Title of Invention	METHOD ENABLING A MAINTENANCE INTERVENTION TO BE CARRIED OUT ON A CHOPPING MACHINE
Abstract	A method enabling a maintenance intervention to be carried out on a chopping machine (7), in particular enabling the chopping members of a chopping machine to be changed, characterized in that, one strand (5) is drawn through a first chopping assembly (C1) in operation, said first chopping assembly (C1) comprising a chopping wheel (8) and an anvil wheel (9), said first chopping assembly (C1) being secured to a chassis mounted so that it can move about an axle (24). The said chassis is rotated about its axle (24) until a second chopping assembly (C2) initially in a position of non-operation is brought into the vicinity of the strand (5), said second chopping assembly (C2) being secured to said chassis and comprising a chopping wheel (8) and an anvil wheel (9). The second chopping assembly (C2) is set in operation and the strand (5) is led in between the chopping wheel (8) and the anvil wheel (9). The said first chopping assembly (C1) is brought into the position of non-operation.

Title of Invention

METHOD ENABLING A MAINTENANCE INTERVENTION TO BE CARRIED OUT ON A CHOPPING MACHINE

Abstract

A method enabling a maintenance intervention to be carried out on a chopping machine (7), in particular enabling the chopping members of a chopping machine to be changed, characterized in that, one strand (5) is drawn through a first chopping assembly (C1) in operation, said first chopping assembly (C1) comprising a chopping wheel (8) and an anvil wheel (9), said first chopping assembly (C1) being secured to a chassis mounted so that it can move about an axle (24). The said chassis is rotated about its axle (24) until a second chopping assembly (C2) initially in a position of non-operation is brought into the vicinity of the strand (5), said second chopping assembly (C2) being secured to said chassis and comprising a chopping wheel (8) and an anvil wheel (9). The second chopping assembly (C2) is set in operation and the strand (5) is led in between the chopping wheel (8) and the anvil wheel (9). The said first chopping assembly (C1) is brought into the position of non-operation.

Full Text	"Method enabling chopping members to be changed" The present invention relates to the field of the manufacture of chopped strands for technical use, particularly strands of thermoplastic and especially glass strands. It relates more specifically to a method enabling a maintenance intervention to be performed, it being possible for this maintenance intervention for example to consist of an operation of changing the chopping members, cleaning, or to consist of any other operation that has to be carried out without the need to interrupt the production process and to a device enabling this method to be implemented. Within the meaning of the invention, the expression "without the need to interrupt the production process" is a phase in production during which the bushings produce filaments which are directed to the chopper (rather than going for scrap), even though, during this phase, the chopping machine might produce chopped strands that are unsuitable for sale as a finished product. Numerous devices capable of manufacturing in this way are known. These systems generally comprise at least one bushing from which glass strands are drawn and led into a chopping device consisting, for example, of a backup roll or anvil collaborating with a chopping roll equipped with blades distributed uniformly at its periphery. The chopping roll is arranged in such a way as to come into contact, under pressure, with the circumferential surface of the backup roll, thus defining a chopping region. During the operation of chopping the glass fiber, the chopping wheel, once it has been in use for a certain period of time, reaches a level of wear which is such that the quality of the chopped strands no longer meets the production requirements and has therefore to be changed. There are therefore regular production stoppages on the bushings, so that a maintenance operation such as, for example, the replacement of worn wheels, can be carried out. These production stoppages lead to a loss in productivity in at least two respects: during the phase of changing the chopping members on the chopping machine, all of the production of filaments goes for scrap, and when this maintenance operation is carried out it is necessary, in order to regain nominal chopped-strand production, to prepare each bushing individually and perform a restart operation for each of them. A restart phase is defined as an operation which consists in reestablishing the continuity of the web of filaments between the bushing and the chopper. A first solution aimed at reducing productivity losses is to associate at least one choppping machine with one bushing or a small number of bushings. This solution offers the advantage of nonetheless ensuring a reduced production of chopped strands from those chopping machines that remain operational during the maintenance phase being performed on one of them, but on the other hand, this solution is limited in terms of its bulk. Associating one chopper with one bushing requires there to be enough space near the bushings for the maintenance and restart operations performed by the user. In addition, it is noted that the predictable increase in productivity (the flow rate) limits the introduction of an additional chopping machine (because of problems of physically incorporating it into an existing line). A second solution is to use so-called "double-head" chopping machines. This solution is described for example in document EP 0 849 381 and consists in considering, on a single machine, two production heads alternately either in production or in maintenance mode. The advantage here being that the chopping unit is already equipped with a set of new wheels and that by simply rotating the machine (about a vertical axis), the chopping members are changed in a relatively shorter space of time because there is no longer a need to remove and refit the wheels while the bushings are shut down. Nonetheless, although the changing of the chopping members is done in parallel time, there still remains a time for which the production from all the bushings is sent for scrap during the operation of pivoting of the machine and during the restart phases. A third solution, described in documents FR0310046 and US6148640 has been imagined; it consists in positioning upstream of the chopping machine a drawing machine which continues to draw out the filaments while the operators are turning the chopping machine, thus limiting the undesirable effects particularly in terms of the thermal stability of the bushings or in terms of malfunctioning at the supply duct. The present invention proposes a solution to the problems mentioned hereinabove by proposing a method that enables a maintenance operation to be performed on the chopping machine, such as the changing of chopping members for example, without the need to interrupt the production process. According to the invention, the method enabling a maintenance intervention to be carried out on a chopping machine, in particular enabling the chopping members of a chopping machine to be changed, is characterized in that - at least one strand is drawn through a first chopping assembly in operation, said first chopping assembly comprising a chopping wheel and an anvil wheel, said first chopping assembly being secured to a chassis mounted so that it can move, particularly in rotation, about an articulation axle, - said chassis is rotated about its axle until a second chopping assembly initially in a position of non- operation is brought into the vicinity of the strand, said second chopping assembly being secured to said chassis and comprising a chopping wheel and an anvil wheel, - the second chopping assembly is set in operation and the strand is led in between the chopping wheel and the anvil wheel, - said first chopping assembly is brought into the position of non-operation. By using one of the chopping assemblies as a means for drawing out the strands throughout the phase of moving the chopping machine about its articulation axle it is possible to switch from one chopping assembly to the other without having to restart the strands. In other preferred embodiments of the invention, recourse may also potentially be had to one and/or other of the following arrangements: - the strands are separated upstream " of the first chopping assembly between two separating means, - the strands are brought closer together between the two separating means, - the strand is guided as the chassis rotates about its axle, this guidance being performed by guide means secured to said chassis, - said chassis is always set in motion in the same direction, - said chassis is set in rotation about a vertical axis . According to another aspect of the invention, the latter is aimed at a chopping machine intended for the manufacture of chopped strands for technical use, particularly strands of thermoplastic and especially glass strands, said machine comprising a three- dimensional chassis having three sides or more, a first chopping assembly secured to one of the sides of said chassis comprising a chopping wheel and an anvil wheel, a second chopping assembly comprising a chopping wheel and an anvil wheel, said second chopping assembly being secured to one of the other sides of said chassis, said chassis being mounted so that it can move on an articulation axle, particularly an axle of rotation, characterized in that the chassis comprises guide means for guiding the strand which are designed to guide the strand in its path between the first chopping assembly and the second chopping assembly when said chassis is moved about its axle. In other preferred embodiments of the invention, recourse may also potentially be had to one and/or other of the following arrangements: the chassis is set in rotation about a vertical axis, the chassis is a cube or a rectangular polyhedron, the first chopping assembly and the second chopping assembly are positioned one on each side of an axis of symmetry of the chassis, the first chopping assembly and the second chopping assembly are positioned respectively on adjacent sides of said chassis, the first chopping assembly and the second chopping assembly are positioned respectively on parallel sides of said chassis, the guide means are positioned upstream and downstream of the first and/or second chopping assemblies, the guide means comprise rolls mounted so that they can move about a more or less vertical axis. Other characteristics, details and advantages of the present invention will become better apparent from reading the description that will follow, given by way of entirely nonlimiting illustration with reference to the attached drawings in which: - figure 1 is a simplified overall schematic view of an installation incorporating a chopping machine according to the invention, and - figures 2 to 8 illustrate the various steps in the process aimed at changing the chopping members, according to the procedures of the invention. Figure 1 therefore schematically shows an installation for producing chopped strands which comprises at least one bushing 1 fed, in the known way, with molten glass or glass beads delivered by a feed device, not depicted. These bushings, for example made of a platinum-rhodium alloy, are usually heated by resistance heating. They are provided on their underside with a plurality of orifices from which a plurality of filaments 2 (here some of them are depicted in chain line) can be mechanically drawn. The filaments 2 generally undergo a sizing operation, that is to say a chemical treatment designed to apply to them a product that provides the strand with cohesion and sufficient lubrication and a capability to be subsequently used, in terms of processability and reinforcement/matrix compatibility, by means of a size applicator roller 3. The filaments coming from a bushing are then combined by assembling rollers 4 into at least one strand 5 which is turned, via means such as a deflection or turn roll 6, so as to send them to a chopping machine 7 Ideated downstream of the bushing 1 assembly. Furthermore, the arrangement of the main components of the installation illustrated in figure 1 is such that the path of the filaments 2 then of the strands 5 lies generally in a vertical plane, from the bushing as far as the chopping machine 7. More specifically, the filaments 2 lie firstly in an approximately vertical direction from the bushing to the deflection or turn roll 6, then the strands 5 follow a more or less horizontal path until they enter the chopping machine 7. A tensioning roll 10 may be provided at the entry to the machine so as to ensure that the strands are wrapped around the anvil wheel over a sufficiently large arc to drive said strands by the friction force. The bushing 1 and the size applicator roller 3 are placed one above the other, for example in one and the same fiberizing cell which stands on the floor on which the chopping machine stands. The turn roll 6 lies vertically in line with the size applicator roller 3. An opening made in the floor allows the bundle of filaments to pass downstream of the size applicator roller. This opening may also allow the fibers to be removed in the event of bushing breaks. Thus, the filaments 2 follow a more or less vertical path from the bushing 1 to the turn roll 6 which deflects the strands through about 90° to bring them horizontally (or more or less horizontally) to the chopping machine 7. The chopping machine 7 firstly comprises a blade- carrying wheel 8 (or chopping wheel) and an anvil wheel 9. Details about the construction of these wheels are given in the prior literature, particularly in publication EP 0 040 145. The chopping and anvil wheels are in contact with one another under slight pressure so that in the region of contact, which is also the chopping region, the deformation of the elastomer results in the blades of the blade-carrying wheel being flush. In practice, just one of the two wheels is driven, the other being driven upon contact therewith. As a preference, it is the blade-carrying wheel that is driven. The drive is conveyed by means of an electric motor, preferably with a direct drive via the hub of the wheel concerned. The chopped strands 11 are collected in a receiving device 12. During the gaps in the chopping operation, particularly when a bushing is restarted, the strands are drawn by a drawing system 23, usually called a strand puller (cf. figure 1). The strands have to be drawn before the chopping operation begins or when a bushing is being restarted in order to establish steady-state operation of the bushing and therefore guarantee well-defined strand quality. Under running conditions, the chopping machine 7 of which either the anvil 8 and/or the blade-carrying wheel 8 is motorized, pulls on the strands. According to a preferred embodiment, the chopping machine visible in figure 1 is in fact a multi-head chopping machine. Figures 2 to 8 are views from above of this chopping machine at various stages in the operating cycle. The multi-head chopping machine comprises at least two chopping assemblies (a first one CI and a second one C2) which are separate and mounted on a chassis, the chassis being able to move in rotation about an axle 24 secured to a base positioned on the floor of the installation, this rotation axle 24 preferably being a vertical axle. As a preference, the chassis can be inscribed within a cube or, more generally, within a rectangular polyhedron, and the chopping assemblies CI, C2 are positioned along an axis of symmetry of this chassis (in the example depicted, the axis of symmetry is the rotation spindle). In the example depicted in figure 2, each chopping assembly CI, C2 is positioned respectively on two sides or two parallel faces of the chassis. As an alternative (not depicted in the figures), the first and second chopping assemblies CI, C2 are positioned on adjacent sides of the chopping machine 7 . As can be seen in figure 2, a web of strands 5 from a bushing 1 or part of a bushing is drawn then chopped by a first chopping assembly CI, the strands 5 passing between the chopping wheel 8 and the anvil wheel 9 of this first chopping assembly CI which is in the production position, these strands being guided from the deflection wheel 6 to the first chopping assembly CI by a first separator 22. As can be seen in figure 2, the first separator 22 allows the strands 5 to be separated from one another and prevent them from occasioning chopping defects as they pass between the chopping wheel 8 and the anvil wheel 9. When the chopping quality deteriorates, then the chopping members need to be changed using procedures that will be explained in detail hereinafter. Figure 3 illustrates a transient phase prior to the changing of the chopping tools. This figure 3 depicts a second separator 25 identical to the previous one. This second separator 25 is on standby and disengaged. It does not interfere with the path of the strands 5 exiting the bushings ]. Initially positioned upstream of the first separator 22 (position identified as A in figure 3), the second separator 25 is brought closer to the first separator 22 (position identified as B in figure 3) either manually or in a motorized manner (it may for example be mounted on an actuator), this approach movement (A, B) (in fact the separator 25 adopts a position B just ahead of the position occupied by the separator 22) is illustrated by an arrow fl. When the second separator 25 is in the upstream vicinity of the first separator 22 it is then engaged and interferes with the path of the strands 5. In figure 4, the second separator 25 moves away from the first separator 22 and returns to the position A it initially occupied (this movement is depicted by an arrow f2) in figure 3, although the second separator 25 remains engaged with the path of the strands 5 the same is true of the first separator 22. In this configuration, the chopping machine 7 will be able to effect a rotational movement about its axle 24 as follows (reference may be made to the sequence in figures 5-6-7-8). This rotation is performed in a known way, by any hydraulic, electrical, or pneumatic actuator, or manually if need be. As can be seen from figure 5, before rotating the chopping machine 7 about its vertical rotation axle 24, two gathering means 26, 26' are simultaneously brought together, so as to collect or gather together the strands 5 running between the first separator 22 and the second - separator 25, this brmging-together of the gathering means 26, 26' is illustrated by the arrows f3 (between a separated position illustrated in dotted line and a gathered-together position illustrated in solid line). These gathering means 26 secured to the chassis consist for example of a roller or roll in the shape of a diabolo mounted so that it can move in terms of rotation on a vertical axle. The gathering means 26' situated in close proximity to the second separator 25 also constitutes a guide means situated upstream of the first chopping assembly CI, the path of the strand coming flush with the external surface of the roller. Other guide means 27, 28, 29 identical to the previous ones are positioned, as can be seen from figure 5, downstream of the first chopping assembly CI and upstream and downstream of the second chopping assembly C2, namely more or less at each of the corners of the chopping machine 7. In figure 6, as the chopping machine 7 is rotated, the guide means 26, 27, 28, 29 (the rollers) each in turn take over the guidance of the strands 5, these continuing to be chopped by the first chopping assembly CI. In figure 7, the chopping machine 7 has completely rotated about its rotation axle 24. The first chopping assembly CI has taken the place of the second chopping assembly C2 and vice versa. The first chopping assembly CI throughout the rotation of the chopping machine 7 is kept in operation and therefore continued to draw the strands 5 during the rotation process, these strands 5 also, furthermore, simultaneously being chopped and collected under the chopping machine 7. The next step is to bring the second chopping assembly C2 into operation and automatically restart the strands on the second chopping assembJy C2. This automatic restart phase is covered by a parallel patent application FR 04/52285 filed on October 07, 2004 by the applicant company and to which reference should be made. Figure 8 depicts the installation after this automatic restart phase. It will be noted that the strands 5 are now drawn and chopped by the second chopping assembly C2 and that the strands 5 are correctly separated, the gathering means 26, 26' having returned to their rest position, the position that they occupied in figure 5. The first chopping assembly CI can then be taken out of operation so that a maintenance operation can be performed on it, it being possible for this for example to consist of a change of chopping members (anvil wheel and/or chopping wheel). As has been seen, the various steps m this process guarantee thai: work can be performed on the chopping machine without having to interrupt the production of the strands from the bushings, something that was not possible with double-head chopping machines known from the prior art, even the latter requiring some degree of scrapping while the machine was being rotated. It goes without saying that the invention as previously described has been illustrated on the basis of a mode of operation that includes rotating the chopping machine about one of its axes of symmetry (in this instance a vertical rotation axle). It will therefore be understood that this invention also comprises modes of operation whereby the rotation about an axis can be broken down into a combination of elementary movements including translational movements, rotational movements during which the strand(s) from the bushings will pass without breakage from a first chopping assembly to a second chopping assembly, amounting to a mode of operation equivalent to the one illustrated by figures 2 to 8. Thus, in a variant embodiment, the chopping machine may perform a circuit in the shape of a square. According to yet another variant embodiment, the chopping machine equipped with these two chopping assemblies is placed on a runway track along which it can move as far as a turntable designed to allow it to make a half-turn, so as to switch the first chopping assembly from an operating position to a maintenance position and vice versa in respect of the second chopping assembly (which is switched from a maintenance position to an operating position). Once the half-turn has been effected, the chopping machine, by moving in the opposite direction along the runway track, returns to its initial position. Furthermore, the automatic switchover of the strands from a first chopping assembly to a second chopping assembly without the need to interrupt production or, more precisely, without the need to send the production for scrap, is highly economical in terms of human intervention: in theory, all of the steps can be managed by a single operator, something which was not the case with double-head chopping machines known from the prior art. The strands chopped during this maintenance phase can be collected and used for profit. WE CLAIM 1. A method enabling a maintenance intervention to be carried out on a chopping machine (7), in particular enabling the chopping members of a chopping machine to be changed, characterized in that; drawing a strand (5) through a first chopping assembly (C1) in operation, said first chopping assembly (C1) comprising a first chopping wheel (8) and a first anvil wheel (9), said first chopping assembly (C1) being secured to a chassis mounted so that it can move about an articulation axle (24); separating a portion of the strand upstream of the first chopping assembly to form a first separated strand portion; chopping the first separated strand portion in the first chopping assembly; gathering a portion of the first separated strand portion to form a gathered strand portion prior to movement of the chassis; moving the chassis about its axle (24) until a second chopping assembly (C2) initially in a position of non-operation is brought into the vicinity of the strand portion (5), said second chopping assembly (C2) being secured to said chassis and comprising a second chopping wheel (8) and a second anvil wheel (9), wherein the strand remains drawn through the first chopping assembly in operation during movement of the chassis; setting the second chopping assembly (C2) in operation and leading the gathered strand (5) in between the second chopping wheel (8) and the second anvil wheel (9); separating the gathered strand portion upstream of the second chopping assembly to form a second separated strand portion; chopping the second separated strand portion in the second chopping assembly; and bringing said first chopping assembly (C1) into the position of non-operation, wherein chopping of the strand continues throughout movement of the chassis. 2. The method as claimed in claim 1, wherein the strands (5) are separated upstream of the first chopping assembly (C1) between two separating means (22, 25). 3. The method as claimed in claim 2, wherein the strands (5) are brought closer together between the two separating means (22, 25). 4. The method as claimed in claim 1, wherein the strand (5) is guided as the chassis rotates about its axle (24), this guidance being performed by guide means (26, 27, 28, 29) secured to said chassis. 5. The method as claimed in claim 1, wherein said chassis always moves in the same direction. 6. The method as claimed in claim 1, wherein said chassis moves about a vertical axis. 7. A chopping machine (7) intended for the manufacture of chopped strands (5) for technical use, particularly strands of thermoplastic and especially glass strands, said machine (7) comprising: a three-dimensional chassis having three sides or more, a first chopping assembly (C1) secured to one of the sides of said chassis comprising a first chopping wheel (8) and a first anvil wheel (9), a second chopping assembly (C2) comprising a second chopping wheel (8) and a second anvil wheel (9), said second chopping assembly (C2) being secured to one of the other sides of said chassis, said chassis being mounted so that it can move on an articulation axle (24), characterized in that said chopping machine comprises: separating means for separating a strand of fibers into a first separated strand portion for chopping by the first chopping assembly; gathering means for gathering a portion of the first separated strand portion together to form a gathered strand portion; and guiding means for guiding the gathered strand portion in an uninterrupted path between the first chopping assembly and the second chopping assembly when the chassis is moved about its axle; wherein the separating means separates the gathered strand portion into a second separated strand portion for chopping by the second chopping assembly; and wherein chopping of the strand of fibers occurs throughout the movement of the chassis. 8. The chopping machine as claimed in claim 7, wherein the chassis moves about a vertical axis. 9. The chopping machine as claimed in claim 7, wherein the chassis is a cube or a rectangular polyhedron. 10. The chopping machine as claimed in claim 7, wherein the first chopping assembly (C1) and the second chopping assembly (C2) are positioned one on each side of an axis of symmetry of the chassis. 11. The chopping machine as claimed in claim 10, wherein the first chopping assembly (C1) and the second chopping assembly (C2) are positioned respectively on adjacent sides of said chassis. 12. The chopping machine as claimed in claim 10, wherein the first chopping assembly (C1) and the second chopping assembly (C2) are positioned respectively on parallel sides of said chassis. 13. The chopping machine as claimed in claim 7, wherein the guiding means (26, 27, 28, 29) - are positioned upstream and downstream of the first and/or second chopping assemblies (C1, C2). 14. The chopping machine as claimed in claim 13, wherein the guiding means (26, 27, 28, 29) comprise rolls mounted so that they can move about a more or less vertical axis. ABSTRACT METHOD ENABLING CHOPPING MEMBERS TO BE CHANGED A method enabling a maintenance intervention to be carried out on a chopping machine (7), in particular enabling the chopping members of a chopping machine to be changed, characterized in that, one strand (5) is drawn through a first chopping assembly (C1) in operation, said first chopping assembly (C1) comprising a chopping wheel (8) and an anvil wheel (9), said first chopping assembly (C1) being secured to a chassis mounted so that it can move about an axle (24). The said chassis is rotated about its axle (24) until a second chopping assembly (C2) initially in a position of non-operation is brought into the vicinity of the strand (5), said second chopping assembly (C2) being secured to said chassis and comprising a chopping wheel (8) and an anvil wheel (9). The second chopping assembly (C2) is set in operation and the strand (5) is led in between the chopping wheel (8) and the anvil wheel (9). The said first chopping assembly (C1) is brought into the position of non-operation.

Full Text

"Method enabling chopping members to be changed"
The present invention relates to the field of the
manufacture of chopped strands for technical use,
particularly strands of thermoplastic and especially
glass strands.
It relates more specifically to a method enabling a
maintenance intervention to be performed, it being
possible for this maintenance intervention for example
to consist of an operation of changing the chopping
members, cleaning, or to consist of any other operation
that has to be carried out without the need to
interrupt the production process and to a device
enabling this method to be implemented.
Within the meaning of the invention, the expression
"without the need to interrupt the production process"
is a phase in production during which the bushings
produce filaments which are directed to the chopper
(rather than going for scrap), even though, during this
phase, the chopping machine might produce chopped
strands that are unsuitable for sale as a finished
product.
Numerous devices capable of manufacturing in this way
are known. These systems generally comprise at least
one bushing from which glass strands are drawn and led
into a chopping device consisting, for example, of a
backup roll or anvil collaborating with a chopping roll
equipped with blades distributed uniformly at its
periphery.
The chopping roll is arranged in such a way as to come
into contact, under pressure, with the circumferential
surface of the backup roll, thus defining a chopping
region. During the operation of chopping the glass
fiber, the chopping wheel, once it has been in use for
a certain period of time, reaches a level of wear which

is such that the quality of the chopped strands no
longer meets the production requirements and has
therefore to be changed.
There are therefore regular production stoppages on the
bushings, so that a maintenance operation such as, for
example, the replacement of worn wheels, can be carried
out.
These production stoppages lead to a loss in
productivity in at least two respects: during the phase
of changing the chopping members on the chopping
machine, all of the production of filaments goes for
scrap, and when this maintenance operation is carried
out it is necessary, in order to regain nominal
chopped-strand production, to prepare each bushing
individually and perform a restart operation for each
of them. A restart phase is defined as an operation
which consists in reestablishing the continuity of the
web of filaments between the bushing and the chopper.
A first solution aimed at reducing productivity losses
is to associate at least one choppping machine with one
bushing or a small number of bushings. This solution
offers the advantage of nonetheless ensuring a reduced
production of chopped strands from those chopping
machines that remain operational during the maintenance
phase being performed on one of them, but on the other
hand, this solution is limited in terms of its bulk.
Associating one chopper with one bushing requires there
to be enough space near the bushings for the
maintenance and restart operations performed by the
user. In addition, it is noted that the predictable
increase in productivity (the flow rate) limits the
introduction of an additional chopping machine (because
of problems of physically incorporating it into an
existing line).

A second solution is to use so-called "double-head"
chopping machines. This solution is described for
example in document EP 0 849 381 and consists in
considering, on a single machine, two production heads
alternately either in production or in maintenance
mode. The advantage here being that the chopping unit
is already equipped with a set of new wheels and that
by simply rotating the machine (about a vertical axis),
the chopping members are changed in a relatively
shorter space of time because there is no longer a need
to remove and refit the wheels while the bushings are
shut down.
Nonetheless, although the changing of the chopping
members is done in parallel time, there still remains a
time for which the production from all the bushings is
sent for scrap during the operation of pivoting of the
machine and during the restart phases.
A third solution, described in documents FR0310046 and
US6148640 has been imagined; it consists in positioning
upstream of the chopping machine a drawing machine
which continues to draw out the filaments while the
operators are turning the chopping machine, thus
limiting the undesirable effects particularly in terms
of the thermal stability of the bushings or in terms of
malfunctioning at the supply duct.
The present invention proposes a solution to the
problems mentioned hereinabove by proposing a method
that enables a maintenance operation to be performed on
the chopping machine, such as the changing of chopping
members for example, without the need to interrupt the
production process.
According to the invention, the method enabling a
maintenance intervention to be carried out on a
chopping machine, in particular enabling the chopping

members of a chopping machine to be changed, is
characterized in that
- at least one strand is drawn through a first chopping
assembly in operation, said first chopping assembly
comprising a chopping wheel and an anvil wheel, said
first chopping assembly being secured to a chassis
mounted so that it can move, particularly in
rotation, about an articulation axle,
- said chassis is rotated about its axle until a second
chopping assembly initially in a position of non-
operation is brought into the vicinity of the strand,
said second chopping assembly being secured to said
chassis and comprising a chopping wheel and an anvil
wheel,
- the second chopping assembly is set in operation and
the strand is led in between the chopping wheel and
the anvil wheel,
- said first chopping assembly is brought into the
position of non-operation.
By using one of the chopping assemblies as a means for
drawing out the strands throughout the phase of moving
the chopping machine about its articulation axle it is
possible to switch from one chopping assembly to the
other without having to restart the strands.
In other preferred embodiments of the invention,
recourse may also potentially be had to one and/or
other of the following arrangements:
- the strands are separated upstream " of the first
chopping assembly between two separating means,
- the strands are brought closer together between the
two separating means,
- the strand is guided as the chassis rotates about its
axle, this guidance being performed by guide means
secured to said chassis,
- said chassis is always set in motion in the same
direction,

- said chassis is set in rotation about a vertical
axis .
According to another aspect of the invention, the
latter is aimed at a chopping machine intended for the
manufacture of chopped strands for technical use,
particularly strands of thermoplastic and especially
glass strands, said machine comprising a three-
dimensional chassis having three sides or more, a first
chopping assembly secured to one of the sides of said
chassis comprising a chopping wheel and an anvil wheel,
a second chopping assembly comprising a chopping wheel
and an anvil wheel, said second chopping assembly being
secured to one of the other sides of said chassis, said
chassis being mounted so that it can move on an
articulation axle, particularly an axle of rotation,
characterized in that the chassis comprises guide means
for guiding the strand which are designed to guide the
strand in its path between the first chopping assembly
and the second chopping assembly when said chassis is
moved about its axle.
In other preferred embodiments of the invention,
recourse may also potentially be had to one and/or
other of the following arrangements:
the chassis is set in rotation about a vertical
axis,
the chassis is a cube or a rectangular polyhedron,
the first chopping assembly and the second
chopping assembly are positioned one on each side
of an axis of symmetry of the chassis,
the first chopping assembly and the second
chopping assembly are positioned respectively on
adjacent sides of said chassis,
the first chopping assembly and the second
chopping assembly are positioned respectively on
parallel sides of said chassis,

the guide means are positioned upstream and
downstream of the first and/or second chopping
assemblies,
the guide means comprise rolls mounted so that
they can move about a more or less vertical axis.
Other characteristics, details and advantages of the
present invention will become better apparent from
reading the description that will follow, given by way
of entirely nonlimiting illustration with reference to
the attached drawings in which:
- figure 1 is a simplified overall schematic view of an
installation incorporating a chopping machine
according to the invention, and
- figures 2 to 8 illustrate the various steps in the
process aimed at changing the chopping members,
according to the procedures of the invention.
Figure 1 therefore schematically shows an installation
for producing chopped strands which comprises at least
one bushing 1 fed, in the known way, with molten glass
or glass beads delivered by a feed device, not
depicted. These bushings, for example made of a
platinum-rhodium alloy, are usually heated by
resistance heating. They are provided on their
underside with a plurality of orifices from which a
plurality of filaments 2 (here some of them are
depicted in chain line) can be mechanically drawn.
The filaments 2 generally undergo a sizing operation,
that is to say a chemical treatment designed to apply
to them a product that provides the strand with
cohesion and sufficient lubrication and a capability to
be subsequently used, in terms of processability and
reinforcement/matrix compatibility, by means of a size
applicator roller 3.
The filaments coming from a bushing are then combined
by assembling rollers 4 into at least one strand 5

which is turned, via means such as a deflection or turn
roll 6, so as to send them to a chopping machine 7
Ideated downstream of the bushing 1 assembly.
Furthermore, the arrangement of the main components of
the installation illustrated in figure 1 is such that
the path of the filaments 2 then of the strands 5 lies
generally in a vertical plane, from the bushing as far
as the chopping machine 7. More specifically, the
filaments 2 lie firstly in an approximately vertical
direction from the bushing to the deflection or turn
roll 6, then the strands 5 follow a more or less
horizontal path until they enter the chopping machine
7. A tensioning roll 10 may be provided at the entry to
the machine so as to ensure that the strands are
wrapped around the anvil wheel over a sufficiently
large arc to drive said strands by the friction force.
The bushing 1 and the size applicator roller 3 are
placed one above the other, for example in one and the
same fiberizing cell which stands on the floor on which
the chopping machine stands.
The turn roll 6 lies vertically in line with the size
applicator roller 3. An opening made in the floor
allows the bundle of filaments to pass downstream of
the size applicator roller. This opening may also allow
the fibers to be removed in the event of bushing
breaks.
Thus, the filaments 2 follow a more or less vertical
path from the bushing 1 to the turn roll 6 which
deflects the strands through about 90° to bring them
horizontally (or more or less horizontally) to the
chopping machine 7.
The chopping machine 7 firstly comprises a blade-
carrying wheel 8 (or chopping wheel) and an anvil wheel
9. Details about the construction of these wheels are

given in the prior literature, particularly in
publication EP 0 040 145. The chopping and anvil wheels
are in contact with one another under slight pressure
so that in the region of contact, which is also the
chopping region, the deformation of the elastomer
results in the blades of the blade-carrying wheel being
flush. In practice, just one of the two wheels is
driven, the other being driven upon contact therewith.
As a preference, it is the blade-carrying wheel that is
driven. The drive is conveyed by means of an electric
motor, preferably with a direct drive via the hub of
the wheel concerned.
The chopped strands 11 are collected in a receiving
device 12. During the gaps in the chopping operation,
particularly when a bushing is restarted, the strands
are drawn by a drawing system 23, usually called a
strand puller (cf. figure 1). The strands have to be
drawn before the chopping operation begins or when a
bushing is being restarted in order to establish
steady-state operation of the bushing and therefore
guarantee well-defined strand quality.
Under running conditions, the chopping machine 7 of
which either the anvil 8 and/or the blade-carrying
wheel 8 is motorized, pulls on the strands.
According to a preferred embodiment, the chopping
machine visible in figure 1 is in fact a multi-head
chopping machine. Figures 2 to 8 are views from above
of this chopping machine at various stages in the
operating cycle. The multi-head chopping machine
comprises at least two chopping assemblies (a first one
CI and a second one C2) which are separate and mounted
on a chassis, the chassis being able to move in
rotation about an axle 24 secured to a base positioned
on the floor of the installation, this rotation axle 24
preferably being a vertical axle.

As a preference, the chassis can be inscribed within a
cube or, more generally, within a rectangular
polyhedron, and the chopping assemblies CI, C2 are
positioned along an axis of symmetry of this chassis
(in the example depicted, the axis of symmetry is the
rotation spindle). In the example depicted in figure 2,
each chopping assembly CI, C2 is positioned
respectively on two sides or two parallel faces of the
chassis. As an alternative (not depicted in the
figures), the first and second chopping assemblies CI,
C2 are positioned on adjacent sides of the chopping
machine 7 .
As can be seen in figure 2, a web of strands 5 from a
bushing 1 or part of a bushing is drawn then chopped by
a first chopping assembly CI, the strands 5 passing
between the chopping wheel 8 and the anvil wheel 9 of
this first chopping assembly CI which is in the
production position, these strands being guided from
the deflection wheel 6 to the first chopping assembly
CI by a first separator 22. As can be seen in figure 2,
the first separator 22 allows the strands 5 to be
separated from one another and prevent them from
occasioning chopping defects as they pass between the
chopping wheel 8 and the anvil wheel 9.
When the chopping quality deteriorates, then the
chopping members need to be changed using procedures
that will be explained in detail hereinafter.
Figure 3 illustrates a transient phase prior to the
changing of the chopping tools.
This figure 3 depicts a second separator 25 identical
to the previous one. This second separator 25 is on
standby and disengaged. It does not interfere with the
path of the strands 5 exiting the bushings ].

Initially positioned upstream of the first separator 22
(position identified as A in figure 3), the second
separator 25 is brought closer to the first separator
22 (position identified as B in figure 3) either
manually or in a motorized manner (it may for example
be mounted on an actuator), this approach movement
(A, B) (in fact the separator 25 adopts a position B
just ahead of the position occupied by the separator
22) is illustrated by an arrow fl. When the second
separator 25 is in the upstream vicinity of the first
separator 22 it is then engaged and interferes with the
path of the strands 5. In figure 4, the second
separator 25 moves away from the first separator 22 and
returns to the position A it initially occupied (this
movement is depicted by an arrow f2) in figure 3,
although the second separator 25 remains engaged with
the path of the strands 5 the same is true of the first
separator 22.
In this configuration, the chopping machine 7 will be
able to effect a rotational movement about its axle 24
as follows (reference may be made to the sequence in
figures 5-6-7-8). This rotation is performed in a known
way, by any hydraulic, electrical, or pneumatic
actuator, or manually if need be.
As can be seen from figure 5, before rotating the
chopping machine 7 about its vertical rotation axle 24,
two gathering means 26, 26' are simultaneously brought
together, so as to collect or gather together the
strands 5 running between the first separator 22 and
the second - separator 25, this brmging-together of the
gathering means 26, 26' is illustrated by the arrows f3
(between a separated position illustrated in dotted
line and a gathered-together position illustrated in
solid line).
These gathering means 26 secured to the chassis consist
for example of a roller or roll in the shape of a

diabolo mounted so that it can move in terms of
rotation on a vertical axle.
The gathering means 26' situated in close proximity to
the second separator 25 also constitutes a guide means
situated upstream of the first chopping assembly CI,
the path of the strand coming flush with the external
surface of the roller.
Other guide means 27, 28, 29 identical to the previous
ones are positioned, as can be seen from figure 5,
downstream of the first chopping assembly CI and
upstream and downstream of the second chopping assembly
C2, namely more or less at each of the corners of the
chopping machine 7.
In figure 6, as the chopping machine 7 is rotated, the
guide means 26, 27, 28, 29 (the rollers) each in turn
take over the guidance of the strands 5, these
continuing to be chopped by the first chopping assembly
CI.
In figure 7, the chopping machine 7 has completely
rotated about its rotation axle 24. The first chopping
assembly CI has taken the place of the second chopping
assembly C2 and vice versa. The first chopping assembly
CI throughout the rotation of the chopping machine 7 is
kept in operation and therefore continued to draw the
strands 5 during the rotation process, these strands 5
also, furthermore, simultaneously being chopped and
collected under the chopping machine 7.
The next step is to bring the second chopping assembly
C2 into operation and automatically restart the strands
on the second chopping assembJy C2. This automatic
restart phase is covered by a parallel patent
application FR 04/52285 filed on October 07, 2004 by
the applicant company and to which reference should be
made.

Figure 8 depicts the installation after this automatic
restart phase.
It will be noted that the strands 5 are now drawn and
chopped by the second chopping assembly C2 and that the
strands 5 are correctly separated, the gathering means
26, 26' having returned to their rest position, the
position that they occupied in figure 5.
The first chopping assembly CI can then be taken out of
operation so that a maintenance operation can be
performed on it, it being possible for this for example
to consist of a change of chopping members (anvil wheel
and/or chopping wheel).
As has been seen, the various steps m this process
guarantee thai: work can be performed on the chopping
machine without having to interrupt the production of
the strands from the bushings, something that was not
possible with double-head chopping machines known from
the prior art, even the latter requiring some degree of
scrapping while the machine was being rotated.
It goes without saying that the invention as previously
described has been illustrated on the basis of a mode
of operation that includes rotating the chopping
machine about one of its axes of symmetry (in this
instance a vertical rotation axle). It will therefore
be understood that this invention also comprises modes
of operation whereby the rotation about an axis can be
broken down into a combination of elementary movements
including translational movements, rotational movements
during which the strand(s) from the bushings will pass
without breakage from a first chopping assembly to a
second chopping assembly, amounting to a mode of
operation equivalent to the one illustrated by figures
2 to 8. Thus, in a variant embodiment, the chopping
machine may perform a circuit in the shape of a square.

According to yet another variant embodiment, the
chopping machine equipped with these two chopping
assemblies is placed on a runway track along which it
can move as far as a turntable designed to allow it to
make a half-turn, so as to switch the first chopping
assembly from an operating position to a maintenance
position and vice versa in respect of the second
chopping assembly (which is switched from a maintenance
position to an operating position). Once the half-turn
has been effected, the chopping machine, by moving in
the opposite direction along the runway track, returns
to its initial position.
Furthermore, the automatic switchover of the strands
from a first chopping assembly to a second chopping
assembly without the need to interrupt production or,
more precisely, without the need to send the production
for scrap, is highly economical in terms of human
intervention: in theory, all of the steps can be
managed by a single operator, something which was not
the case with double-head chopping machines known from
the prior art. The strands chopped during this
maintenance phase can be collected and used for profit.

WE CLAIM
1. A method enabling a maintenance intervention to be carried out on a chopping machine
(7), in particular enabling the chopping members of a chopping machine to be changed,
characterized in that;
drawing a strand (5) through a first chopping assembly (C1) in operation, said first
chopping assembly (C1) comprising a first chopping wheel (8) and a first anvil wheel (9), said
first chopping assembly (C1) being secured to a chassis mounted so that it can move about an
articulation axle (24);
separating a portion of the strand upstream of the first chopping assembly to form a first
separated strand portion;
chopping the first separated strand portion in the first chopping assembly;
gathering a portion of the first separated strand portion to form a gathered strand portion
prior to movement of the chassis;
moving the chassis about its axle (24) until a second chopping assembly (C2) initially in a
position of non-operation is brought into the vicinity of the strand portion (5), said second
chopping assembly (C2) being secured to said chassis and comprising a second chopping wheel
(8) and a second anvil wheel (9), wherein the strand remains drawn through the first chopping
assembly in operation during movement of the chassis;
setting the second chopping assembly (C2) in operation and leading the gathered strand
(5) in between the second chopping wheel (8) and the second anvil wheel (9);
separating the gathered strand portion upstream of the second chopping assembly to
form a second separated strand portion;
chopping the second separated strand portion in the second chopping assembly; and
bringing said first chopping assembly (C1) into the position of non-operation, wherein
chopping of the strand continues throughout movement of the chassis.
2. The method as claimed in claim 1, wherein the strands (5) are separated upstream of
the first chopping assembly (C1) between two separating means (22, 25).
3. The method as claimed in claim 2, wherein the strands (5) are brought closer together
between the two separating means (22, 25).

4. The method as claimed in claim 1, wherein the strand (5) is guided as the chassis rotates
about its axle (24), this guidance being performed by guide means (26, 27, 28, 29) secured to
said chassis.
5. The method as claimed in claim 1, wherein said chassis always moves in the same
direction.
6. The method as claimed in claim 1, wherein said chassis moves about a vertical axis.
7. A chopping machine (7) intended for the manufacture of chopped strands (5) for
technical use, particularly strands of thermoplastic and especially glass strands, said machine (7)
comprising:
a three-dimensional chassis having three sides or more,
a first chopping assembly (C1) secured to one of the sides of said chassis comprising a
first chopping wheel (8) and a first anvil wheel (9),
a second chopping assembly (C2) comprising a second chopping wheel (8) and a second
anvil wheel (9), said second chopping assembly (C2) being secured to one of the other sides of
said chassis, said chassis being mounted so that it can move on an articulation axle (24),
characterized in that said chopping machine comprises:
separating means for separating a strand of fibers into a first separated strand portion for
chopping by the first chopping assembly;
gathering means for gathering a portion of the first separated strand portion together to
form a gathered strand portion; and
guiding means for guiding the gathered strand portion in an uninterrupted path between
the first chopping assembly and the second chopping assembly when the chassis is moved
about its axle;
wherein the separating means separates the gathered strand portion into a second
separated strand portion for chopping by the second chopping assembly; and
wherein chopping of the strand of fibers occurs throughout the movement of the chassis.
8. The chopping machine as claimed in claim 7, wherein the chassis moves about a vertical
axis.

9. The chopping machine as claimed in claim 7, wherein the chassis is a cube or a
rectangular polyhedron.
10. The chopping machine as claimed in claim 7, wherein the first chopping assembly (C1)
and the second chopping assembly (C2) are positioned one on each side of an axis of symmetry
of the chassis.
11. The chopping machine as claimed in claim 10, wherein the first chopping assembly (C1)
and the second chopping assembly (C2) are positioned respectively on adjacent sides of said
chassis.
12. The chopping machine as claimed in claim 10, wherein the first chopping assembly (C1)
and the second chopping assembly (C2) are positioned respectively on parallel sides of said
chassis.
13. The chopping machine as claimed in claim 7, wherein the guiding means (26, 27, 28, 29) -
are positioned upstream and downstream of the first and/or second chopping assemblies (C1,
C2).
14. The chopping machine as claimed in claim 13, wherein the guiding means (26, 27, 28,
29) comprise rolls mounted so that they can move about a more or less vertical axis.

ABSTRACT

METHOD ENABLING CHOPPING MEMBERS TO BE CHANGED
A method enabling a maintenance intervention to be carried out on a
chopping machine (7), in particular enabling the chopping members of a
chopping machine to be changed, characterized in that,
one strand (5) is drawn through a first chopping assembly (C1) in operation,
said first chopping assembly (C1) comprising a chopping wheel (8) and an anvil
wheel (9), said first chopping assembly (C1) being secured to a chassis mounted
so that it can move about an axle (24). The said chassis is rotated about its axle
(24) until a second chopping assembly (C2) initially in a position of non-operation
is brought into the vicinity of the strand (5), said second chopping assembly (C2)
being secured to said chassis and comprising a chopping wheel (8) and an anvil
wheel (9). The second chopping assembly (C2) is set in operation and the strand
(5) is led in between the chopping wheel (8) and the anvil wheel (9). The said
first chopping assembly (C1) is brought into the position of non-operation.

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=9c7XtxI3AbaXrSiTLVf3/A==&loc=wDBSZCsAt7zoiVrqcFJsRw==

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Patent Number

278201

Indian Patent Application Number

1559/KOLNP/2007

PG Journal Number

53/2016

Publication Date

23-Dec-2016

Grant Date

16-Dec-2016

Date of Filing

03-May-2007

Name of Patentee

OCV INTELLECTUAL CAPITAL,LLC

Applicant Address

ONE OWENS CORNING PARKWAY,TOLEDO,OHIO,43659-0001

Inventors:

#	Inventor's Name	Inventor's Address
1	VEUILLEN, GERARD	30 CHEMIN DES PRES, F-73000 BARBERAZ CHAMBERY
2	FONT, DOMINIQUE	165 ROUTE DE LA PORRETTAZ, F-73190 SAINT BALDOLPH

PCT International Classification Number

C03B 37/16

PCT International Application Number

PCT/FR2005/050939

PCT International Filing date

2005-11-09

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	0452700	2004-11-19	France