FR2700288A1 - Cutter for dividing up composite base of printed circuit boards - Google Patents

Abstract

The cutter has a frame (1) with a flat plate which receives the pcb (6). A jack (5) moves the plate horizontally towards the cutting band (14) and the PCB is pushed by an integral parallelepiped or raised edge (10) on the side of the plate. A groove (11) with a lead-in point is previously cut in the PCB to receive the band.The cutting band may also take the form of a wire. The lead edge is rounded and is about 0.15 mm in width. The band is mounted on pulleys (13,15) so that it can be advanced to an unused edge after a certain number of cuts.

Description

 The invention relates to a cutting device for a composite printed circuit support and a method for cutting such a support.

 Composite printed circuit supports are generally manufactured in large dimensions to obtain the greatest possible manufacturing profitability, then cut after printing the circuits and / or installing the components. Thus, each support can carry a plurality of printed circuits, different from each other or identical, which are separated by cutting the support after the circuits have been printed and / or components installed.

 Currently, the supports are grooved and then manually sectioned by folding along these grooves. This operation exposes the supports to significant stresses, in particular causing tears in the conductive tracks of the printed circuits as well as possible breaks in the soldering of the components.

 The object of the invention is to remedy the aforementioned drawbacks.

 Another object of the invention is to propose a device and a method for sectioning composite supports producing practically no cutting residue.

 It is yet another object of the invention to provide a device and a method for sectioning composite supports making it possible to increase the density of the printed circuits carried by the supports and at the same time limit the number of circuits rendered unusable during the sectioning. This is particularly important when the components are surface welded.

 The object of the invention is achieved by a sectioning device for a composite printed circuit support formed of a fiber-reinforced polymer, with a frame on which is disposed a plate intended to receive the composite support to be cut. The plate is movable relative to the frame so as to allow its translation in at least one direction. The device further comprises a cutting means and a pusher device intended to push, via the plate, the composite support against the cutting means to obtain cutting of the composite support.

 According to the invention, the sectioning means of the sectioning device is a thin elongated static element, energized at least during sectioning.

 The sectioning means is distinguished from other sectioning means by the fact that it is not animated, at least while it acts on the composite support, of any longitudinal or circular movement. The sectioning of the support is then, as will be explained below, by transverse movement of the support relative to the longitudinal axis of the sectioning element.

The invention also relates to the following characteristics, considered in isolation or in all their technically possible combinations:
- The device is intended for cutting a grooved composite support, each groove comprising a primer.

 Grooving is not a technical condition necessary for the operation of the cutting device.

However, it has proven advantageous to make grooves in the composite support to guide the cutting means and ensure a clean cutting of the latter.

In addition, the grooving makes the operation of the cutting device independent of the thickness of the composite support.

 - The sectioning means has a rounded leading edge. This arrangement avoids a deviation of the sectioning means during its application, a phenomenon which can be observed otherwise when using sectioning means provided with a cutting edge, such as for example a sharp blade.

 Furthermore, it should be emphasized that the operating principle of the sectioning device of the invention is based on the discharge of the polymer as and when the composite support is traversed by the sectioning means, this discharge being accompanied by the breakage of the fibers which are on the path of advancement of the composite support with respect to the cutting means.

 One of the advantages of the sectioning principle applied by the present invention lies in the absence of waste, namely in the absence of cutting residues.

 Another advantage lies in the fact that the sectioning is done cold since there is no friction caused by an animated blade.

 - The sectioning means is a strip. This arrangement combines the advantages of a thin elongated element with those of an element having a certain stability in a plane substantially parallel to the largest dimension of its cross section.

 - It is however also conceivable that the cutting means is a wire. This arrangement increases the field of application of the sectioning device to the extent that the sectioning can also be done along curved lines.

 However, it should be noted that a wire must be stretched more strongly than a strip to obtain the same mechanical stability during sectioning. At the same time, it must be considered that an increase in the tension of the wire reduces its resistance to breakage.

 - The sectioning means is a closed loop.

This arrangement allows, in comparison with the use of straight means stretched between two fastening elements, complete use of the cutting means all around the circumference of the loop and facilitates its tensioning.

 - The width of the leading edge of the cutting means is approximately 0.15 mm.

 - The sectioning means is mounted on rollers so that it can be advanced each time the leading edge is worn. This arrangement combines the advantages of full use of the sectioning means set out above, with that of easier advancement of the loop.

 More particularly, this arrangement opens the way to automation of the advancement of the sectioning means. Thus, one can conceive the example of a strip which is advanced in steps of 5 mm after the passage of a given number of composite supports corresponding to a maximum allowed deformation of the leading edge.

The object of the invention is also achieved by a method of sectioning a composite printed circuit support formed from a fiber-reinforced polymer. In accordance with the invention, the method comprises the following stages:
- positioning the support in front of a thin elongated static sectioning means;
- Application of a driving force on the composite support in a transverse direction relative to the longitudinal extent of the cutting means and corresponding at all times substantially to the orientation of the cutting line.

The invention also relates to the following characteristics, considered in isolation or in all their technically possible combinations:
- The support is previously grooved along at least one sectioning line;
- Each of the grooves is primed at one of its ends and at the intersections of two grooves.

 The priming of the grooves at that of their ends by which the cutting along a groove will be started, increases the cutting precision. This is particularly important for the cutting of supports which present networks of printed conductors, or printed circuits, very dense. A primer must also be provided at each intersection of grooves. These primers can be produced by drilling.

 It is also conceivable to prepare the sectioning of a support by the sole initiation of the start of the sectioning line or lines. The initiation of a sectioning line without prior grooving of the support is particularly advantageous in cases where the density of the printed conductors makes it difficult or even impossible to groove the support. Even in this case, the primer makes it possible to engage the sectioning means at the precise location of the start of the sectioning line.

Other characteristics and advantages of the invention will emerge from the description of a nonlimiting exemplary embodiment of a sectioning device with reference to the accompanying drawings. In these drawings:
Figure 1 shows a preferred embodiment of a sectioning device according to the invention;
Figure 2 shows a cross section of a strip according to the invention;
Figure 3 shows, in simplified perspective, a grooved part of a partially sectioned composite support; and
Figure 4 shows in a) in perspective a view of a composite support carrying two printed circuits each provided with electronic components, the support being in the process of sectioning;
Figure 4 shows in b) a partial section of the support not yet sectioned;
Figure 4 shows in c) a partial section of the cut support;
The sectioning device shown in FIG. 1 comprises a frame 1 constituted by a base 2 and a support 3.

The support 3 is mounted perpendicularly on the base 2 and is fixed to it by screws (not shown). It is however conceivable that the support is welded to the base.

 The base 2 carries a plate 4 movably mounted on the base 2 by means of a linear jack 5. The plate 4 is intended to receive a composite support 6 to be cut which, in the example chosen, comprises two printed circuits 7 and 8 identical fitted with electronic components. The components can be welded by through or surface tabs.

 The plate 4 is attached to the movable element of the jack 5 by a substantially parallelepiped connecting element 9, the largest dimension of which is oriented parallel to the direction of movement of the jack 5. It is approximately horizontal.

 In addition, the plate 4 is provided with a pusher 10 disposed at the level of the composite support 6 but oriented perpendicular to the direction of movement of the jack 5. The essential function of the pusher 10 consists in constituting an element against which the composite support 6 can lean on during its sectioning.

 For this reason, the pusher 10 can be designed as a rectangular piece forming an integral part with the plate 4. The pusher 10 can also take the form of a simple flange obtained by folding the plate.

 In another alternative embodiment, the pusher 10 can be a movable piece connected directly to the jack 5. The plate 4 is, in this case, stationary mounted on the base 2 and only forms a plane on which the composite support 6 is posed and moved.

 Of course, it is the relative movement of the composite support relative to the cutting means that matters.

a device could be produced in which the support is fixed and the sectioning means is mobile. In this case, the sectioning means is not driven by any other movement than this transverse movement, neither in the direction of the length approximately perpendicular to the support, nor on itself.

It is in this sense that the sectioning means is static.

 To facilitate a clean and complete sectioning of the composite support over the entire length of the sectioning line, referenced at 11, the pusher 10 can be provided with a notch 12, as will be explained below.

 The support 3 is provided with an approximately vertical retaining ring 13 having the general shape of a "U".

The crown 13 is intended to maintain in the working position a strip 14 formed in a closed loop or infinite strip. The strip 14 is held by the retaining ring 13 and by a tension roller 15. The tension roller 15 is mounted for free rotation about an axis 16 fixed on a tension rod 17.

 The tension rod 17 is connected, at one of its ends, to the support 3 by a pivot axis 18. At the other end, the rod 17 is connected to the base 2 by a tension jack 19 intended to generate the force necessary to subject the strip 14 to a certain tension. The tension cylinder 19 is pivotally mounted relative to an axis parallel to the pivot axis 18, on the base 2.

 It is understood that the tensioner function assumed in the example chosen by the rod 17 / jack 19 assembly can also be achieved by other means. it will be cited here only the possibility of providing a second tension roller, mounted on the support 3 by means of an axis arranged in an adjustable manner in a non-linear recess.

The support 3 is mounted on the base 2 so that the sectioning plane defined by the strip 14 is approximately parallel to the direction of movement of the jack 5. It follows that the composite support 6 is placed on the plate 4 in such a way that the sectioning line 11 is approximately both parallel to the direction of movement of the jack 5 and aligned with the part, referenced at
T, strip 14 which performs the sectioning.

The retaining ring 13 is shown in the
Figure 1 as an approximately circular external shaped part. To allow the composite support 6 to pass through the support 3, a diametrical clearance 20 is made over the major part of a diameter of the crown 13. The greatest extent of the clearance 20 is oriented parallel to the plane defined by the extent of deck 4.

 Figure 2 shows the section of the strip 14 shown in Figure 1. The strip 14 has a substantially rectangular section with rounded angles. The smallest dimension corresponds to the thickness of the strip which is of the order of 0.15 mm. The largest dimension, representing the width of the strip, is of the order of 20 mm.

 The strip 14 is advantageously made of stainless steel. The loop is closed by welding, by laser welding, of the strip on itself.

 The short sides of the strip section 14, referenced at 21 and 22, correspond to the attack faces of the strip. Depending on the degree of wear caused by the cutting, either 11 one or the other of the two attack faces 21 and 22 of the strip 14, or successively one after the other, can be used.

 The two leading faces 21 and 22 constitute rounded edges or, as shown in the drawing, flat with rounded angles of the strip 14. These edges are not sharp edges.

 Figure 3 shows, in simplified perspective, part of a composite support 6 in which a strip 14 is engaged to effect the cutting of the support.

The strap 14 is engaged along the sectioning line 11 formed by a practical groove on the support, for example, when drilling the support.

 In most applications, the groove 11 will be made in the two surfaces of the composite support 6. It is however possible, in particular in the case of very thin supports, to only practice grooving on one surface.

 FIG. 4a shows, in a simplified perspective, the composite support 6 during sectioning, represented by the engagement of the strip 14 on a part of the groove 11.

 Figures 4b and 4c show sections of the composite support 6 indicated, in Figure 4a, by the section lines b-b and c-c. It can be seen in particular that the grooves are formed in the shape of a "V" with a depth corresponding to approximately one third of the thickness of the support 6.

 Furthermore, Figure 4c shows that the edges of the printed circuits 7 and 8, obtained by sectioning, are "broken" and do not require any additional finishing work.

 The device and method of the invention are particularly well suited to the sectioning of epoxy - glass fiber supports. The thickness of these supports is of the order of 1 to 3 mm. The grooving advantageously has a depth on each face equal to one third of the thickness of the support.

The preparation of a composite support for sectioning by means of a device according to the invention and the sectioning with this device are essentially carried out in the following stages:
The support is grooved along the section lines defined during the design of all the circuits carried by the support.

 The grooving is carried out, for each sectioning line, by two grooves of substantially triangular section, that is to say in the shape of a V, produced one opposite the other on each of two faces of the support. . The depth of each groove is chosen such that the thickness of the composite support is reduced, in line with the sectioning line, to a value between 0.3 and 1 mm, preferably 0.6 mm. This corresponds for a standard support to approximately one third of the thickness of the support.

 Thus, the residual thickness of the standard support is around a third at the right of the sectioning line.

 Then, each of the grooves thus obtained is primed at its ends. By this operation which consists in carrying out a start of sectioning of the composite support for example by the grooving tool, a notch is prepared in which the sectioning means, either a strip or a wire, can be engaged without risk of being deflected when starting the sectioning.

 Once the support is placed in the working position in front of the sectioning means, the sectioning means is stretched with a tension force preferably between 40 and 80 kg / mm 2 and engaged in the initiation of the sectioning line.

 A feed force of preferably between 15 and 20 kg (in the case of a standard epoxy-fiberglass support) is then applied to press the support against the sectioning means and obtain the desired sectioning.

During this last step, when the plate carrying the composite support advances, the cutting means is static.

 The reference signs inserted after the technical characteristics mentioned in the claims, have the sole purpose of facilitating the understanding of the latter, and in no way limit their scope.

Claims (11)

 1. Sectioning device for a composite support (6) of a printed circuit formed from a fiber-reinforced polymer, with a frame (l) on which is disposed a plate (4) intended to receive the composite support (6) to be cut , the plate (4) being movable relative to the frame (1) so as to allow its translation in at least one direction, a cutting means (14) and a pusher device (5) intended to push, by means of the plate (4), the composite support (6) against the cutting means to obtain the cutting (14) of the composite support (6), the device being characterized in that the cutting means (14) is a thin elongated element static, energized at least during disconnection.  2. Device according to claim 1, characterized in that it is intended for cutting a composite support (6) grooved, each groove (ll) comprising a primer.  3. Device according to claim 1 or 2, characterized in that the cutting means (14) has a rounded leading edge (21; 22).  4. Device according to any one of claims 1 to 3, characterized in that the cutting means (14) is a strip.  5. Device according to any one of claims 1 to 3, characterized in that the cutting means (14) is a wire.  6. Device according to any one of claims 1 to 5, characterized in that the cutting means (14) is a closed loop.  7. Device according to any one of claims 1 to 6, characterized in that the width of the leading edge (22; 22) of the cutting means (14) is about 0.15 mm.  8. Device according to claim 6, characterized in that the cutting means (14) is mounted on rollers (13, 15) so as to be able to be advanced each time the leading edge (21; 22) is worn.  9. Method for sectioning a composite printed circuit support formed from a fiber-reinforced polymer, characterized in that it comprises the following steps:  - positioning the support in front of a thin elongated static sectioning means;  - Application of a driving force on the composite support in a transverse direction relative to the longitudinal extent of the cutting means and corresponding at all times substantially to the orientation of the cutting line.  10. Method according to claim 9, characterized in that the support is previously grooved along at least one sectioning line.  11. Method according to claim 9 or 10, characterized in that the support is initiated at the right corresponding to the start of each sectioning line.