JPS5954030B2 - Method and device for manufacturing metal foil laminates - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method and apparatus for manufacturing a metal foil-clad laminate suitable as a printed wiring board.

Conventionally, metal foil-clad laminates have been produced using clean and dust-free press plates made of stainless steel or the like with a smooth surface of 0.5 to 5.0 mm in thickness, and between the two press plates, the base material is A predetermined number of prepregs obtained by impregnating a thermosetting resin with a thermosetting resin or an adhesive sheet obtained by impregnating a thermoplastic resin as an adhesive are stacked together. (referred to as "Prepreg") Thickness 5 to 2 with or without adhesive on one or both sides of the outermost layer of prepreg for lamination
A 00 μm clean and dust-free metal foil is further overlaid with a release film if necessary, and then hot-press molded, and after hot-press molding, the press plate is separated from the metal foil.
Here, the press plates are used in circulation to obtain metal foil-clad laminates, but when manufacturing the above-mentioned laminates, the press plates and metal foils are cleaned and dust-free before hot-pressing. Dust floating in the air in the working environment and fibers and debris generated from the worker's clothing adhere to the space between the press plate and the metal foil, and the surface of the metal foil is damaged by this dust after the hot press. This is to prevent dents from occurring.

However, in this conventional method, the metal foil is manually cut to a size slightly larger than the size of the press plate, and then the metal foil is placed on the press plate. It also had the disadvantage that dust could get in there and dust could fly in and stick to it.

Recently, two metal foil rolls are used, one of which is unwound, a press plate is placed on top of this metal foil, and the other metal foil roll is placed on top of this press plate. is unraveled, the top and bottom surfaces of the press plate are continuously coated, the coated metal foil is bonded under pressure on at least two sides of the press plate, and the press plate is cut at the same time. A method for manufacturing foil-clad laminates was published in the Tokuko Publication Act in 1972-22.
No. 380, this method automates the press plate coating process to obtain a metal foil-clad laminate with a smooth surface without minute dents. The production equipment became larger due to the pressure bonding and cutting equipment, etc., which had the disadvantage of requiring a large installation area and large capital investment. Furthermore, even if the production volume per hour increases by automating the coating process of press plates, the next process, the process of overlapping the coated press plates and the prepreg for lamination, requires a lot of manpower and time. It was not possible to immediately shorten the overall production time of stretched laminates.

The present invention solves these problems; (a) a laminate with a smooth metal foil surface and no minute dents can be obtained; and (b) a press plate can be coated with metal foil. This coating press plate and prepreg for lamination can be laminated at the same time, shortening the overall manufacturing time, and (c) economical metal foil lamination with less equipment and no need for a large installation space. An object of the present invention is to provide a method and apparatus for manufacturing a board.

The first feature of the present invention is that the metal foil supplied from one metal foil roll is continuously folded onto a press plate and a laminating prepreg loading device, and every half cycle of the folding, the metal foil is Lamination plate 4. There is a manufacturing method in which repregs are alternately supplied between the metal foils.

A second feature of the present invention is a belt conveyor configured to carry a press plate and move forward or backward as a whole, a belt conveyor configured to carry a lamination prepreader and move forward or backward as a whole, and Between both belt conveyors is a loading device adjacent to both belt conveyors, which is configured to load press plates and laminating prepregs carried from the belt conveyors and whose height from the horizontal surface can be raised and lowered. A folding device that unwinds a metal foil roll and continuously folds the metal foil, and a folding device that alternately sandwiches the press plate and the laminating prepreg between the metal foils every half cycle of the operation of the folding device. and a control device for controlling both of the belt conveyors, the loading device, and the folding device.

Embodiments of the present invention will be described below based on the drawings.

FIG. 1 is a perspective view showing the basic structure of a press plate and a laminating prepreg sandwiched between metal foils according to an embodiment of the present invention.

In FIG. 1, 1 is a press plate, 2 is a prepreg for lamination, and 3 is a metal foil.

The press plate 1 is a stainless steel plate with a size of about 1 m 2 and a thickness of 2 mm, both sides of which are clean and dust-free.
The prepreg 2 for lamination has approximately the same size as the press plate 1, and is made by laminating a required number of prepregs made by impregnating a glass cloth base material with a thermosetting resin such as an epoxy resin. In addition, the metal foil 3 has one side smooth and the other side rough-finished, so that the screen is clean and dust-free, and the press plate 3 is designed to completely cover both sides of the press plate 1 and the laminating prepreg 2. It is a continuous sheet having a width slightly wider than that of 1 and prepreg 2 for lamination, and has a thickness of 35 μm.
m copper foil.

The press plate 1 and the prepreg for lamination 2 are alternately sandwiched between the metal foils 3 every half cycle of folding of the metal foil 3.

FIG. 2 is a configuration diagram of an apparatus for sandwiching a press plate and a laminating prepreg between metal foils.

In FIG. 2, reference numeral 5 denotes a loading device which alternately stacks the press plate 1 and the prepreg for lamination 2 while folding the metal foil 3, and stacks the press plate 1 and the prepreg for lamination 2 according to the loading amount of the press plate 1 and the prepreg for lamination 2. , the height of the top plate 6 placed on the loading device 5 from the horizontal plane rises and falls. Also, on both sides of the loading device 5,
A pair of belt conveyors 7 and 8 are installed, and a metal foil roll 10 is installed above the loading device 5. A clean and dust-free press plate 1 is transferred to the belt conveyor 7 from a transfer device (not shown), and a prepreg 2 for lamination is transferred to the belt conveyor 8 from a transfer device (not shown). Also, both ends of the central axis 11 of this metal foil roll 10 are
A folding device 12 is installed. This folding device 12 is provided with a swinging arm 14 that interlocks with the central shaft 11 and feed rollers 15 and 16. The folding device 12 interlocks with the drive of the belt conveyors 7 and 8, and folds the metal foil roll 10.
, and fold the metal foil 3 onto the top plate 6 of the loading device 5. Here, each drive of the loading device 5, belt conveyors 7 and 8, and folding device 12 is controlled by a control device 17.

That is, this control device 17 includes a lifting motor 18 for the loading device 5, a driving motor 19 for the belt conveyor 7, a driving motor 20 for the belt conveyor 8, and a folding device 12.
A drive motor 21 is electrically connected to the drive motor 21 . Further, at the rear end of the belt conveyor 7, a light emitter 22 and a photoelectric converter 23 are provided, and between the belt conveyor 7 and the loading device 5,
A light emitter 24 and a photoelectric converter 25 are provided, and a light emitter 26 and a photoelectric converter 27 are provided at the rear end of the belt conveyor 8, and a light emitter 26 and a photoelectric converter 27 are provided between the belt conveyor 8 and the loading device 5.
A light emitter 28 and a photoelectric converter 29 are provided, and the outputs of the photoelectric converters 23 , 25 , 27 , 29 are connected to the control device 17 . With such a configuration, the operation of the apparatus of this embodiment will be explained.

Place the cushion rubber 31. on the top plate 6 of the loading device 5 in advance. The press plate 1a, the metal foil 3a, and the laminating prepreg 2a are stacked in this order.

First, the press plate 1 is transferred to the belt conveyor 7 from a transfer device (not shown). At this time, when the press plate 1 blocks the light from the light emitter 22, the motor 19 of the belt conveyor 7 starts to drive and moves forward while carrying the press plate 1. At the same time, the swing arm 14 of the folding device 12 and the feed roller 15, 16 is activated, the metal foil cap 10 is released, and the metal foil 3 is spread on the top plate 6 of the loading device 5. Next, the rollers 7 of the belt conveyor 7
When the light from the light emitter 24 is blocked by the belt conveyor 7, the belt conveyor 7 reduces its forward speed, and the belt conveyor 7 is moved forward a certain period of time after the light is blocked.
Stops when a reaches the desired position above the top plate 6 (
Figure 2 a).

After the belt conveyor 7 has stopped, it now moves backwards and places the conveyed press plate on the metal foil 3 on the top plate 6.

Following the retreat of the belt conveyor 7, the folding device 12
A new metal foil 3 is spread on the press plate 1 which has been driven. The belt conveyor 7 transmits the light from the light emitter 24 to the photoelectric converter 2.
5, it stops at the original starting position. Further, as the folding device 12 operates, the height of the top plate 6 of the loading device 5 is lowered by the thickness of the press plate 1.

At the same time, the prepreg 2 for lamination is transferred to the belt conveyor 8 from a transfer device (not shown). The belt conveyor 8 starts to drive when the laminating prepreg 2 blocks the light from the light emitter 26.
When the prepreg 2 for lamination moves forward and the roller 8a of the belt conveyor 8 blocks the light from the light emitter 28, the belt conveyor 8 reduces its forward speed, and after a certain period of time has elapsed since the light was blocked, the roller 8a moves to the top plate 6. It stops when it reaches the desired position above (Figure 2, exit). After the belt conveyor 8 stopped, it moved backward this time to convey the laminating prepreader 2.
is placed on the metal foil 3 on the top plate 6.

After the light from the light emitter 28 enters the photoelectric converter 29 again, the Pelton pair 8 stops at the original starting position. Following the retreat of the belt conveyor 8, the height of the top plate 6 of the loading device 5 is lowered by the thickness of the laminating prepreg 2. Thereafter, each belt conveyor and device are driven repeatedly in the same manner.
While the metal foil 3 is being folded, the press plates 1 and the laminating prepregs 2 are stacked alternately. An example of the manufacturing process after stacking the press plate 1 and the laminating prepreg 2 between the metal foils 3 is shown in FIG.

In FIG. 3, the press plate 1 and the laminating prepreg 2 stacked between the metal foils 3 are hot-pressed in a press 32 (FIG. 3 A and B). After molding, the metal foil 3 is stuck to the laminating prepreg 2, so the folded portion of the metal foil 3 is cut and the press plate 1 is separated to obtain a metal foil-covered laminate 33. The separated press plate 1 is cleaned and dust-free and used for circulation. In the above example, the thickness of the press plate is 2 mm.
Although the example is shown, the thickness may be 0.5 to 5.0 mm.

Further, the material of the press plate may be a metal other than stainless steel. In addition, the prepreg for lamination has been shown as an example in which the required number of prepregs made of glass cloth impregnated with a thermosetting resin such as epoxy resin are laminated together, but glass paper, paper, glass fiber, synthetic fiber mixed paper, Epoxy resin, phenolic resin,
The required number of prepregs impregnated with a thermosetting resin such as polyester resin or polyimide resin or a thermoplastic resin such as Teflon resin may be stacked together.Also, as for the metal foil, an example with a thickness of 35 μm is shown, 5-2
It may have a thickness of 00 μm.

The material is not limited to copper, but may also be nickel, aluminum, Kovar alloy, or the like. Further, both surfaces of the metal foil may be smoothed. Further, although an example of optical detection means has been shown as a detection means serving as an input to the control system, means using magnetism, electromagnetic waves, contact, etc. may also be used, and it is preferable that the control device is an automatic control device. Furthermore, two other steps, such as a metal foil cleaning step, may be added in the middle of the steps described in the above embodiments.

Further, although an example has been shown in which the prepreg for lamination is placed on the metal foil by a belt conveyor, the prepreg for lamination may be placed manually. Furthermore, the folding device may be one that moves back and forth in the same direction as the driving direction of the belt conveyor while rotating the feed roller 2 roller without using the swing arm. According to the invention, by alternately stacking the press plate and the laminating preplayer between the continuously folded metal foils, (a) adhesion of dust, etc. to the press plate and the metal foil is prevented; A laminate with no minute dents can be obtained, and (b) the work of covering the press plate with metal foil and the work of overlapping the coated press plate with the prepreg for lamination can be done simultaneously and with an extremely small number of hands; The manufacturing time for the entire metal foil-clad laminate can be shortened, and (c) the number of devices is small and a large installation space is not required, resulting in an excellent economical effect.

[Brief explanation of the drawing]

Figure] is a perspective view showing the basic structure of a press plate sandwiched between metal foils and a laminating prepreg according to an embodiment of the present invention. FIG. 2 is a configuration diagram of an apparatus for sandwiching a press plate and a prepreg for lamination between metal foils according to an embodiment of the present invention. FIG. 3 is a manufacturing process diagram of a metal foil-clad laminate according to an embodiment of the present invention. 1...Press plate, 2...Prepreg for lamination, 3.
... Metal foil, 5... Loading device, 6... Top plate, 7, 8
... Belt conveyor, 10 ... Metal foil roll, 11
... central axis, 12 ... folding device, 14 ... rocking arm, 15, 16 ... feed roller, 17 ... control device,
18... Lifting motor, ] 9120, 21... Drive motor, 22, 24, 26, 28... Light emitter, 23
, 25, 27, 29... Photoelectric converter, 31... Cushion rubber 32... Press, 33... Metal foil clad laminate.

Claims (1)

[Scope of Claims] 1. The press plate is pressed so that when the metal foil is attached to the prepreg for lamination, the surface of the metal foil is in close contact with the press surface of the clean and dust-free press plate. A method for manufacturing a metal foil-clad laminate, which includes a step of coating with metal foil and a step of overlapping a press plate coated with the metal foil and the prepreg for lamination, in which the metal foil is supplied from a single metal foil roll. The metal foil is continuously folded onto a press plate and a laminating prepreg loading device, and the press plate and the laminating prepreg are alternately sandwiched between the metal foils every half cycle of folding. A method for manufacturing a metal foil-clad laminate, characterized by supplying the metal foil laminate. 2. A belt conveyor 7 configured to carry a press plate and move forward or backward as a whole, a belt conveyor 8 configured to carry a laminating prepreg and move forward or backward as a whole, and both belts between these belt conveyors. Adjacent to the conveyor is a loading device configured to load press plates and prepregs for lamination carried from the belt conveyor and to move up and down in height from the horizontal surface. A folding device that continuously folds the foil, and both belt conveyors 7, which alternately sandwich the press plate and the laminating prepreg between the metal foils every half cycle of the operation of the folding device. 8 and a control device for controlling the loading device and the folding device.