[0001] This invention relates to a method and an apparatus for guiding and transferring
a rapidly quenched metallic tape (referred to "tape" hereinafter), particularly an
amorphous metallic tape produced by a single roll method from a single cooling roll
(referred to "cooling roll" hereinafter) to a winder.
[0002] Recently, it has been investigated and developed to produce metallic tapes directly
from molten metals (including alloys) by rapidly liquid quenching methods such as
a single roll method and a twin roll method. In carrying out these methods, the producing
technique itself may of course be important to determine surface configurations and
uniformity in thickness of the metallic tapes. However, in the production of the metallic
tapes on industrial scale, it is needed to accomplish handling of produced metallic
tapes or technique for winding the metallic tapes into coils.
[0003] In case of crystalline metallic tapes having thickness of not less than 100 »m, feeding
speeds of the tapes are usually not more than 5 m/sec by a limitation resulting from
solidification due to heat transfer to a cooling element. Therefore, such metallic
tapes can be transferred by a mesh belt having a clamper and taken up by winding by
a heat-resistant belt wrapper as proposed in Japanese Patent laid open No. 61-88,904.
[0004] In case of amorphous metallic tapes, on the other hand, the thickness is very thin
as less than 50 »m and the feeding speed of the tapes is not lower than 20 m/sec.
Therefore, means disclosed in the above Japanese Publication could not be applied
without any modifications. With the amorphous metallic tapes, moreover, the characteristics
of the materials tend to change depending upon producing speeds so that mechanical
strengths are often spoilt. Therefore, it is more difficult to accomplish taking-up
technique because the producing speed could not be changed in taking up on a reel
and taking off.
[0005] It has been proposed to wind an amorphous metallic tape onto a take-up reel having
a magnet embedded therein arranged closely adjacent a cooling roll in Japanese Patent
laid open No. 57-94,453 and Japanese Patent Application Publication No. 59-34,467.
This method is dexterous in arranging the take-up reel closely adjacent the cooling
roll to eliminate the troublesome transferring of the tapes. However, as the reel
is close to the cooling roll, it is not necessarily suitable for continuous production
of the tapes. Moreover, it is not suitable for industrial production on a large scale,
for lack of spaces for providing inspection devices for thicknesses and apertures
of tapes and control device for tensile forces on the tapes.
[0006] In order to avoid these disadvantages, proposals for positively accomplishing the
transfer technique by arranging winders remote from cooling rolls have been disclosed
in Japanese Patent laid open Nos. 56-12,257, 59-43,772 and 59-138,572 and Japanese
Patent Application No. 62-290,477. In these techniques, it has been proposed to use
suction devices, brush rolls or brush solid roll pairs and the like as pinch rolls
for catching and transferring amorphous metallic tapes. A stable taking up of amorphous
metallic tapes can be realized if amorphous metallic tapes are caught between pinch
rolls without being ruptured and given tensile forces required for transferring.
[0007] As there are few literatures and data concerning the transferring and taking up techniques
after producing amorphous metallic tapes in comparison with producing technique thereof,
it is not an easy matter to study all the techniques. The inventors have been investigated
and improved the guide and transfer of amorphous metallic tapes peeling and flying
from cooling rolls arranged remote from winders on the basis of the acknowledgement
that arrangement of winders remote from cooling rolls is basically industrially superior,
and they have encountered the following problems.
[0008] In the guiding and transferring systems above described, brush-solid roll pairs made
of a combination of brush rolls and solid rolls are used as pinch rolls. It has been
ascertained that by embracing an amorphous metallic tape between pinch rolls, tensile
forces required for transferring is given to the metallic tape.
[0009] In guiding a rapidly quenched metallic tape produced by solidification through rapid
quenching on a cooling roll to pinch rolls through a transfer guide after the peeling
from the cooling roll, the guiding was not very difficult matter by applying particular
devices to an air knife and the transfer guide. However, the metallic tape could not
be pulled, even if the pinch rolls are pressed together. Therefore, the pinch rolls
could not be used as a transfer system by moving the pinch rolls to a winder. Tensile
forces required for transferring could not be given to a metallic tape only by transferring
the metallic tape peeled from a cooling roll through a transfer guide.
[0010] It is an object of the invention to provide a method and an apparatus for guiding
and transferring a rapidly quenched metallic tape by giving tensile forces required
for transferring to the winder.
[0011] In order to achieve this object, in a method of guiding and transferring a rapidly
quenched metallic tape the steps of independent claim 1 are carried out, and an apparatus
for guiding and transferring a rapidly quenched metallic tape comprising the features
of independent claim 5 is provided.
[0012] Enhancements and preferred embodiments of the present invention are claimed in the
dependent claims.
[0013] The invention will be described with reference to the accompanying drawings, wherein:
Fig. 1 is a schematic view of an apparatus for guiding and transferring a rapidly
quenched metallic tape according to the invention;
Fig. 2 is a schematic view of the conventional apparatus for guiding and transferring
a rapidly quenched metallic tape;
Fig. 3 is a graph showing a relation between flying direction and rapture of metallic
tape;
Figs. 4a and 4d are views showing a distribution of air flow rate in the transfer
guide, respectively;
Figs. 5a to 5b are views showing an influence of air flow rate in the transfer guide,
respectively; and
Fig. 6 is a graph showing a relation between length of a transfer guide and time of
catching metallic tape.
[0014] In Fig. 1 is shown a preferable apparatus for guiding and transferring the rapidly
quenched metallic tape according to the invention, wherein numeral 1 is a cooling
roll rotating at a high speed. A metallic tape 2 prepared by solidifying through rapid
quenching on the surface of the cooling roll 1 is peeled off from the cooling roll
1 with an air knife 3 and guided into a cylindrical transfer guide 4, at where the
tape 2 is caught by a pinch roll unit 5 (combination of brush roll 5a and solid roll
5b) placed on a transfer trolley 6. Then, the transfer trolley 6 is moved together
with the pinch roll unit 5 toward a winder (not shown), whereby the tape 2 is taken
up on the winder. Further, a deflector roll 7 is arranged at an entrance side of the
transfer guide 4, which functions to form an adequate pass line when tension is applied
to the metallic tape. Moreover, a high speed air flow is formed inside the transfer
guide 4 by means of a blower 8 arranged behind the pinch roll unit 5. Numeral 9 is
a pouring nozzle.
[0015] In this case, it is important that the transfer guide 4 is arranged so that the axial
line of the guide locates on a normal line at a peeling point of the metallic tape
2 from the cooling roll 1, whereby the flying metallic tape 2 is not contacted with
the inner wall of the transfer guide 4.
[0016] The invention will be described with respect to experimental results leading in the
success of the invention.
[0017] The guiding and transferring of the metallic tape 2 were repeated by using the apparatus
shown in Fig. 2. In this apparatus, the transfer guide was shifted from the normal
line at the peeling point of the metallic tape without the air adjustment and the
optimization of the deflector roll as shown in Fig. 2.
[0018] According to the above experiments, the metallic tape 2 could be introduced from
the cooling roll 1 through the transfer guide 4 into the entrance side of the pinch
roll unit 5, but tension could not be applied to the metallic tape 2. In order to
elucidate this cause, the behavior of the metallic tape flying inside the transfer
guide was recorded by means of VTR or the like, but in this case, only the continued
metallic tape was observed. However, it has been confirmed that if it is intended
to cast the metallic tape of amorphous alloy aiming at the invention, since the tape
forming rate is usually 25-30 m/sec, an apparently static image can not be obtained
by a general picture system, so that the detail movement of the metallic tape can
not be analyzed. Now, when the picturing was carried out by making the whole of the
apparatus dark and conducting stroboradiation at 1/50000 sec, an apparently static
image of the metallic tape flying inside the transfer guide could be recorded by VTR.
[0019] When the recorded image is analyzed in detail, there are obtained the following results,
which can not quite be anticipated in the conventional VTR observation.
(1) The metallic tape flying inside the transfer guide was raptured in some places;
(2) The cracks were frequently observed in the metallic tape flying inside the transfer
guide;
(3) The cracked metallic amorphous tape was easily raptured through the application
of tension.
[0020] That is, it has newly been found that the occurrence of such a rapture in the transfer
guide is a cause of not applying tension to the metallic tape of amorphous alloy through
the pinch roll unit.
[0021] On the other hand, it is well-known that the mechanical strength of the amorphous
alloy tape is very high. When examining the cause of easily generating the crack in
such a high strength material inside the transfer guide, there is caused a problem
when the metallic tape is passed through the transfer guide. That is, when the metallic
tape flying at a high rate of 25-30 m/sec collides with the inner wall face of the
guide, the cracks are generated or the tape is broken. This is considered to result
from such a characteristic of the amorphous metallic tape that the tape is strong
to uniaxial tension but is weak to shearing force.
[0022] In order to solve this problem, according to the invention, when the metallic tape
peeled off from the cooling roll with the air knife flies inside the transfer guide,
the tape does not substantially come into contact with the inner wall face of the
transfer guide. Particularly, the transfer guide is arranged in a direction that the
metallic tape peeled off from the cooling roll with the air knife flies freely, whereby
it is avoided to contact the metallic tape flying inside the transfer guide with the
inner wall face of the transfer guide to realize the transferring of the metallic
tape without impact.
[0023] Moreover, when the transfer guide 4 as shown in Fig. 1 is not arranged between the
cooling roll and the pinch roll unit, the rapture of the metallic tape by collision
is never caused, but the metallic tape can not stably be guided into the pinch roll
unit. Therefore, the arrangement of the transfer guide is essential in the invention.
[0024] If it is intended to produce the metallic tape by the single roll method, the metallic
tape peeled off from the cooling roll with the air knife tends to fly in a direction
of a normal line at the peeling position on the roll surface, so that the metallic
tape flies as if it springs out from the center of the roll. Therefore, when the transfer
guide is arranged in such a direction, the metallic tape is hardly subjected to impact
by contacting with the inner wall face of the guide, and consequently there is caused
no cracking nor rapture of the metallic tape.
[0025] Further, a distance (width) of a clearance 10 can be adjusted by an adjusting plate
11 arranged on an upper edge portion of an inlet port 4a of the transfer guide 4 and
freely moved to the cooling roll 1, whereby the width of air flow passage is increased
or decreased to change a blowing amount of air to the metallic tape 2 to thereby control
the flying direction of the metallic tape 2.
[0026] Further, the inventors have examined the influence of air flow inside the transfer
guide 4 on the flying trajectory of the metallic tape 2 flying at high speed inside
the transfer guide and found the following knowledges.
[0027] That is, when air flow is jetted from the air knife 3 under a pressure enough to
peel off the metallic tape 2, the air flow in the vicinity of the inlet port of the
transfer guide does not advance toward the pinch roll unit in the transfer guide but
flows downward toward the bottom face inside the transfer guide. Therefore, the metallic
tape 2 peeled off from the cooling roll 1 collides with the bottom face of the inner
wall of the transfer guide under an influence of such a downward air flow and then
takes a flying trajectory in horizontal direction together with air flow gradually
directing toward the pinch roll unit inside the transfer guide.
[0028] It is possible to avoid the collision of the metallic tape 2 with the inner wall
of the transfer guide 4 to a certain extent by weakening the air flow from the air
knife 3. However, the air knife 3 acts to give a pressure enough to completely peel
the metallic tape 2, so that there is a restriction for reducing the quantity and
pressure of the air flow.
[0029] On the other hand, it is difficult to coincide the jetting direction of air from
the air knife with the direction of the air flow inside the transfer guide (direction
toward pinch roll unit) in view of the structure.
[0030] As a result that the flying trajectory of the metallic tape 2 is analyzed from the
image of VTR, it has been confirmed that if the air flow from the air knife 3 contacts
with the flying metallic tape over a wide area, the trajectory of the tape 2 directs
downward to collide with the inner wall of the transfer guide.
[0031] In other words, it has been found that it is possible to control the advancing direction
of the metallic tape by adjusting the contacting area of air flow from the air knife
3 with the tape 2.
[0032] In order to realize such a control, it is advantageous to freely change the width
of the air flow from the air knife 3.
[0033] Fig. 3 shows the rapture number of the metallic tape inside the transfer guide (A)
when the clearance between the transfer guide 4 and the cooling roll 1 is narrowed
to direct the tape toward the pinch roll unit and (B) when the clearance is widened
to direct the tape toward the bottom face of the guide.
[0034] As seen from the results of Fig. 3, the metallic tape 2 can be guided into the pinch
roll unit 5 by adjusting the clearance between the transfer guide 4 and the cooling
roll 1 without rapturing the tape inside the transfer guide.
[0035] Moreover, the optimum value of the clearance 10 between the transfer guide 4 and
the cooling roll 1 is desirable to be determined by confirming the flying trajectory
of the metallic tape because this value is varied by physical adhesion force between
the tape 2 and the cooling roll 1, suction force at the inlet of the transfer guide
4, relative arrangement between the peeling position of the tape and the clearance
10 and the like.
[0036] There may be caused a case that the flying posture of the metallic tape 2 just after
the peeling does not necessarily take the horizontal flying trajectory. In this case,
it is sufficient to change the distance of the clearance 10 in the widthwise direction
of the metallic tape.
[0037] In addition, a high speed air flow is formed inside the transfer guide 4 by suction
of air through the blower 8 arranged behind the pinch roll unit 5. In this case, it
is important that the flow rate of the high speed air flow inside the transfer guide
4 is measured by means of a flow meter (not shown), while the tape passing rate of
the metallic tape 2 is measured by means of a tachometer (not shown) based on the
rotating rate of the cooling roll 1, whereby the flow rate of the high speed air flow
is set above the measured tape feeding speed.
[0038] Such a flow rate of the high speed air flow inside the transfer guide 4 can be adjusted
and set to a given value by changing at least one of suction amount of the blower
8, air jetting quantity of the air knife 3, clearance 10 between the cooling roll
1 and the transfer guide 4 and inner shape of the transfer guide 4.
[0039] In this connection, it has been found that the collision of the metallic tape with
the inner wall of the transfer guide can substantially be avoided when the flow rate
of the high speed air flow in at least a last half of the transfer guide is made faster
than the tape feeding speed of the metallic tape.
[0040] Furthermore, the rapture of the rapidly quenched metallic tape on the inner wall
face of the transfer guide can be prevented by limiting the length of the transfer
guide to a range of 10 cm - 100 cm. The reason on such a limitation of the transfer
guide length will be described with respect to the following concrete experimental
data.
[0041] The transfer guide 4 was arranged as shown in Fig. 1, and the length of the transfer
guide was varied over a range of 10 cm to 200 cm. While, the high speed air flow of
about 35 m/sec was formed inside the transfer guide 4 by means of the blower 8 behind
the pinch roll unit 5.
[0042] The amorphous alloy tape peeled off with the air knife 3 was smoothly guided into
the transfer guide 4 and caught by the pinch roll unit 5 after the confirmation of
passing the tape between the brush roll 5a and the solid roll 5b constituting the
pinch roll unit 5 at an open state, during which the time for catching the tape was
measured to obtain results as shown in Fig. 6. As seen from Fig. 6, when the transfer
guide length is not more than 100 cm, the catching of the tape is in 10 seconds. If
the length exceeds 100 cm, the catching becomes considerably difficult, because it
is considered that as the length of the transfer guide becomes long, the probability
of rapturing the tape on the inner wall of the transfer guide through collision becomes
high. While, when the transfer guide length is less than 10 cm, the high speed air
flow required for the catching through the pinch roll unit 5 can not stably be formed.
[0043] According to the invention, the metallic tape peeled off from the cooling roll is
passed through the transfer guide to the pinch roll unit at substantially non-contact
state to the inner wall of the transfer guide by means of a deflector roll having
a function as an air floater located at the entrance side of the transfer guide. For
this end, the deflector roll is arranged at the entrance side of the transfer guide
at such a certain space upward from the bottom of the transfer guide that air sufficiently
passes between the deflector roll and the bottom of the transfer guide so as not to
disturb the air flow required for controlling the flying posture of the metallic tape
flying inside the transfer guide.
[0044] The deflector roll is constructed so as to make constant the formation of pass line
between the peeling point from the cooling roll and the pinch roll unit when tension
is applied to the metallic tape peeled off from the cooling roll by the action of
the pinch roll unit and to serve as an air floater for eliminating the friction with
the deflector roll. Furthermore, in order to provide good flying posture of the metallic
tape before the catching by the pinch roll unit, there is a space between the deflector
roll and the transfer guide that air flow sufficiently flows toward the delivery side
of the transfer guide. Moreover, the deflector roll is provided with air jet ports
14 jetting air as an air floater for causing no friction between the pass line of
the metallic tape after the catching and the deflector roll. If necessary, an apron
(guide plate) 15 smoothly flowing air flow inside the transfer guide may effectively
be arranged on the lower face of the deflector roll in order to make the disturbance
of air flow inside the transfer guide through the deflector roll.
[0045] The deflector roll 7 acts to form an adequate pass line when tension is applied to
the caught metallic tape. Particularly, it can be said that the deflector roll 7 is
effective to form the adequate pass line when the setting position of the transfer
guide 4 changes in the height direction of the cooling roll.
[0046] Furthermore, the use of the deflector roll as mentioned above brings about the following
unexpected results which have never been observed by VTR:
(1) When the metallic tape is caught by the pinch roll unit, it is straight tensioned
between the pinch roll unit and the cooling roll. If the deflector roll is existent
therebetween, the pass line of the metallic tape is formed between the deflector roll
and the cooling roll, and consequently the stable peeling point can be maintained
irrespective of the air flow from the air knife;
(2) The tension is instantly applied to the metallic tape in the catching through
the pinch roll unit, but the metallic tape is raptured by the deflector roll immediately
thereafter;
(3) The metallic tape is instantly closed to the deflector roll in the catching through
the pinch roll unit;
(4) The metallic tape collides with the bottom face of the transfer guide to cause
the rapture thereof even after it is separated downward from the deflector roll;
(5) It is frequently observed that the metallic tape flying inside the transfer guide
is beaten onto the bottom of the transfer guide in the vicinity of the entrance side
thereof by the downward air flow from the air knife.
[0047] Thus, the deflector roll is essential to form the pass line between the pinch roll
unit and the cooling roll, but brings about the rapture of the metallic tape, which
is a cause that tension is not applied to the amorphous alloy tape through the pinch
roll unit.
[0048] As a result of the investigations on such a cause, it has been found that when the
metallic tape caught by the pinch roll unit while applying tension thereto comes into
contact with the deflector roll, friction is generated to the metallic tape on the
surface of the deflector roll and consequently there is caused a so-called sticking
phenomenon that tension is different between the upstream and the downstream about
the deflector roll. That is, the difference in the speed of the metallic tape between
the upstream and the downstream of the deflector roll is caused to lower the speed
at the upstream than the tape feeding speed, whereby the slacking of the tape is caused
to collide on the deflector roll.
[0049] Such a problem has been completely solved by adapting an air floater comprised of
plural air jet ports 14 to the tape-passing face of the deflector roll as a means
for solving the sticking.
[0050] Although the metallic tape is caught without the rapture through the deflector roll
provided with the air floater, a phenomenon that the tape is beaten onto the bottom
of the transfer guide immediately after the passing through the deflector roll to
cause rapture has further been confirmed by VTR. This is based on the air flow about
the deflector roll. That is, air drawn into the transfer guide through the suction
force of the blower is lost in the vicinity of the bottom of the transfer guide at
the entrance side thereof by the deflector roll, and consequently the metallic tape
is subjected to downward force by the air flow from the air knife for peeling the
metallic tape.
[0051] For this end, a clearance is formed between the deflector roll and the bottom of
the transfer guide to form an air flow therebetween. As a result, it has been confirmed
that air flowing through the clearance has an air flow rate enough to push the metallic
tape upward and cause no rapture. Furthermore, the air flowing through the clearance
largely acts to push the posture of the metallic tape flying inside the transfer guide
upward at the initial stage between the peeling from the cooling roll and the catching
through the pinch roll unit, and consequently the inconvenience of colliding the flying
metallic tape onto the bottom of the transfer guide before the catching is considerably
improved.
[0052] In order to more smoothly flow air through the clearance between the deflector roll
and the bottom of the transfer guide, an apron 15 is attached to the deflector roll,
which is effective to solve a wavy phenomenon of the metallic tape due to discontinuous
tension change.
[0053] The following examples are given in illustration of the invention and are not intended
as limitations thereof.
Example 1
[0054] A molten alloy having a composition of 10 atomic % (hereinafter referred to as "at%")
of B, 9 at% of Si, 1 at% of C and the balance being Fe was kept at 1,300°C, and ejected
onto an uppermost portion of a cooling roll made of a copper alloy and rotating at
a high speed (25 m/sec) through a slit-like nozzle having a width of 100 mm to produce
an amorphous alloy tape of 25 »m in thickness. As shown in Fig. 1, the axis of a transfer
guide 4 was substantially directed toward the center of the cooling roll 1. A high
speed air flow was formed inside the guide by means of a blower behind a pinch roll
unit.
[0055] Then, the alloy tape was peeled off from the cooling roll with an air knife, and
introduced into the transfer guide. While the peeled alloy tape was smoothly guided
inside the transfer guide, it was led to an opened state pinch roll unit constituted
by a brush roll and a solid roll. After the tape passed between the rolls, it was
caught by pressing down the brush roll against the solid roll. The metallic tape flying
inside the transfer guide did not contact upper and lower faces and side faces of
an inner wall of the transfer guide at least with impact.
[0056] In this case, it was confirmed that a stable tension was applied to the amorphous
alloy tape flying inside the transfer guide by the pinch roll unit under rotation
at a speed higher than that of the cooling roll by about 2 m/sec, while the tape was
not raptured inside the transfer guide, and that the tape could be transferred by
moving the pinch roll unit with use of a transfer truck.
Example 2
[0057] A molten alloy having a composition of 10 at% of B, 9 at% of Si, 1 at% of C and the
balance being Fe was kept at 1,300°C, and ejected onto an uppermost portion of the
copper alloy cooling roll rotating at a high speed (25 m/sec) through the slit-like
nozzle having a width of 100 mm to produce an amorphous alloy tape of 25 »m in thickness.
[0058] Then, the alloy tape was peeled off from the cooling roll with the air knife, and
guided into the transfer guide. In order to prevent the alloy tape from sticking against
the inner wall of the guide during flying in the guide, the width of an air flow from
the air knife was adjusted by advancing or retracting an adjusting plate so that the
alloy tape might smoothly fly inside the guide at a substantially non-contact state.
The alloy tape was guided to the opened state pinch roll unit constituted by the brush
roll and the solid roll. After the alloy tape was passed through the rolls, it was
caught by pressing down the brush roll against the solid roll. The alloy tape flying
inside the transfer guide did not contact the upper and lower faces and the side faces
of the inner wall of the transfer guide at least with impact.
[0059] In this case, it was confirmed that a stable tension was applied to the amorphous
alloy tape by the pinch roll unit under rotation at a speed higher than that of the
cooling roll by about 2 m/sec, while the alloy tape flying inside the transfer guide
was not raptured in the guide, and that the alloy tape could be transferred by moving
the pinch roll unit with the transfer truck.
Example 3
[0060] A molten alloy having a composition of 10 at% of B, 9 at% of Si, 1 at% of C and the
balance being Fe was kept at 1,300°C, and ejected onto an uppermost portion of the
copper alloy cooling roll rotating at a high speed (25 m/sec) through the slit-like
nozzle having a width of 100 mm to produce an amorphous alloy tape of 25 »m in thickness.
[0061] Then, the alloy tape was peeled off from the cooling roll with the air knife by using
the apparatus shown in Fig. 1. When the alloy tape was to be guided into the transfer
guide, a high speed air flow was preliminarily formed inside the transfer guide by
means of the suction blower behind the pinch roll unit as shown in Figs. 4a through
4d. Fig. 4a shows the shape of the transfer guide and planes at which the flow rate
of the air stream was measured. Figs. 4b, 4c and 4d show flow rates at the planes
α, β and γ and respectively, by lengths of arrows and figures (m/s) given thereunder.
At that time, the maximum flow rate of the air flow was 30 m/sec at the rear half
portion of the transfer guide as shown in Figs 4b to 4d.
[0062] The amorphous alloy tape peeled with the air knife was smoothly guided inside the
transfer guide. After it was confirmed that the amorphous alloy tape passed through
the opened state pinch roll unit constituted by the brush roll and the solid roll,
the tape was caught by pressing down lowering the brush roll against the solid roll.
The alloy tape flying inside the transfer guide did not contact the upper and lower
faces and the side faces of the inner wall of the transfer guide at least with impact.
A static image of the alloy tape introduced into the transfer guide was shown at a
scale of 1/50,000 in Fig. 5a. For the comparison, Fig. 5b shows a static image of
the alloy tape which contacted the bottom face of the tape transfer guide when the
flow rate of the air flow was smaller than that of passing the amorphous alloy tape.
[0063] In the case of Fig. 5a, it was confirmed that a stable tension was applied to the
amorphous alloy tape by the pinch roll unit under rotation at a speed higher than
that of the cooling roll is about 2 m/sec, while the tape flying inside the transfer
guide was not raptured in the guide, and the the metallic tape could be transferred
together with the pinch roll unit by moving the transfer table.
Example 4
[0064] A molten alloy having a composition of Fe₈₀B₁₀Si₉C₁ (at%) was kept at 1,300°C, and
ejected onto an uppermost portion of the copper alloy cooling roll rotating at a high
speed of 25 m/sec through the slit-like nozzle having a width of 100 mm to produce
an amorphous alloy tape of 25 »m in thickness. The transfer guide 4 was arranged as
shown in Fig. 1, and had a length of 60 cm. An air flow at a high speed of about 33
m/sec was formed inside the transfer guide 4 by the blower 8 behind the pinch roll
unit 5.
[0065] The amorphous alloy tape was peeled off with the air knife, and smoothly guided inside
the transfer guide. Then, after the tape was passed through the opened state pinch
roll constituted by the brush roll and the solid roll, the tape was surely caught
within 2 seconds by pressing down the brush roll against the solid roll.
[0066] In this case, it was confirmed that a stable tension was applied to the amorphous
alloy tape by the pinch roll unit under rotation at a speed higher than that of the
cooling roll by about 2 m/sec, while the tape flying inside the transfer guide was
not raptured in the guide, and that the tape could be transferred together with the
pinch roll unit by moving the transfer trolley.
Example 5
[0067] A molten alloy having a composition of 10 at% of B, 9 at% of Si, 1 at% of C and the
balance being Fe was kept at 1,300°C, and ejected onto an uppermost portion of the
copper alloy cooling roll rotating at a high speed of 25 m/sec through the slit-like
nozzle having a width of 100 mm to produce an amorphous alloy tape of 25 »m in thickness.
As shown in Fig. 1, a deflector roll had air jet ports on the side along which the
tape passed, and an air inflow opening was provided between the bottom plate of the
transfer guide and the deflector roll. A high speed air flow was formed inside the
transfer guide by sucking with the blower behind the pinch roll unit.
[0068] Then, the tape was peeled off from the cooling roll with the air knife, and guided
to the opened state pinch roll unit constituted by the brush roll and the solid roll.
After the tape passed through the pinch roll unit, the tape was caught by pressing
down the brush roll against the solid roll. Immediately after the tape was caught,
a tension was applied to the flying tape at a stretch so that a pass line was formed
between the pinch roll unit and the deflector. The tape was guided without rapture,
while the pass line was stabilized and the tape did not contact the deflector with
impact. Next, it was confirmed that a stable tension was applied to the amorphous
alloy tape by the pinch roll unit under rotation at a speed higher than that of the
cooling roll by about 2 m/sec, and that the tape could be transferred by moving the
pinch roll unit with the transfer table.
[0069] As mentioned above, according to the invention, the amorphous alloy tape produced
by the single roll method can be transferred and taken up without rapture. Thus, the
invention has great significance as a producing technique of metallic tapes.
1. A method of guiding and transferring a rapidly quenched metallic tape (2) including
the steps of
- peeling the rapidly guenched metallic tape (2) produced by solidification through
rapid quenching on a circumferential surface of a single cooling roll (1) rotating
at a high speed,
- introducing the metallic tape (2) into a cylindrical transfer guide (4) to a pinch
roll unit (5) arranged at a terminal end of the transfer guide (4) to catch the metallic
tape (2) by the pinch roll unit (5), and
- moving the pinch roll unit (5) to a winder for the metallic tape (2),
characterized by feeding said metallic tape (2) in the transfer guide (4) substantially
without being in contact with the transfer guide (4) by arranging said transfer guide
(4) in a flying direction of the metallic tape (2) peeled from the single cooling
roll (1), and by peeling said metallic tape (2) by jetting air of which amount is
adjusted.
2. A method as set forth in claim 1, wherein the metallic tape (2) is peeled by air jetting,
and high speed air flow directing from an entrance side to a delivery side of the
transfer guide (4) is caused by air suction on the delivery side of the transfer guide
(4) so that velocity of the air flow at least in a downstream half of the transfer
guide (4) is higher than a velocity of the metallic tape (2) fed in the transfer guide
(4).
3. A method as set forth in claim 2, wherein a flow rate of the high speed air flow is
adjusted by at least one of adjustments of an amount of the air suction on the delivery
side of the transfer guide (4), an amount of the air jetting for peeling the rapidly
quenched metallic tape (2) and a clearance between said single cooling roll (1) and
the transfer guide (4) and a modification of internal configuration of the transfer
guide (4).
4. A method as set forth in claim 1, wherein the metallic tape (2) is guided to the pinch
roll unit (5) by suction air by means of a blower (8) and a pass line for the metal
tape (2) is substantially formed by a deflector roll with an air floater provided
on an entrance side of the transfer guide (4).
5. An apparatus for guiding and transferring a rapidly quenched metallic tape (2) comprising
a cylindrical transfer guide (4) for introducing thereinto and guiding therein the
rapidly quenched metallic tape (2) produced by solidification through rapid quenching
on a circumferential surface of a single cooling roll (1) and peeled therefrom, the
axial line of said transfer guide (4) being located on a normal line of the single
cooling roll (1), at a position where the metallic tape (2) is peeled, a pinch roll
unit (5) arranged at a terminal end of the transfer guide (4) for catching the metallic
tape, and a transfer trolley (6) for transferring said pinch roll unit (5) to a winder
for the metallic tape (2), characterized in that said transfer guide (4) is arranged
adjacent said single cooling roll (1), and the apparatus further comprises an air
knife (3) for peeling the metallic tape (2) from the single cooling roll (1) by air
jetting, said air knife (3) being arranged extending from a downstream side of a rotating
direction of the single cooling roll (1) toward a clearance (10) between the single
cooling roll (1) and the transfer guide (4).
6. An apparatus as set forth in claim 5, comprising adjusting means (11) for adjusting
the clearance between the single cooling roll and the transfer guide.
7. An apparatus as set forth in claim 6, wherein said apparatus further comprises a suction
blower (8) arranged downstream of said pinch roll unit (5) for producing high speed
air flow in the transfer guide (4), a tachometer for detecting rotating speeds of
the single cooling roll (1), and a speed meter for detecting velocities of the high
speed air flow in the transfer guide (4).
8. An apparatus as set forth in claim 6, wherein said transfer guide (4) has a length
between 10 cm - 100 cm.
9. An apparatus as set forth in claim 6, wherein said apparatus further comprises a blower
for guiding the metallic tape (2) to the pinch roll unit (5) by suction air produced
by the blower, and a deflector roll (7) provided on an entrance side of the transfer
guide (4) to form a pass line for the metallic tape (2), and wherein a clearance between
the deflector roll (7) and a bottom plate of the transfer guide (4) is provided for
causing air to flow into the clearance by suction air of the blower.
1. Verfahren zur Führung und Übertragung eines schnell abgeschreckten Metallbands (2),
umfassend die folgenden Schritte:
- Ablösen des schnell abgeschreckten Metallbands (2), das durch Erstarrenlassen durch
schnelles Abschrecken auf einer Mantelfläche einer mit hoher Geschwindigkeit rotierenden
einzigen Kühlwalze (1) erzeugt worden ist,
- Einführen des Metallbands (2) in eine zylindrische Übertragungsführung (4) zu einer
an deren hinterem (terminal) Ende angeordneten Klemmwalzeneinheit (5) zum Erfassen
des Metallbands (2) durch die Klemmwalzeneinheit (5) und
- Verschieben der Klemmwalzeneinheit (5) zu einer Aufwickeleinheit für das Metallband
(2),
gekennzeichnet durch Zuführen des Metallbands (2) in der Übertragungsführung (4)
im wesentlichen ohne Berührung mit letzterer durch Anordnen der Übertragungsführung
(4) in einer "Flug-" oder Schweberichtung des von der einzigen Kühlwalze (1) abgelösten
Metallbands (2) und Ablösen des Metallbands (2) durch Ausblasen von Luft in einer
eingestellten Menge.
2. Verfahren nach Anspruch 1, wobei das Metallband (2) durch Luftausblasung abgelöst
wird und ein von einer Einlaufseite zu einer Auslaßseite der Übertragungsführung (4)
gerichteter Hochgeschwindigkeit-Luftstrom durch Luftansaugung an der Auslaßseite der
Übertragungsführung (4) so erzeugt wird, daß die Geschwindigkeit des Luftstroms zumindest
in der stromabseitigen Hälfte der Übertragungsführung (4) höher ist als eine Geschwindigkeit
des in der Übertragungsführung (4) geführten Metallbands (2).
3. Verfahren nach Anspruch 2, wobei eine Strömungsgeschwindigkeit des Hochgeschwindigkeit-Luftstroms
mittels mindestens einer Einstellung etwa einer Luftansaugmenge an der Auslaßseite
der Übertragungsführung (4), einer Menge der Ausblasluft zum Ablösen des schnell abgeschreckten
Metallbands (2) und eines Zwischenraums zwischen der einzigen Kühlwalze (1) und der
Übertragungsführung (4) sowie einer Abwandlung der Innenkonfiguration der Übertragungsführung
(4) eingestellt wird.
4. Verfahren nach Anspruch 1, wobei das Metallband (2) durch Saugluft mittels eines Gebläses
(8) zur Klemmwalzeneinheit (5) geleitet wird und eine Durchlauflinie für das Metallband
(2) im wesentlichen durch eine an einer Einlaufseite der Übertragungsführung (4) angeordnete
Ablenkwalze mit einer (einem) Luftleitfläche oder -lager gebildet wird.
5. Vorrichtung zur Führung und Übertragung eines schnell abgeschreckten Metallbands (2),
umfassend eine zylindrische Übertragungsführung (4) zum Einführen des schnell abgeschreckten
Metallbands (2), das durch Erstarrenlassen durch schnelles Abschrecken auf einer Mantelfläche
einer einzigen Kühlwalze (1) erzeugt und von ihr abgelöst oder abgestreift worden
ist, in diese Führung und Leiten des Metallbands darin, wobei die Achslinie der Übertragungsführung
(4) an einer Stelle, an welcher das Metallband (2) abgelöst wird, auf einer Linie
senkrecht zur einzigen Kühlwalze (1) angeordnet ist, eine an einem hinteren (terminal)
Ende der Übertragungsführung (4) angeordnete Klemmwalzeneinheit (5) zum Erfassen des
Metallbands und einen Transportwagen (6) zum Übertragen bzw. Abführen der Klemmwalzeneinheit
(5) zu einer Aufspuleinheit für das Metallband (2), dadurch gekennzeichnet, daß die
Übertragungsführung (4) neben der einzigen Kühlwalze (1) angeordnet ist und die Vorrichtung
ferner eine Luftrakel (3) zum Ablösen oder Abstreifen des Metallbands (2) von der
einzigen Kühlwalze (1) durch Luftausblasung umfaßt, wobei die Luftrakel (3) so angeordnet
ist, daß sie sich von einer Stromabseite einer Rotationsrichtung der einzigen Kühlwalze
(1) in Richtung auf einen Zwischenraum (10) zwischen der einzigen Kühlwalze (1) und
der Übertragungsführung (4) erstreckt.
6. Vorrichtung nach Anspruch 5, umfassend eine Einstelleinrichtung (11) zum Einstellen
des Zwischenraums zwischen der einzigen Kühlwalze und der Übertragungsführung.
7. Vorrichtung nach Anspruch 6, wobei die Vorrichtung ferner umfaßt: ein der Klemmwalzeneinheit
(5) nachgeschaltetes Sauggebläse (8) zur Erzeugung eines Hochgeschwindigkeit-Luftstroms
in der Übertragungsführung (4), ein(en) Tachometer (Drehzahlmesser) zum Messen der
Drehgeschwindigkeiten der einzigen Kühlwalze (1) und einen Geschwindigkeitsmesser
zum Messen der Geschwindigkeiten des Hochgeschwindigkeit-Luftstroms in der Übertragungsführung
(4).
8. Vorrichtung nach Anspruch 6, wobei die Übertragungsführung (4) eine Länge zwischen
10 cm und 100 cm aufweist.
9. Vorrichtung nach Anspruch 6, ferner umfassend ein Gebläse zum Führen des Metallbands
(2) zur Klemmwalzeneinheit (5) mittels des vom Gebläse erzeugten Luftsogs und eine
an einer Einlaufseite der Übertragungsführung (4) vorgesehene Ablenkwalze (7) zur
Bildung einer Durchlauflinie für das Metallband (2), wobei zwischen der Ablenkwalze
(7) und einer Bodenplatte der Übertragungsführung (4) ein Zwischenraum vorgesehen
ist, um mittels des Luftsogs des Gebläses Luft in den Zwischenraum einströmen zu lassen.
1. Un procédé pour guider et transférer une bande métallique trempée (2), comportant
les phases consistant à
- retirer par pelage la bande métallique trempée (2) produite par solidification de
trempage sur la surface circonférencielle d'un rouleau unique de refroidissement (1)
tournant à grande vitesse,
- introduire la bande métallique (2) dans un guide cylindrique de transfert (4) vers
une unité de pinçage (5) à rouleaux disposée à l'extrémité terminale du guide de transfert
(4) pour saisir la bande métallique (2) par l'unité de pinçage (5) à rouleaux, et
- déplacer l'unité de pinçage (5) à rouleaux vers un bobinoir pour la bande métallique
(2),
caractérisé par la fourniture de ladite bande métallique (2) dans le guide de transfert
(4) sensiblement sans qu'elle soit en contact avec le guide de transfert (4), en agençant
ledit guide de transfert (4) dans la direction de vol de la bande métallique (2) prélevée
par pelage du rouleau unique (1) de refroidissement, et en retirant par pelage ladite
bande métallique (2) par un jet d'air dont la quantité est ajustée.
2. Un procédé selon la revendication 1, dans lequel la bande métallique (2) est retirée
par pelage à l'aide d'un jet d'air, et l'écoulement d'air à grande vitesse dirigé
depuis le côté entrée jusqu'au côté sortie du guide de transfert (4) est provoqué
par une aspiration d'air du côté sortie du guide de transfert (4), de manière que
la vitesse de l'écoulement d'air, au moins dans la moitié aval du guide de transfert
(4), est supérieure à la vitesse de la bande métallique (2) délivrée dans le guide
de transfert (4).
3. Un procédé selon la revendication 2, dans lequel le débit de l'écoulement d'air à
grande vitesse est réglé par au moins l'un des réglages de la quantité d'aspiration
d'air du côté sortie du guide de transfert (4), de la quantité du jet d'air pour retirer
par pelage la bande métallique trempée (2) et de l'espace entre ledit rouleau unique
de refroidissement (1) et le guide de transfert (4), et de la modification de la configuration
interne du guide de transfert (4).
4. Un procédé selon la revendication 1, dans lequel la bande métallique (2) est guidée
vers l'unité de pinçage (5) à rouleaux par l'air d'aspiration au moyen d'un ventilateur
(8), et une ligne de passage pour la bande métallique (2) est formée sensiblement
par un rouleau déflecteur, un flotteur à air étant prévu du côté entrée du guide de
transfert (4).
5. Un dispositif pour guider et transférer une bande métallique trempée (2) comportant
un guide cylindrique de transfert (4) pour l'introduction et le guidage dans celui-ci
de la bande métallique trempée (2) produite par solidification de trempage sur la
surface périphérique d'un rouleau unique de refroidissement (1) et retirée de celui-ci
par pelage, la ligne axiale du guide de transfert (4) étant située sur une ligne normale
du rouleau unique de refroidissement (1), en une position où la bande métallique (2)
est retirée par pelage, une unité de pinçage (5) à rouleaux disposée à l'extrémité
terminale du guide de transfert (4) pour saisir la bande métallique, et un chariot
de transfert (6) pour transférer ladite unité de pinçage (5) à rouleaux vers un bobinoir
pour la bande métallique (2), caractérisé en ce que ledit guide de transfert (4) est
disposé en adjacence audit rouleau unique de refroidissement (1), et en ce que le
dispositif comporte au surplus un couteau à air (3) pour retirer par pelage la bande
métallique (2) du rouleau unique de refroidissement (1) par un jet d'air,ledit couteau
à air (3) étant agencé pour s'étendre depuis l'aval, en considérant le sens de rotation
du rouleau unique de refroidissement (1), vers un espace (10) entre le rouleau unique
de refroidissement (1) et le guide de transfert (4).
6. Un dispositif selon la revendication 5, comportant des moyens de réglage (11) pour
régler l'espace entre le rouleau unique de refroidissement et le guide de transfert.
7. Un dispositif selon la revendication 6, dans lequel ledit dispositif comporte au surplus
un ventilateur (8) disposé en aval de ladite unité de pinçage (5) à rouleaux pour
produire un écoulement d'air à grande vitesse dans le guide de transfert (4), un tachymètre
pour détecter la vitesse de rotation du rouleau unique de refroidissement (1), et
un compteur de vitesse pour détecter la vitesse de l'écoulement d'air à grande vitesse
dans le guide de transfert (4).
8. Un dispositif selon la revendication 6, dans lequel ledit guide de transfert (4) présente
une longueur comprise entre 10 cm et 100 cm.
9. Un dispositif selon la revendication 6, dans lequel ledit dispositif comporte au surplus
un ventilateur pour guider la bande métallique (2) vers l'unité de pinçage (5) à rouleaux
par l'air d'aspiration produit par le ventilateur, et un rouleau déflecteur (7) prévu
du côté entrée du guide de transfert (4) pour former une ligne de passage pour la
bande métallique (2), et dans lequel un espace entre le rouleau déflecteur (7) et
une plaque de fond du guide de transfert (4) est prévu pour amener l'air à circuler
dans l'espace par l'air d'aspiration du ventilateur.