a cold door and window frame with
several movable panes comprising a fixed frame 46 made with section bars 2 and movable
frames 47 and 48 made with section bars 4 and 2, respectively.
[0046] In Fig. 17 there is represented diagrammatically a thermally-broken door and window
frame with several movable panes comprising a fixed frame 49 made with section bars
20 and movable frames 51 and 52 made with section bars 40 and 20, respectively.
[0047] In Fig. 18 there is represented diagrammatically a frame formed by section bars 2,
provided with a cross-beam formed by the section bar 6, joined to the vertical section
bars 2 by means of self-tapping screws like that indicated with 53. The screws 53
pass through holes 54 of a section bar 2 and are screwed into the U-shaped seats 28
of the section bar 6, as also shown in Fig. 19.
1. Set of cold metal section bars (1; 2; 3; 4; 5; 6) which are convertible into thermally-broken
section bars (10; 20; 30; 40; 50; 60), particularly for door and window frames, each
comprising an element of internal metal section bar (7) and an element of external
metal section bar (8) connected together by means of connecting walls (9), characterized
in that
said connecting walls (9) are made of metal and comprise teeth (11) linked to said
elements of internal and external section bars (7, 8) by means of weakening lines
(14) suitable for making them deformable, and strips (12) connected to said deformable
teeth (11) by means of further weakening lines (13) suitable for making them removable,
the thickness of said strips (12) being less than the thickness of said teeth (11),
said elements of internal and external section bars (7, 8) are provided with longitudinal
recesses (18) each formed by one of said deformable teeth (11), by at least one rigid
ridge (15) substantially parallel to said teeth (11) and by a back wall (16) connecting
one tooth (11) and one ridge (15), and
said element of external section bar (8) comprises at least one abutment fin (21)
connected to at least one of said back walls (16) by means of a connecting tang (23)
protruding outward, so as to form a chamber (19) for aeration and for collection of
water in the proximity of said fin (21) and to minimize the transmission of deformations
from said teeth (11) to said fin (21).
2. Set of section bars according to claim 1, characterized in that said element of internal
section bar (7) is provided with at least two longitudinal recesses (18) arranged
at a distance greater than that at which two corresponding longitudinal recesses (18)
of the element of external section bar (8) are arranged and said removable strips
(12) are inclined with respect to said back wall (16), converging toward said element
of external section bar (8), so as to carry any water and condensate toward said collection
chamber (19).
3. Set of section bars according to claim 1, characterized in that said abutment fin
(21) has a substantially convex wall, so that deformations of said teeth (11) involve
only variations in the curvature of the fin (21).
4. Set of section bars according to claim 1, characterized in that with said element
of internal section bar (7) there is integral at least one U-shaped seat (28), suitable
for housing a seal (43) or a self-tapping screw (53).
5. Set of thermally-broken section bars (10; 20; 30; 40; 50; 60), particularly for door
and window frames, each comprising an element of internal metal section bar (7) and
an element of external metal section bar (8) connected together by means of insulating
bars (29) housed in matching longitudinal recesses (18) of an element of internal
section bar (7) and of an element of external section bar (8), characterized in that
said longitudinal recesses (18) are each formed by a deformable tooth (11), by
at least one rigid ridge (15) substantially parallel to said tooth (11) and by a back
wall (16) connecting one tooth (11) and one ridge (15), said tooth (11) being connected
to the respective element of internal and external metal section bar (7, 8) by means
of a weakening line (14) suitable for making it easier to fold them over extremities
(29a) of said insulating bars (29), so as to clamp them in said recesses (18) leaving
an air space (17) between them, and
said element of external section bar (8) comprises at least one abutment fin (21)
connected to at least one of said back walls (16) by means of a connecting tang (23)
protruding outward, so as to form a chamber (19) for aeration and for collection of
water in the proximity of said fin (21) and to minimize the transmission of deformations
from said tooth (11) to said fin (21).
6. Set of section bars according to claim 5, characterized in that said insulating bars
(29) are arranged inclined with respect to said back wall (16), converging towards
said element of external section bar (8), so as to carry any water and condensate
toward said collection chamber (19).
7. Set of section bars according to claim 5, characterized in that said abutment fin
(21) has a substantially convex wall, so that deformations of said tooth (11) involve
only variations in the curvature of the fin (21).
8. Set of section bars according to claim 5, characterized in that with said element
of internal section bar (7) there is integral at least one U-shaped seat (28), suitable
for housing a seal (43) or a self-tapping screw (53).