Glass manufacturing – Processes of manufacturing fibers – filaments – or preforms – Formation of fiber or preform utilizing fluid blast
Reexamination Certificate
2002-10-30
2004-08-17
Hoffmann, John (Department: 1731)
Glass manufacturing
Processes of manufacturing fibers, filaments, or preforms
Formation of fiber or preform utilizing fluid blast
C065S458000, C065S526000
Reexamination Certificate
active
06776013
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to methods and systems for manufacturing fiber insulation, and more particularly to methods and systems for manufacturing wool fiber insulation via a gas attenuation process.
BACKGROUND OF THE INVENTION
One prior art system for manufacturing glass wool insulation is described in U.S. Pat. No. 4,090,241 to Houston, entitled “Method for Estimating and Controlling the Mass Flow Rate of a Free Falling Fluid Stream,” issued May 16, 1978, the entirety of which is hereby incorporated by reference herein. In the system described in Houston, raw material or batch is conveyed from storage bins to a melting furnace to form molten glass. The molten glass free falls through several spaced bushings, each of which is positioned above a respective fiberizing apparatus. The fiberizing apparatus includes a centrifuge device that projects radial streams of molten glass into a transverse gaseous blast directed downward toward a horizontally moving collecting belt or forming chain. The gaseous blasts form the molten streams of glass emanating from the centrifuge into hollow cylindrical fiber veils that are deposited upon the forming chain. Before reaching the forming chain, it is common to treat the flowing fibers with a binding material. An uncured glass wool pack is thereby built upon the forming chain including glass fibers,coated with binding material. The wool pack then passes through a thermal oven wherein the binder cures. The final wool pack is then typically chopped into bans of a desired length and packaged. These systems are often referred to as gas attenuated fiber insulation manufacturing systems. The products formed thereby are referred to as gas attenuated fiber insulation products.
In some commercial embodiments of a manufacturing system described above, a forming bucket is positioned between each centrifuge and the collecting belt or forming chain. The hollow cylindrical glass fiber veils, which include millions of glass fibers, are projected downward towards the chain or belt through the forming buckets. The veils are then treated with binder and collected on the forming chain or collecting belt. Each forming bucket oscillates or swings perpendicularly to the length and direction of the forming chain or collecting belt. The plurality of forming buckets thereby cooperate to direct the fiber veils to deposit the fibers evenly across the forming chain.
A portion of this system is illustrated in
FIG. 1. A
bucket
10
, which is shown in cross section, swings perpendicularly to the length and direction of the forming chain or collecting belt
12
, which moves in the direction indicated by the arrows. The bucket
10
is made to swing by partially rotating arms
16
back and forth to direct the glass fibers
14
(moving in the direction indicated by the double arrows) through bucket
10
and evenly across the width of the belt
12
as it moves.
FIGS. 2A and 2B
illustrate forming buckets currently in use in a manufacturing system described above.
FIG. 2B
is a side elevational view of a bucket
40
used with an 800 mm diameter fiberizer. Buckets used in connection with an 800 mm diameter fiberizer are sometimes referred to herein as “800 mm buckets”. The bucket
40
has a top or input diameter D
I
of approximately 3′-6{fraction (13/16)}″ and an output diameter D
O
of 2′-6¼″. The bucket
40
has a height H
1
of 7⅞″ and a height H
2
of 2′-9½″.
FIG. 2A
is a side elevational view of a bucket
50
used in connection with a 600 mm diameter fiberizer. Buckets of this type are sometimes referred to herein as “600 mm buckets”. The bucket
50
has a top or input diameter D
I
of approximately 2′-7½″ and an output diameter D
O
of 1′-10{fraction (11/16)}″. The bucket
40
has a height H
1
of 1′-1{fraction (9/16)}′ and a height H
2
of 2′-7⅝″.
As can be seen in
FIGS. 2A-2B
, both prior art buckets
50
,
40
consist of a hollow, linear conical portion that terminates at a circular sleeve portion having a consistent diameter. These buckets are typically welded at their inlets to a mounting collar, not shown, that includes the arms
16
that are rotated to swing the buckets, as described above with respect to
FIG. 1
, across the forming chain or collecting belt.
As buckets
40
,
50
swing during the gas attenuation process, some of the fibers that flow through the buckets contact the inner walls of the buckets, primarily due to turbulence in the fiber stream within the forming buckets. The fibers that collide with the inner surface of a bucket tend to entangle and form what are referred to in the industry as “ropes.” The binder that is sprayed into the fiber stream as it exits the forming buckets cannot fully penetrate these ropes, leading to poor binder distribution and poor mass density of the resultant wool fiber insulation mats and affecting both the physical and mechanical properties of the insulation mats.
Therefore, there is a need to reduce or eliminate the formation of fiber ropes in a gas attenuated fiber insulation manufacturing process. To that end, there is a need for a new forming bucket that reduces or prevents the formation of fiber ropes in insulation mats, particularly in gas attenuated fiberglass insulation mats.
SUMMARY OF THE INVENTION
A forming bucket for use in the preparation of gas attenuated fiber insulation products is provided. The forming bucket includes a tubular member having a fiber inlet and a fiber outlet. The tubular member has a conical portion disposed between the fiber inlet and the fiber outlet. The conical portion has a smooth curvilinear surface for minimizing turbulence in a fiber stream flowing through the forming bucket during the gas attenuation process.
The forming bucket so provided is more aerodynamic than prior art buckets and reduces collisions between the fibers of the fiber stream and the interior surface of the forming bucket. This, in turn, reduces the formation of fiber ropes that are difficult to impregnate with binder. Binder distribution thereby improves along with the mass density of the fiber mat, resulting in improved physical and mechanical properties of the fabricated insulation products.
The above and other features of the present invention will be better understood from the following detailed description of the preferred embodiments of the invention that is provided in connection with the accompanying drawings.
REFERENCES:
patent: 3787194 (1974-01-01), Rayle et al.
patent: 3881903 (1975-05-01), Stalego
patent: 4090241 (1978-05-01), Houston
patent: 4359444 (1982-11-01), Shah et al.
patent: 4371312 (1983-02-01), Tank
patent: 4478624 (1984-10-01), Battigelli et al.
patent: 4592769 (1986-06-01), Lemaignen
patent: 4889546 (1989-12-01), Denniston
patent: 4927004 (1990-05-01), Leaton
patent: 4958571 (1990-09-01), Puckett
patent: 5314521 (1994-05-01), Lewis et al.
patent: 5364431 (1994-11-01), Lewis et al.
patent: 5493796 (1996-02-01), Ballew et al.
patent: 5553404 (1996-09-01), Bergeron
patent: 6237260 (2001-05-01), Gooch
Merriam Webster's Collegiate Dictionary, 10thed, 1997 p. 136.*
“Glass Fiber Manufacturing,” (9/85) pp. 11.13-1 through 11.13-16.
Certainteed Corporation
Duane Morris LLP
Hoffmann John
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