JPH041105B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a method for plating fiber bundles in which uniform plating is applied to the fiber bundles while unraveling them in a plating bath.

[Conventional technology]

In the method of plating fiber bundles in which continuously transported fiber bundles are plated in a plating bath, it has traditionally been difficult to spread out the bundled fiber bundles and apply uniform plating to each fiber strand. This is a common technical issue. As a method to solve this problem, a method is proposed in which a nozzle is installed in the plating tank to create a jet of plating liquid, and the hydrodynamic resultant force of the jet is used to spread the fibers and at the same time make the plating uniform. Publication No. 57-77342, Japanese Patent Publication No. 58-174593
Publication No. 193391, Japanese Patent Application Publication No. 1983-19339, Japanese Patent Application Publication No. 1987-
Publication No. 215497, Japanese Patent Publication No. 60-119269, Publication No. 119269, Japanese Patent Publication No.
It is disclosed in Publication No. 60-141895 and the like. In this method, for example, as shown in FIG.
The fiber bundle 3 is passed through the plating liquid 2 in the plating solution 2, and if the fiber bundle 3 is conductive, plating is performed by applying a predetermined potential between the cathode electrode roller 4 and the anode plate 5, for example. A jet nozzle 6 is provided in the plating tank 1. When the fiber bundle 3 is taken up by the take-up roller 7, it is controlled to apply a predetermined tension using a dancer roll 8 or the like. And the jet nozzle 6
The fiber bundle 3 being transferred is opened by the jet stream from the fiber bundle 3 .

[Problem that the invention seeks to solve]

However, in the above method,
Since tension is applied to the fiber bundle 3 transported through the plating liquid 2, the strength of the jet must be considerably increased in order to spread the fibers by the jet flow in the plating liquid. The agitation of high-metallic liquid becomes considerably stronger. The fiber bundle 3 is usually made up of several thousand wires of several micrometers in diameter, but due to the tension and jet flow, some of the fibers may break or the cut fibers may wrap around the fiber bundle 3. There is a risk that problems may occur. Therefore, in the end, it was not possible to sufficiently perform the appropriate fiber opening required for uniform plating.

In order to eliminate the adverse effects of such a jet flow, for example, as shown in FIGS. 4 and 5, the fiber bundle 3 is placed on a belt conveyor 9 or 10 and transported, and the fiber bundle on the belt conveyor 9 or 10 is transported. 3 in a tension-free state and opening the tension-free fiber bundle 3 with a relatively weak jet stream is also considered, but if the fiber bundle 3 meandering randomly on the belt conveyor 9 or 10 or its strands is There remains the problem that they may become entangled with each other, resulting in a slight decrease in operability.

An object of the present invention is to provide a method that can prevent single yarn breakage in conventional methods using jet flow, open fiber bundles efficiently and appropriately, and uniformly plate the fiber bundles without causing any trouble. It is in.

[Means for solving problems]

The fiber bundle plating method of the present invention which meets this objective is a fiber bundle plating method in which continuously transported fiber bundles are plated in a plating bath. It consists of a method in which the fiber bundle is placed on a bar and passed over the rocking bar, and the rocking bar is rocked in the fiber bundle transport direction, thereby plating the fiber bundle while unraveling it.

The fiber bundle is suitably relaxed and transported in the plating bath, and the relaxed fiber bundle is placed on a rocking bar and passed over the rocking bar. The swing bar is not particularly limited mechanically as long as it can pass the fiber bundle over it while guiding the fiber bundle appropriately and can reciprocate in the direction along the fiber bundle transport. In particular, it is preferable to oscillate in a single pendulum shape.

[Effect]

In such a method, since the fiber bundle is moderately relaxed in the plating bath, the fiber bundle is maintained in a state of minimal tension or a state close to substantially no tension. The swinging of the swinging bar generates a reciprocating flow due to agitation of the plating liquid in the fiber bundle transfer direction, but by keeping the swinging speed of the swinging bar to an appropriate low level, a gentle agitation of the liquid flow is generated. can be done. Since the agitation is gentle, large forces are not applied locally to the fiber bundle, preventing the occurrence of single yarn breakage, and the unraveling action of the fiber bundle due to the reciprocating flow,
Extremely uniform opening is possible. As a result, uniform plating is applied to each appropriately opened fiber strand without causing any trouble.

〔Example〕

Preferred embodiments and specific implementation results of the present invention will be described below with reference to the drawings.

1 and 2 show an apparatus for carrying out a method according to an embodiment of the invention. Although this device uses a two-stage bathtub, the number of stages may be arbitrary. In the figure, 11 is a plating tank, 12
13 indicates a plating liquid contained therein, and 13 indicates a fiber bundle that is sequentially and continuously transferred through the plating liquid 12.

The present invention can be applied to any of conductive materials such as carbon, inorganic non-conductive materials such as boron, silicon carbide, alumina, or synthetic fiber materials such as nylon and polyethylene terephthalate as the fiber bundle 13. As the plating method, either electric plating or electroless plating can be applied. In this embodiment, the fiber bundle 13 is made of a conductive material, and a metal roller 14 as a cathode electrode is provided outside the plating tank 11, and an electrode plate 15 as an anode electrode is provided in the plating solution 12. The required potential is applied to the

The fiber bundle 13 is continuously transported in the direction of the arrow in the figure by the nip roller 16 and the cathode roller 14, and is sufficiently immersed in the plating liquid 12 by passing under the fixed bar 17.

Inside the plating bath (plating liquid 12 in the plating tank 11)
A swing bar 18 is provided in the middle), and the fiber side 13 is located on the lower surface side of the fixed bar 17, and the swing bar 18
It passes through the upper surface side and the lower surface side of the fixing bar 17 in this order. This swing bar 18 is centered around a fulcrum 19.
The swing bar 18 swings at a relatively low speed in a single pendulum-like manner (in the direction of the arrow in the figure) in the transport direction. The fixed bar 1 is arranged so that the swing bar 18 can swing.
Between 7 and 17, the fiber bundle 13 is moderately relaxed.

Regarding the swing bar 18 and its swing mechanism,
It is not limited to the structure shown in FIGS. 1 and 2, and any structure that can reciprocate in the transport direction of the fiber bundle 13 may be used.In addition to the structure that swings in an arc shape as shown in FIG. It may be one that moves back and forth.
Further, in order to prevent the path length of the fiber bundle 13 between the fixed bars 17, 17 from changing as much as possible, the structure may be such that the fiber bundle 13 swings in an arc shape that is upside down from that shown in FIG. As the swing drive source for the swing bar 18, any known suitable source may be used.

The method of the present invention is carried out as follows using the apparatus as described above.

The fiber bundle 13 is fed into the plating tank 11 by a cathode electrode roller 14 and a nip roller 16 on the entrance side, and between the entrance side rollers 14, 16, intermediate rollers 14, 16, and between the intermediate rollers 14, 16 and the exit side. plating tank 11 between the rollers 14 and 16 of
It is pulled out by the cathode electrode roller 14 and the nip roller 16 on the exit side while the inner relaxation length is kept substantially constant. Fiber bundle 1 immersed in plating liquid 12
3 is a fixed bar 17, a swing bar 18, and a fixed bar 1.
However, since the swing bar 18 is swung in the direction of transporting the fiber bundle 13, agitation of a gentle liquid flow that reciprocates in the direction of transport of the fiber bundle 13 is generated in the vicinity of the swing bar 18. As a result of this agitation, the relaxed fiber bundle 13 is appropriately decondensed and spread, particularly in the width direction of the plating tank, as shown in FIG.

This fiber opening is performed in conjunction with the agitation described above, and the agitation caused by the gentle rocking of the rocking bar 18 is much weaker than the conventional jet flow, and the fiber bundle 13 is much weaker than the conventional jet flow. Since the fiber bundle is moderately relaxed in this part and has almost no tension, no breakage of single threads will occur in the fiber bundle, and therefore no trouble will occur where broken single threads will become entangled. Furthermore, since the swinging bar 18 is continuously oscillated, the fiber bundles 13 being transferred are successively opened in good order. Furthermore, although the fiber bundle 13 is relaxed, it is guided along a substantially constant path on the swing bar 13, so the fiber bundle 13 is guided along a substantially constant path on the swing bar 13.
There is no chance for the three to become entangled with each other.

Since the fiber bundle 13 passes through the plating liquid 12 while being spread appropriately and uniformly, each spread fiber strand is uniformly plated.

The opened fiber bundle 13 then passes through a fixed bar 17 and rollers 14, 16 whose positions are fixed, and is appropriately focused again.

Using the device as described above, a single fiber with a diameter of 7μ is produced.
A carbon fiber bundle consisting of 6,000 fibers was plated. The fiber bundle 13 is brought into contact with the cathode electrode roller 14, a nickel plate is provided as the anode electrode plate 15, and the swing bar 18
When plating was performed while opening the fibers by swinging the fibers, a uniform plating yarn with no single yarn breakage was obtained. The composition of the plating liquid is nickel sulfate 150g/,
The pH of the plating solution was 6.0 and the temperature was 25°C in a normal bath containing 15 g of ammonium chloride and 15 g of boric acid.
The traveling speed of the carbon fiber bundle was 50 cm/min, the residence time in the plating bath was 3 minutes, and the plating was performed at a total current of 10 A.

〔Effect of the invention〕

As explained above, when using the fiber bundle plating method of the present invention, the fiber bundle can be uniformly opened in a substantially tension-free state by swinging the rocking bar in the plating bath, It is possible to achieve the effect that uniform plating without color tone unevenness, plating defects, etc. can be performed without causing troubles such as single thread breakage.

[Brief explanation of drawings]

FIG. 1 is a schematic side view of a plating device used for carrying out a fiber bundle plating method according to an embodiment of the present invention, FIG. 2 is a plan view of the device shown in FIG. 1, and FIG. FIG. 4 is a schematic side view of a plating device using a belt conveyor, and FIG. 5 is a schematic side view of another plating device using a belt conveyor. 11... plating tank, 12... plating liquid, 13...
... fiber bundle, 14 ... cathode electrode roller, 15 ... anode electrode plate, 16 ... nip roller, 17 ... fixed bar, 18 ... swinging bar, 19 ... fulcrum.

Claims (1)

[Claims] 1. A fiber bundle plating method in which a continuously transferred fiber bundle is plated in a plating bath, the fiber bundle being placed on a rocking bar provided in the plating bath and passing over the rocking bar, A method for plating a fiber bundle, characterized in that plating is performed while unraveling the fiber bundle by swinging the rocking bar in the fiber bundle transport direction.