Indian Patents. 219065:"A HEAT EXCHANGE DEVICE "

Title of Invention	"A HEAT EXCHANGE DEVICE "
Abstract	A heat exchanger device (1) comprising at least one fin (3) provided witlt means for blowing a fluid characterized in that the blowing means consist of at least one of the walls (4, 5) of Said fin (2) said wall (4, 5) having open porosity.

Full Text	- 1 - The present invention relates to improvements made to fib rising booths intended for the fabrication of glass filaments. It will he recalled that a fiberisdng booth is, in a way known per se, made up of at least one bushing pierced with a plurality of holes through which molten gla3s flows to form a web of glass filaments. More specifically, the present invention is aimed at a heat exchanger device designed to be positioned underneath the bottom of the bushing the latter being itself situated within the fiberizing booth. Now, operating a fiberising booth is actually a particularly complex process in the course of which numerous physico-chemical parameters are constantly monitored, in this respect, it is pointed out in particular that the temperature at the bottom of the bushing is one of the most important parameters in obtaining an optimum filament as it is actually this that governs the viscosity of the glass. To this end, it is therefore necessary to cool the underside of the bushing so as to set the temperature of the cones of glass fibers. Furthermore; other phenomena influence the temperature of the cone of filaments and require the incorporation of heat exchanger devices underneath the bottom of the bushing. Thus, in a fiberizing booth, the movement of the filaments carries along the air trapped in the web toward the outside of the booth, anil this causes air to be sucked from the outside toward the inside of the web underneath the bottom of the bushing. It is necessary to supply fresh air to compensate for this lack of air underneath the bottom of the bushing so as to ensure uniform heat exchange with the glass cones and the bottom of the bushing, thus making it possible to improve the uniformity of the filament thickness. A first family of known heat exchanger devices which are able to influence the temperature at the -2- bottom of the bushing but do not perform the air supply function consists of an array of fins farming combs. Each of the fins is made of a bar made of a material with excellent heat exchange coefficients (particularly in terms of conduction}, one of the free ends of each bar being connected to a manifold secured to the fiberizing booth at the underside at the bushing and provided with a heat transfer circuit thus allowing the heat energy extracted by conduction to be taken away, the glass filaments passing between the gaps at the comb. Although, it meets the current requirements in terms of the Cooling of the underside of the bushing, this first family of devices cannot be read across to bushings with a high throughput. Problems associated with the geometry of the fiberiaing booths (the dimensions of the area of the booth intended to accommodate the bushing are set by construction) make it difficult to envisage mounting these devices on bushings comprising a great many (several thousand] orifices, this problem being all the more exacerbated when, in addition, additional air needs to be supplied, something that is essential in high-throughput bushings. Also known is a second family of heat exchanger devices which perform both the function of cooling the cone of glass and the function of supplying air. These are blowing fins. The latter are also configured as a comb and situated underneath the bottom of the bushing, the glass filaments passing through the gaps between the rows of fins. Cooling fins ore known from patents US 3 150 946 and Us 3 345 147. Now, according no those documents, the fins are made from a metal gauze which is folded into a tube to form the fin. However, folding deforms some of the holes in the mesh. These are then no longer the same size and the flow generated by blowing is no longer uniform. - 3 - Patent US 5 693 us discloses a suction fin device that increases the convecced heat exchange underneath the bottom of the bushing, The sucking of air through the fins generates uniform flow under the bushing and improves the stability of the fiberizing. By contrast, the sucking-in of air through the fins encourages the deposition of airborne substances (dust) of the surface of the fins and the ingress of dust and water droplets into the web, and these are factors known to contribute to the instability of the web. Patents US 4 214 884 and US 4 310 602 relate to fins made from a thin sheet of solid nickel. The holes; with identical and precise dimensions, are obtained using a photochemical or electrolytic process. In spite of the care taken in manufacturing these holes, their density is not enough to guarantee the optimum air flow conditions (uniformity) that will guarantee the stability of the web of glass filaments. The present invention therefore aims to alleviate these disadvantages by proposing a heat exchanger device intended to be positioned underneath the bottom of a bushing, particularly a high-throughput bushing, this heat exchanger device being designed ta guarantee optimum fiberizing conditions for the web of filaments passing through said bushing. To this end, the heat exchanger device that is the subject of the invention, comprising at least one fin provided with means for blowing a fluid, is characterized in that the blowing means are uniform and consist of at least one of the walls of said fin, said wall having open porosity. By virtue of these arrangements it is possible to obtain optimum cooling of the cone of glass leaving the bottom of the bushing using a convection movement resulting from the blowing of the fluid. In preferred embodiments of the invention recourse may also possibly be had to one and/or other of the following treasures; - 4 - - the open porosity of the wall is between 5 and 30% and preferably between 10 and 25% and more preferably still between 15 and 20%, - the fin is of parallelepipedal overall shape and tubular cross section and has a permeability measured with air at a pressure of 0.5 bar and at 0°C lying in the range from 200 to 1500 Sm2/h/m2, particularly lying in the range from 300 to 600 Sm2/h/m2, and preferably lying in the range between 500 and 600 Sm2/h/m2 , - the blowing fluid velocity field is symmetric across the open porosity wall, - at least one of the walls of the heat exchanger device is obtained by sintering a metal powder, - the metal powder is based on a mixture of powdered stainless steel, brass and nickel, with a particle size smaller than 100 µm and preferably with a particle size lying within the range from 10 to 80 µm, - the porosity of the fin based on metal powder is Of the order of 17%, - at least one of the walls of the heat exchanger device is obtained by laminating a metal gauze, - the lamination comprises 3 to 13, particularly 3 to 6, layers of metal gauze, - the fluid is air at a pressure of between 0.1 and 6 bar, preferably between 0.2 and 4 bar, - the blowing fluid results from the vaporization within the fin of a fluid that was initially in the liquid state, - the heat exchanger device is provided with an auxiliary cooling circuit. other features and advantages of the invention will become apparent in the course of the following description of one of its embodiments, given by way of non-limiting example with reference to the attached drawings, In the drawings. - Figure 1 is a perspective view of a heat exchanger device according to the invention. - Figure 2 is a curve illustrating the change in - 5 - throughput of a bushing as a function of the increase in the set point temperature of the bushing, and for various cooling air flow rates through the fin, - Figure 3 is a curve illustrating the change in thennal power likely to be removed by a blowing fin as a function of the blowing fluid flow rate and as a function of the temperature difference between a point on the fin and the blown air. - Figures 4 and 5 are photographs illustrating the change in shape of the cone for various blowing fluid temperatures and flow rates, for two different positions of the cone on the fin. figure 1 depicts the heat exchanger device 1 according to the invention. This device essentially comprises a plurality of fins 2 (to make the drawing essiar to understand, just two fins have been depicted) and a manifold 3. Each of the fins, at one of its free ends, is secured by known means (welding, brazing, banding) to one of the walls of the manifold so as to form a comb in this particular embodiment. It goes without saying that this heat exchanger device may adopt different configurations other than that of a comb; it may thus be in the form of a frame or portion of a frame incorporating said fins. This heat exchanger device is intended to be positioned underneath and near the bottom of a bushing in a fiberising booth. The spacing between the fins corresponds roughly to the separation of the fiberizing nozzles situated at the bottom of the bushing so that the filaments of molten glass pass more or less in a plane positioned such that it is coplanar with and equidistant between two juxtaposed fins. Each fin is of roughly parallelepipedal shape with a tubular cross section and has short and long walls 4, 5 parallel to one another in pairs, the long walls 4, 5, however, being intended to face the filaments. In the example depicted in figure 1, the fin is of rectangular cross section and the interior passage 6 - 6 - defined between the walls 4, 5 of the fin allows a compressed blowing fluid (such as air or nitrogen for example) to paas. This blowing fluid is subjected beforehand to a treatment to remove any harmful particles which might tend to clog the pores of the fin (air from which oil and dust have been removed) . The blowing fluid may also result from the vaporization of a fluid initially in the liquid state (water, alcohol, ethylene glycol, acetone, this fluid being used pure or as a mixture). this vaporization taking place within che fin: this type of blowing fluid is advantageous because it makes it possible to use the latent heat of vaporization of the fluid. Each of the passages of each of the fins is connected to the manifold when the comb is produced, the comb itself being provided at the manifold with a device for connection to the blowing fluid distributed to the fiberizing booth. According to a first embodiment of the invention, the fin is obtained by sintering a metal powder, particularly a mixture of powdered stainless steel, brass and nickel, the parcicle size of which is smaller than 100 µm and preferably lies in the range from 10 to 80 µm. The open, porosity sought with this type of powder is in the range between 5 and 30% and preferably between 10 and 25% and more preferably still between 15 and 20% and more or less around 17%. The thickness of the tubular walls of the fin is more or less, around l mm. using these fins it has been possible to measure, across each to the long faces of the fin, a permeability to air measured at 0.5 bar and 0°C in the range from 300 to 1500 Sm2/h/m2, particularly in the range from 300 to 800 Sm2/h/m2 and preferably in the range from 500 to 600 Sm2/h/m2, which represents flow speeds of between 0.08 and 0.2 m/s in the case of the first range of permeability values. The operating pressure of the fin and therefore of the comb which - 7 - incorporates at least one of these fins is between 0-1 and 6 bar, preferably between 0.2 and 4 bar. According to a second embodiment, the fin is obtained by laminating a metal gauze, between at least 3 and 18 layers, particularly between at lease 3 and 6 layers of gauze assembled by compression or by sintering. The mesh size of the gauze lies more or less in the range from 1 to 30 µm. The open porosity sought with this lamination of metal gauze lies in the range from 5 to 30 % and preferably between 10 and 25% and more preferably still between 15 and 20%. Likewise, using these fins, it has been possible to measure on each of the long faces of the fin a permeability to air at 0.5 bar and at 0°C in the range from 300 to 1500 Sm2/h/m2, particularly in the range from 300 to 800 Sm2/h/m2, preferably in the range from 500 to 600 Sm2/h/m2 which represents flow speeds of between 0.08 and 0.2 m/S (in the case of the first range of permeability values) . The operating pressure of the fin and therefore of the comb incorporating at lease one of these fins is between 0.1 and 6 bar, preferably between 0.2 and 4 bar. Using this method of fabrication it has been possible to determine a certain number of characteristics regarding the flow of the bloving fluid through each side of the long wills, of the fin. Hemce, Figure 2 shows the change in throughput of the bushing as a function of the increase in the set point temperature of the bottom of the bushing for various blowing fluid flow rates through a wall of the fin. The data relating to the bushing illustrated in Figure 5 et seq, are given by way of indication, the bushing in question being a laboratory bushing fed with alkali resistant glass cullor. The chroughpic of the bushing increases progressively as the pushing set point temperature increases. At the maximum temperature (1475oC that the - 8 - bushing can withstand, by adjusting the blowing flow rate a maximum bushing throughput of 47.2 kg/day is observed. This is 211 higher than the maximum throughput that can be achieved with conventional fins (39.1 kg/day) , The gain in throughput using the blowing fins is therefore very great. It should the pointed out that this maximum throughput is limited rather by the maximum set point temperature of the bushing (1475°C) at which temperature the alloy of which the pushing is made melts. The increase in the throughput of the pushing is not only dependent on the temperature of the blowing fluid, which provides cooling of the fins by convection, when the blowing fluid passes through the porous walls of the fins, the fresh blown fluid (entering the fins at 20°C) efficiently coals the fins and is able to keep the fin temperature relatively low dependent an the blowing flow rate. This low temperature of the blowing fins allows at the seme time an increase in the radiation heat exchange between the eones and the blowing fins. In order to give an idea of the cooling capability of the blowing fins, Figure 3 sets out the thermal power that can be removed by a blowing fin as a function of the blowing fluid flow rate, assuming an air temperature around the cones of 100oC. 200oC and 300oC, respectively. It can be pointed out that, if a fin blows a blowing fluid (in this instance air) at a flow rate of 5 m3/h, it is able to remove 130 W at 100°C, 280 W at 200oC and 450 W at 300oC. This data should be compared with the cooling capability of a fin known from the prior art, the latter cooling capability being limited to around 100 watts. Although increasing the throughput of a bushing is one of the users' main objectives it is nevertheless important to loss sight of the fact that this increase must not be had at the expense of the stability of the bushing, and mainly the stability of - 9 - the cones formed underneath the bottom of the bushing. Now, ccne stability is dependent on the cone temperature, this temperature itself being dependent on the flow rate of the blowing fluid and on its homogeneity. As can be seen in Figures 4 and 5, it is observed that when the set point temperature increases the ccne depicted in Figure 4 becomes increasingly hot. It progressively regains its volume and becomes increasingly straight. In the case of the cone depicted in Figure 5, the blowing by the fins is more gentle and the cone is wider. when the set point temperature increases, the cone enlarges and begins to spill over around the nozzle. Upwards of 1465oC the air flow rate has to be increased in order to stabilise the fiberizing, An extremely advantageous phenomenon is observed: the cone is very stable and there is practically no longer any of the pulsation of the cone that is found with fins of the prior art. Fiberizing can be achieved stably even when the cone spills over around the nozzle. When the cone is extremely hot, pulsation reappears and a small increase in blowing is immediately able to calm this instability. In addition, during tests, it was found that the shape of the cones could very easily and very flexibly be varied by altering the flow rate blown through the fins. This offers the advantage of a great potential for adjusting the thickness of the filament. Of course, other embodiments not depicted in the figures may be conceived of particularly in terms of the shapes, cross sections and outlines of the fins. Likewise, in terms of the heat exchanger device and according to an alternative form, also not depicted in the figures, provision is made for a cooling circuit to be incorporated in the manifold in order to remove additional heat energy by circulating a heat transfer fluid (such as water for example). The invention described above offers numerous - 10 - advantages: • It increases the cooling of the cone of glass and the. bottom of the bushing by the blowing of the fins. This makes it possible to widen the fiberizing temperature range. Fiberising becomes less critical and more stable; • It avoids the deposition of airborne substances on the surfaces of the fins by blowing. It makes it possible to provide fins that are more efficient and more economical for the fiberizing of glass filaments. The production of filaments can thus mainly or entirely dissociate itself from the disruption of periodic cleaning of the fins, thus improving productivity; • It provides fins the heat absorption rate of which can be adjusted, allowing optimum heat absorption under all operating conditions; • It supplies an additional means for precisely adjusting the thickness of the filaments by adjusting the blowing pressure; • It immediately, using fresh air blown through the fins, compensates for the air sucked out of the fiberizing region by the drawing of the filaments, making it possible to reduce ox prevent the ingress of air from the outside toward the inside of the web of filaments in this sensitive region. Fiberizing can thus dissociate itself from the effects of turbulent or transient disturbances in the flow of air outside the web of filaments (for example: the movement of dust). The air flow conditions in the fiberizing region become more stable and easier to control. • with uniform and homogeneous blowing fins it is therefore possible to fiberize at a higher temperature and to reduce the fiberizing tension while at the same time maintaining the stability of the bushing. - 11 – CLAIMS I. A heat exchanger device (1) comprising at least one fin (2) provided with means for blowing a fluid. characterized in that the blowing means are uniform and consist of at lease one of the walls (4,5) of said fin (2), said wall (4, 5) having open porosity. 2. Heat exchanger device (1) as claimed in claim 1, characterised in that the open porosity of the wall (4, 5) is between 5 and 30% and preferably between 10 and 25% and wore preferably still between 15 and 20%. 3. Heat exchanger device (1} as claimed in one of claims 1 and 2, characterized in that the fin (2) is of parallelepipedal overall shape and tubular cross section and has a permeability measured with air at a pressure of 0.5 bar and at OoC lying in the range from 300 to 1500 Sm2/h/m2 , particularly lying in the range from 300 to 800 Sm2/h/m2 4. The heat exchanger device (1) as claimed in claim 3, characterized in that the permeability measured with air at a pressure of 0.5 bar and at 0°C lies in the range from 500 to 600 Sm2/h/m2 5. The heat exchanger device (1) as claimed in one of claims 1 to 4, characterized in that the- between fluid velocity field is symmetric across the open porosity wall. 6. The heat exchanger device as claimed in one of claims 1 to 5. characterized in that at least one at the walle (4, 51 of the heat exchanger device is obtained by sintering a metal powder. 7. The heat exchanger device (1) as claimed in claim 6, characterized in that the metal powder is based on a mixture of pawdered stainless steel, brass and nickel, with a particle size smaller than 100 µm and preferably with a - 12 - particle size lying within the range from 10 to 80 µm. 8. The heat exchanger device (1) as claimed in claim 7. characterized in that the open porosity is of the order of 17%. 9. The heat exchanger device (1) as claimed in one of claims 1 to 5, characterized in chat at least one of the walls of the heat exchanger device is obtained by laminating a metal gauze. 10. The heat exchanger device (1) as claimed in claim 9, characterized in that the lamination comprises 3 to 18, particularly 3 to 6, layers of metal gauze. 11. The heat exchanger device (l) as claimed in any one of the preceding claims, characterised ill that the fluid is air at a pressure of between 0.1 and 6 bar, preferably between 0.2 and 4 bar 12. The heat exchanger device (l) as claimed in any one of claims 1 to 10, characterized in that the blowing fluid results from the vaporization within the fin (2) of a fluid that was initially in the liquid state. 13. The heat exchanger device (l) as claimed in any one of the preceding claims, characterized in that the heat exchanger device is provided with an auxiliary cooling circuit. A heat exchanger device (1) comprising at least one fin (3) provided witlt means for blowing a fluid characterized in that the blowing means consist of at least one of the walls (4, 5) of Said fin (2) said wall (4, 5) having open porosity.

Full Text

- 1 -
The present invention relates to improvements made
to fib rising booths intended for the fabrication of
glass filaments. It will he recalled that a fiberisdng
booth is, in a way known per se, made up of at least
one bushing pierced with a plurality of holes through
which molten gla3s flows to form a web of glass
filaments.
More specifically, the present invention is aimed
at a heat exchanger device designed to be positioned
underneath the bottom of the bushing the latter being
itself situated within the fiberizing booth.
Now, operating a fiberising booth is actually a
particularly complex process in the course of which
numerous physico-chemical parameters are constantly
monitored, in this respect, it is pointed out in
particular that the temperature at the bottom of the
bushing is one of the most important parameters in
obtaining an optimum filament as it is actually this
that governs the viscosity of the glass.
To this end, it is therefore necessary to cool the
underside of the bushing so as to set the temperature
of the cones of glass fibers.
Furthermore; other phenomena influence the
temperature of the cone of filaments and require the
incorporation of heat exchanger devices underneath the
bottom of the bushing.
Thus, in a fiberizing booth, the movement of the
filaments carries along the air trapped in the web
toward the outside of the booth, anil this causes air to
be sucked from the outside toward the inside of the web
underneath the bottom of the bushing. It is necessary
to supply fresh air to compensate for this lack of air
underneath the bottom of the bushing so as to ensure
uniform heat exchange with the glass cones and the
bottom of the bushing, thus making it possible to
improve the uniformity of the filament thickness.
A first family of known heat exchanger devices
which are able to influence the temperature at the

-2-
bottom of the bushing but do not perform the air supply
function consists of an array of fins farming combs.
Each of the fins is made of a bar made of a material
with excellent heat exchange coefficients (particularly
in terms of conduction}, one of the free ends of each
bar being connected to a manifold secured to the
fiberizing booth at the underside at the bushing and
provided with a heat transfer circuit thus allowing the
heat energy extracted by conduction to be taken away,
the glass filaments passing between the gaps at the
comb.
Although, it meets the current requirements in
terms of the Cooling of the underside of the bushing,
this first family of devices cannot be read across to
bushings with a high throughput. Problems associated
with the geometry of the fiberiaing booths (the
dimensions of the area of the booth intended to
accommodate the bushing are set by construction) make
it difficult to envisage mounting these devices on
bushings comprising a great many (several thousand]
orifices, this problem being all the more exacerbated
when, in addition, additional air needs to be supplied,
something that is essential in high-throughput
bushings.
Also known is a second family of heat exchanger
devices which perform both the function of cooling the
cone of glass and the function of supplying air. These
are blowing fins. The latter are also configured as a
comb and situated underneath the bottom of the bushing,
the glass filaments passing through the gaps between
the rows of fins.
Cooling fins ore known from patents US 3 150 946
and Us 3 345 147. Now, according no those documents,
the fins are made from a metal gauze which is folded
into a tube to form the fin. However, folding deforms
some of the holes in the mesh. These are then no longer
the same size and the flow generated by blowing is no
longer uniform.

- 3 -
Patent US 5 693 us discloses a suction fin device
that increases the convecced heat exchange underneath
the bottom of the bushing, The sucking of air through
the fins generates uniform flow under the bushing and
improves the stability of the fiberizing. By contrast,
the sucking-in of air through the fins encourages the
deposition of airborne substances (dust) of the surface
of the fins and the ingress of dust and water droplets
into the web, and these are factors known to contribute
to the instability of the web.
Patents US 4 214 884 and US 4 310 602 relate to
fins made from a thin sheet of solid nickel. The holes;
with identical and precise dimensions, are obtained
using a photochemical or electrolytic process.
In spite of the care taken in manufacturing these
holes, their density is not enough to guarantee the
optimum air flow conditions (uniformity) that will
guarantee the stability of the web of glass filaments.
The present invention therefore aims to alleviate
these disadvantages by proposing a heat exchanger
device intended to be positioned underneath the bottom
of a bushing, particularly a high-throughput bushing,
this heat exchanger device being designed ta guarantee
optimum fiberizing conditions for the web of filaments
passing through said bushing.
To this end, the heat exchanger device that is the
subject of the invention, comprising at least one fin
provided with means for blowing a fluid, is
characterized in that the blowing means are uniform and
consist of at least one of the walls of said fin, said
wall having open porosity.
By virtue of these arrangements it is possible to
obtain optimum cooling of the cone of glass leaving the
bottom of the bushing using a convection movement
resulting from the blowing of the fluid.
In preferred embodiments of the invention recourse
may also possibly be had to one and/or other of the
following treasures;

- 4 -
- the open porosity of the wall is between 5 and
30% and preferably between 10 and 25% and more
preferably still between 15 and 20%,
- the fin is of parallelepipedal overall shape and
tubular cross section and has a permeability measured
with air at a pressure of 0.5 bar and at 0°C lying in
the range from 200 to 1500 Sm2/h/m2, particularly lying
in the range from 300 to 600 Sm2/h/m2, and preferably
lying in the range between 500 and 600 Sm2/h/m2 ,
- the blowing fluid velocity field is symmetric
across the open porosity wall,
- at least one of the walls of the heat exchanger
device is obtained by sintering a metal powder,
- the metal powder is based on a mixture of
powdered stainless steel, brass and nickel, with a
particle size smaller than 100 µm and preferably with a
particle size lying within the range from 10 to 80 µm,
- the porosity of the fin based on metal powder is
Of the order of 17%,
- at least one of the walls of the heat exchanger
device is obtained by laminating a metal gauze,
- the lamination comprises 3 to 13, particularly 3
to 6, layers of metal gauze,
- the fluid is air at a pressure of between 0.1
and 6 bar, preferably between 0.2 and 4 bar,
- the blowing fluid results from the vaporization
within the fin of a fluid that was initially in the
liquid state,
- the heat exchanger device is provided with an
auxiliary cooling circuit.
other features and advantages of the invention
will become apparent in the course of the following
description of one of its embodiments, given by way of
non-limiting example with reference to the attached
drawings, In the drawings.
- Figure 1 is a perspective view of a heat exchanger
device according to the invention.
- Figure 2 is a curve illustrating the change in

- 5 -
throughput of a bushing as a function of the increase
in the set point temperature of the bushing, and for
various cooling air flow rates through the fin,
- Figure 3 is a curve illustrating the change in
thennal power likely to be removed by a blowing fin as
a function of the blowing fluid flow rate and as a
function of the temperature difference between a point
on the fin and the blown air.
- Figures 4 and 5 are photographs illustrating the
change in shape of the cone for various blowing fluid
temperatures and flow rates, for two different
positions of the cone on the fin.
figure 1 depicts the heat exchanger device 1
according to the invention. This device essentially
comprises a plurality of fins 2 (to make the drawing
essiar to understand, just two fins have been depicted)
and a manifold 3. Each of the fins, at one of its free
ends, is secured by known means (welding, brazing,
banding) to one of the walls of the manifold so as to
form a comb in this particular embodiment. It goes
without saying that this heat exchanger device may
adopt different configurations other than that of a
comb; it may thus be in the form of a frame or portion
of a frame incorporating said fins.
This heat exchanger device is intended to be
positioned underneath and near the bottom of a bushing
in a fiberising booth. The spacing between the fins
corresponds roughly to the separation of the fiberizing
nozzles situated at the bottom of the bushing so that
the filaments of molten glass pass more or less in a
plane positioned such that it is coplanar with and
equidistant between two juxtaposed fins.
Each fin is of roughly parallelepipedal shape with
a tubular cross section and has short and long walls 4,
5 parallel to one another in pairs, the long walls 4,
5, however, being intended to face the filaments. In
the example depicted in figure 1, the fin is of
rectangular cross section and the interior passage 6

- 6 -
defined between the walls 4, 5 of the fin allows a
compressed blowing fluid (such as air or nitrogen for
example) to paas. This blowing fluid is subjected
beforehand to a treatment to remove any harmful
particles which might tend to clog the pores of the fin
(air from which oil and dust have been removed) . The
blowing fluid may also result from the vaporization of
a fluid initially in the liquid state (water, alcohol,
ethylene glycol, acetone, this fluid being used pure or
as a mixture). this vaporization taking place within
che fin: this type of blowing fluid is advantageous
because it makes it possible to use the latent heat of
vaporization of the fluid. Each of the passages of each
of the fins is connected to the manifold when the comb
is produced, the comb itself being provided at the
manifold with a device for connection to the blowing
fluid distributed to the fiberizing booth.
According to a first embodiment of the invention,
the fin is obtained by sintering a metal powder,
particularly a mixture of powdered stainless steel,
brass and nickel, the parcicle size of which is smaller
than 100 µm and preferably lies in the range from 10 to
80 µm.
The open, porosity sought with this type of powder
is in the range between 5 and 30% and preferably
between 10 and 25% and more preferably still between 15
and 20% and more or less around 17%.
The thickness of the tubular walls of the fin is
more or less, around l mm.
using these fins it has been possible to measure,
across each to the long faces of the fin, a
permeability to air measured at 0.5 bar and 0°C in the
range from 300 to 1500 Sm2/h/m2, particularly in the
range from 300 to 800 Sm2/h/m2 and preferably in the
range from 500 to 600 Sm2/h/m2, which represents flow
speeds of between 0.08 and 0.2 m/s in the case of the
first range of permeability values. The operating
pressure of the fin and therefore of the comb which

- 7 -
incorporates at least one of these fins is between 0-1
and 6 bar, preferably between 0.2 and 4 bar.
According to a second embodiment, the fin is
obtained by laminating a metal gauze, between at least
3 and 18 layers, particularly between at lease 3 and 6
layers of gauze assembled by compression or by
sintering. The mesh size of the gauze lies more or less
in the range from 1 to 30 µm.
The open porosity sought with this lamination of
metal gauze lies in the range from 5 to 30 % and
preferably between 10 and 25% and more preferably still
between 15 and 20%.
Likewise, using these fins, it has been possible
to measure on each of the long faces of the fin a
permeability to air at 0.5 bar and at 0°C in the range
from 300 to 1500 Sm2/h/m2, particularly in the range
from 300 to 800 Sm2/h/m2, preferably in the range from
500 to 600 Sm2/h/m2 which represents flow speeds of
between 0.08 and 0.2 m/S (in the case of the first
range of permeability values) . The operating pressure
of the fin and therefore of the comb incorporating at
lease one of these fins is between 0.1 and 6 bar,
preferably between 0.2 and 4 bar.
Using this method of fabrication it has been
possible to determine a certain number of
characteristics regarding the flow of the bloving fluid
through each side of the long wills, of the fin.
Hemce, Figure 2 shows the change in throughput of
the bushing as a function of the increase in the set
point temperature of the bottom of the bushing for
various blowing fluid flow rates through a wall of the
fin. The data relating to the bushing illustrated in
Figure 5 et seq, are given by way of indication, the
bushing in question being a laboratory bushing fed with
alkali resistant glass cullor.
The chroughpic of the bushing increases
progressively as the pushing set point temperature
increases. At the maximum temperature (1475oC that the

- 8 -
bushing can withstand, by adjusting the blowing flow
rate a maximum bushing throughput of 47.2 kg/day is
observed. This is 211 higher than the maximum
throughput that can be achieved with conventional fins
(39.1 kg/day) , The gain in throughput using the blowing
fins is therefore very great. It should the pointed out
that this maximum throughput is limited rather by the
maximum set point temperature of the bushing (1475°C)
at which temperature the alloy of which the pushing is
made melts.
The increase in the throughput of the pushing is
not only dependent on the temperature of the blowing
fluid, which provides cooling of the fins by
convection, when the blowing fluid passes through the
porous walls of the fins, the fresh blown fluid
(entering the fins at 20°C) efficiently coals the fins
and is able to keep the fin temperature relatively low
dependent an the blowing flow rate. This low
temperature of the blowing fins allows at the seme time
an increase in the radiation heat exchange between the
eones and the blowing fins. In order to give an idea of
the cooling capability of the blowing fins, Figure 3
sets out the thermal power that can be removed by a
blowing fin as a function of the blowing fluid flow
rate, assuming an air temperature around the cones of
100oC. 200oC and 300oC, respectively. It can be pointed
out that, if a fin blows a blowing fluid (in this
instance air) at a flow rate of 5 m3/h, it is able to
remove 130 W at 100°C, 280 W at 200oC and 450 W at
300oC. This data should be compared with the cooling
capability of a fin known from the prior art, the
latter cooling capability being limited to around 100
watts.
Although increasing the throughput of a bushing is
one of the users' main objectives it is nevertheless
important to loss sight of the fact that this
increase must not be had at the expense of the
stability of the bushing, and mainly the stability of

- 9 -
the cones formed underneath the bottom of the bushing.
Now, ccne stability is dependent on the cone
temperature, this temperature itself being dependent on
the flow rate of the blowing fluid and on its
homogeneity.
As can be seen in Figures 4 and 5, it is observed
that when the set point temperature increases the ccne
depicted in Figure 4 becomes increasingly hot. It
progressively regains its volume and becomes
increasingly straight. In the case of the cone depicted
in Figure 5, the blowing by the fins is more gentle and
the cone is wider. when the set point temperature
increases, the cone enlarges and begins to spill over
around the nozzle. Upwards of 1465oC the air flow rate
has to be increased in order to stabilise the
fiberizing, An extremely advantageous phenomenon is
observed: the cone is very stable and there is
practically no longer any of the pulsation of the cone
that is found with fins of the prior art. Fiberizing
can be achieved stably even when the cone spills over
around the nozzle. When the cone is extremely hot,
pulsation reappears and a small increase in blowing is
immediately able to calm this instability. In addition,
during tests, it was found that the shape of the cones
could very easily and very flexibly be varied by
altering the flow rate blown through the fins. This
offers the advantage of a great potential for adjusting
the thickness of the filament.
Of course, other embodiments not depicted in the
figures may be conceived of particularly in terms of
the shapes, cross sections and outlines of the fins.
Likewise, in terms of the heat exchanger device and
according to an alternative form, also not depicted in
the figures, provision is made for a cooling circuit to
be incorporated in the manifold in order to remove
additional heat energy by circulating a heat transfer
fluid (such as water for example).
The invention described above offers numerous

- 10 -
advantages:
• It increases the cooling of the cone of glass and
the. bottom of the bushing by the blowing of the
fins. This makes it possible to widen the
fiberizing temperature range. Fiberising becomes
less critical and more stable;
• It avoids the deposition of airborne substances on
the surfaces of the fins by blowing. It makes it
possible to provide fins that are more efficient
and more economical for the fiberizing of glass
filaments. The production of filaments can thus
mainly or entirely dissociate itself from the
disruption of periodic cleaning of the fins, thus
improving productivity;
• It provides fins the heat absorption rate of which
can be adjusted, allowing optimum heat absorption
under all operating conditions;
• It supplies an additional means for precisely
adjusting the thickness of the filaments by
adjusting the blowing pressure;
• It immediately, using fresh air blown through the
fins, compensates for the air sucked out of the
fiberizing region by the drawing of the filaments,
making it possible to reduce ox prevent the
ingress of air from the outside toward the inside
of the web of filaments in this sensitive region.
Fiberizing can thus dissociate itself from the
effects of turbulent or transient disturbances in
the flow of air outside the web of filaments (for
example: the movement of dust). The air flow
conditions in the fiberizing region become more
stable and easier to control.
• with uniform and homogeneous blowing fins it is
therefore possible to fiberize at a higher
temperature and to reduce the fiberizing tension
while at the same time maintaining the stability
of the bushing.

- 11 –
CLAIMS
I. A heat exchanger device (1) comprising at least
one fin (2) provided with means for blowing a
fluid. characterized in that the blowing means
are uniform and consist of at lease one of the
walls (4,5) of said fin (2), said wall (4, 5)
having open porosity.
2. Heat exchanger device (1) as claimed in claim 1,
characterised in that the open porosity of the
wall (4, 5) is between 5 and 30% and preferably
between 10 and 25% and wore preferably still
between 15 and 20%.
3. Heat exchanger device (1} as claimed in one of
claims 1 and 2, characterized in that the fin (2)
is of parallelepipedal overall shape and tubular
cross section and has a permeability measured
with air at a pressure of 0.5 bar and at OoC
lying in the range from 300 to 1500 Sm2/h/m2 ,
particularly lying in the range from 300 to
800 Sm2/h/m2
4. The heat exchanger device (1) as claimed in
claim 3, characterized in that the permeability
measured with air at a pressure of 0.5 bar and at
0°C lies in the range from 500 to 600 Sm2/h/m2
5. The heat exchanger device (1) as claimed in one
of claims 1 to 4, characterized in that the-
between fluid velocity field is symmetric across
the open porosity wall.
6. The heat exchanger device as claimed in one of
claims 1 to 5. characterized in that at least one
at the walle (4, 51 of the heat exchanger device
is obtained by sintering a metal powder.
7. The heat exchanger device (1) as claimed in
claim 6, characterized in that the metal powder
is based on a mixture of pawdered stainless
steel, brass and nickel, with a particle size
smaller than 100 µm and preferably with a

- 12 -
particle size lying within the range from 10 to
80 µm.
8. The heat exchanger device (1) as claimed in
claim 7. characterized in that the open porosity
is of the order of 17%.
9. The heat exchanger device (1) as claimed in one
of claims 1 to 5, characterized in chat at least
one of the walls of the heat exchanger device is
obtained by laminating a metal gauze.
10. The heat exchanger device (1) as claimed in
claim 9, characterized in that the lamination
comprises 3 to 18, particularly 3 to 6, layers of
metal gauze.
11. The heat exchanger device (l) as claimed in any
one of the preceding claims, characterised ill
that the fluid is air at a pressure of between
0.1 and 6 bar, preferably between 0.2 and 4 bar
12. The heat exchanger device (l) as claimed in any
one of claims 1 to 10, characterized in that the
blowing fluid results from the vaporization
within the fin (2) of a fluid that was initially
in the liquid state.
13. The heat exchanger device (l) as claimed in any
one of the preceding claims, characterized in
that the heat exchanger device is provided with
an auxiliary cooling circuit.

A heat exchanger device (1) comprising at least one
fin (3) provided witlt means for blowing a fluid
characterized in that the blowing means consist of at
least one of the walls (4, 5) of Said fin (2) said
wall (4, 5) having open porosity.

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Patent Number

219065

Indian Patent Application Number

01348/KOLNP/2005

PG Journal Number

17/2008

Publication Date

25-Apr-2008

Grant Date

23-Apr-2008

Date of Filing

13-Jul-2005

Name of Patentee

SAINT-GOBAIN VETROTEX FRANCE, S.A.

Applicant Address

130 AVENUE DES FOLLAZ, F-73000 CHAMBERY, FRANCE

Inventors:

#	Inventor's Name	Inventor's Address
1	XU, DAVID, XIAOQIANG	4, RUE DES AUBEPINES, F-59700 MARCQ EN BAROEUL, FRANCE
2	DELEPLACE, PIERRE	LE HAUT SOMONT, F-73170 YENNE, FRANCE
3	MARSAULT, NICOLAS	9, ROUTE DE QUINTAL, F-74600 VIEUGY, FRANCE

PCT International Classification Number

C03B 37/02

PCT International Application Number

PCT/FR2004/000052

PCT International Filing date

2004-01-14

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	03/00380	2003-01-15	France