FR2836860A1 - Thick layer electronic print mechanism having viscous product substrate placed through mask and positive pressure difference applied across filling face during mask contact separation phase. - Google Patents

Abstract

The thick layer electronic print method has a viscous product on a substrate (1) across a mask (3). A positive pressure difference is applied across the filling face during the mask contact separation phase.

Description

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PRESSURE DEMOLDING DEVICE AREA OF APPLICATION:
The present invention finds its application in the field of the transfer of more or less viscous products through a mask. More particularly, it is applicable to the screen printing of thick layers, as for example it is practiced in the field of electronics for depositing soldering creams, glues or inks.

 During the serigraphy of thick deposits of soldering cream, a major difficulty is encountered which limits the performance achievable by this process and which is today one of the major causes of faults in electronic assembly. This difficulty lies in the demolding limit. Indeed, it is commonly accepted that when the aspect ratio (minimum opening dimension of the stencil divided by the thickness of the stencil) takes a value less than 1.5 or even when the surface ratio (surface of the opening of the stencil divided by the surface of the walls of the opening of the stencil) takes a value less than 0.66, the release can not take place in a total and repetitive manner. When the aspect and / or surface ratios are respectively less than 1.5 or 0.66, part of the soldering cream is reentrained by the stencil during the separation of the latter with the substrate on which the deposit is to be made.

 This demolding problem becomes more and more critical with the use of components having increasingly reduced interconnections and a growing level of dimensional heterogeneity on electronic cards.

 Indeed, it is not uncommon today to see coexisting on the same card, components requiring heights of solder cream deposits of at least 150 microns with components having reception ranges which lead to ratios surface area of the order of 0.5.

 Another application for which the release of the soldering cream is extremely critical is the operation of producing I / O bosses on matrix components sometimes directly on wafers. In this case, it is generally sought to obtain, by coalescence of the soldering cream, a spherical cap having substantially a height corresponding to half the interconnection pitch.

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 2 However, an irregular solder paste deposit between the different studs leads to variations in the co-flatness of the bosses.

DESCRIPTION OF THE PRIOR ART:
Solutions have been proposed to push the limits of demolding.

HTI or MPM, which are two manufacturers of screen printing equipment, recommend applying a vibration to the stencil during demolding so as to facilitate the separation between the soldering cream and the stencil. Their competitors DEK or PANASONIC recommend applying a vibration to the substrate. These attempts to push the limits of demolding do not achieve the desired goal and on the contrary generate defects. In fact, when the solder cream is subjected to a vibration, a segregation is generated between the metal particles and the organic part which compose it, which has the effect of causing the solder pads to collapse and leading to the generation of short circuits.

 In patents US5713275 and US5389148, contactless deposition techniques have been developed. They consist in spraying an ink or a liquid contained in the pores of a screen, using an air knife and to project them thanks to the kinetic energy of the air on the substrate which is spaced from said screen. These methods no longer have anything to do with a screen printing operation for which the mask must come, at least temporarily, in intimate contact with the substrate so as to ensure a seal between said mask and the substrate and thus allow '' obtain perfectly defined and delimited deposits. This contact constraint between the stencil and the substrate is particularly important when it is sought to deposit pads of soldering cream at least 100 microns in height on reception areas which may be 100 microns or even less. each other and that the studs thus deposited should not collapse and touch. Spray deposition as described in the above patents therefore does not allow this type of deposition to be carried out.

DESCRIPTION OF THE INVENTION:
The present invention aims to propose another solution for pushing back the demolding limits. It is essentially characterized in that it consists in applying a positive pressure difference between the filling face of the mask with respect to the face of the mask in contact with the substrate during the phase of separation of the stencil and the substrate. In this way, the product present in the stencil openings

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 or the mask is pushed and this pushing force is added to the driving force generated by the adhesion of the product to the substrate which promotes the release of the product pad.

 Unlike the patents of the prior art, the force applied by the overpressure must be static, that is to say that the speed, perpendicular to the mask, of the fluid which can be air or any other gas is limited. By way of nonlimiting example, speeds of the order of 600 m / min, or even lower, give good results. In all cases, no attempt is made to project the product present in the mask onto the substrate because, on the one hand, the gas velocities required for the projection lead to deformation of the studs and to non-control of the contact surface of studs on the substrate and on the other hand, the kinetic energy of the gas injected between the mask and the substrate, deteriorates the shape of the deposits.

 To avoid these harmful phenomena and according to another characteristic of the present invention, the static overpressure is obtained by the creation of an air cushion, during the movement of separation of the mask and the substrate, on the filling surface of the stencil. The air cushion offers the double advantage of creating a controlled overpressure in a defined area and of limiting the gas flow in flow and speed through the mask.

 Generally the screen printing of solder cream using a metal stencil is carried out by plating the stencil over the entire surface of the substrate and a separation is carried out at a controlled speed of the substrate and the entire stencil. In this case, the overpressure according to the present invention must be applied to the entire surface of the image to be printed during the demolding phase.

 This arrangement is conceivable and is covered by the scope of the present invention, but it causes a difficulty linked to the bearing force of the overpressure on the mask. Indeed, if we consider an image to be printed of the order of 600 cm2 and an overpressure of 1000 Pa. This leads to a pressing force on the mask of 6 daN, which leads to a deformation in the form of a bowl of the mask.

 Another arrangement consists in generating an air cushion at the rear of the screen printing doctor blade and in demolding the area covered by the air cushion as the doctor blade advances thanks to a non-contact between the stencil and the substrate.

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 The present invention therefore makes it possible to push back the current demolding limits. Thus, it gives the possibility of increasing the volume of product deposited on small reception areas, it gives access to new applications such as for example the production of reflow bosses with levels of quality and repeatability unattainable to date. . Finally, the invention offers the possibility of using larger sizes of solder cream. Indeed, to date for applications having aspect or critical surface ratios, an alternative consists in using a soldering cream containing metallic particles of smaller dimensions. This makes it possible to slightly improve the mold release, on the other hand the lifetime of these soldering creams with a small particle size 20-30 microns or even less, is considerably reduced because the metal surface exposed to the phenomenon of oxidation increases when the granulometry. In addition, soldering creams with a small particle size cost more than creams of the standard 25-45 micron type. It is therefore extremely interesting to be able to continue using standard soldering creams despite the reduction of the openings in the stencils.

 Other characteristics of the present invention will become apparent from the description of the appended figures given by way of nonlimiting examples.

 In Figure 1 is shown in section, a pad of soldering cream during the separation of the stencil and the substrate.

 In Figure 2 is shown in section, an embodiment of the present invention.

 In Figure 3 is shown in section, an alternative embodiment of the present invention.

 In Figure 1 is shown during demolding a solder pad (4) composed of metal balls (11) and flow (12). The solder pad must be placed on the surface of a receiving area (2) of a substrate (1). In order to be able to make a subsequent interconnection of acceptable quality, it is sought to empty the orifice (7) of the mask (3) completely with the least possible deformation of the stud. However, as explained above, when the mask openings reach certain critical limits, demolding becomes extremely difficult and in some cases it is either partial or nonexistent. These limits can be determined by means of an aspect ratio and a surface ratio previously defined. As we can

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voir sur la figure 1, en cours de démoulage, le plot est soumis à une force d'adhérence sur la plage d'accueil qui s'oppose à une force de ré-entraînement par le pochoir. On considère généralement que le poids du plot est négligeable par rapport aux autres forces et nous n'en tiendrons pas compte ici. Lorsque les ratios d'aspect et/ou de surface atteignent les valeurs critiques, respectivement 1. 5 et 0. 66, voire inférieures, la force de ré-entraînement par le pochoir devient supérieure ou égale à la force d'adhérence sur la plage d'accueil, ce qui conduit à un mauvais démoulage. La présente invention vise à déplacer les limites de démoulage en appliquant une surpression statique ou quasistatique, sur le dessus du pochoir lors de la phase de démoulage. Cette surpression pourra être appliquée de différentes façons sans sortir du champ de la présente invention. Toutefois la réalisation d'un coussin gazeux (5) permet d'obtenir une pression statique parfaitement contrôlée et constitue donc un mode préférentiel de réalisation de la présente invention. La pression du gaz qui peut être de l'air ou tout autre gaz comme par exemple l'azote pour limiter les phénomènes d'oxydation, génère une force d'appui sur le plot de crème à braser, qui s'additionne à la force d'adhérence sur la plage d'accueil et permet donc ainsi de favoriser le démoulage. Des essais ont permis d'obtenir des démoulages complets et répétitifs avec des pochoirs d'épaisseur 125 microns ayant des ouvertures présentant un ratio de surface de 0. 45.

see in FIG. 1, during demolding, the stud is subjected to an adhesion force on the reception area which opposes a re-entrainment force by the stencil. We generally consider that the weight of the stud is negligible compared to the other forces and we will not take it into account here. When the aspect and / or surface ratios reach the critical values, respectively 1.5 and 0.66, or even lower, the force of re-entrainment by the stencil becomes greater than or equal to the force of adhesion on the range reception, which leads to poor mold release. The present invention aims to move the demolding limits by applying a static or quasistatic overpressure, on the top of the stencil during the demolding phase. This overpressure can be applied in different ways without departing from the scope of the present invention. However, the production of a gas cushion (5) makes it possible to obtain a perfectly controlled static pressure and therefore constitutes a preferred embodiment of the present invention. The pressure of the gas, which may be air or any other gas such as, for example, nitrogen to limit the oxidation phenomena, generates a pressing force on the solder pad, which adds to the force grip on the reception area and thus allows to promote the release. Tests have made it possible to obtain complete and repetitive mold release with stencils of thickness 125 microns having openings having a surface ratio of 0.45.

In Figure 2 is shown a particularly interesting embodiment of the present invention. As can be seen, a product transfer device (9) (10) which can be a doctor blade or a direct injection device is moved in the direction A in abutment against a substrate (1). Between the device (9) and the substrate (1) is interposed a screen printing stencil (3), stretched over a frame (8). In the rest position, the stencil is spaced from the substrate (1) by a non-contact which can be adjusted on the screen printing equipment not shown. In the working position, the stencil is pushed into intimate contact with the substrate by the transfer device (9) and as the latter progresses, the stencil separates from the substrate and therefore causes the pads to be removed from the mold. (4). It is therefore in the demolding zone at the rear of the transfer device relative to the direction of advance that it is advisable to place the device which is the subject of the present invention. In the embodiment shown in FIG. 2, the device consists of an air inlet (14) distributed over the entire length of the image to be printed and thanks to the wall (6) and the lip (13 ), an air cushion is formed between the

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 stencil and the wall (6) in the demolding zone. The lip (13), located upstream of the transfer member in the direction of movement of said member, simultaneously plays both a role of deflector for directing the air or the gas between the wall (6) and the stencil ( 3), and a role of keeping the stencil in contact with the substrate in order to prevent the release from starting before the overpressure zone. It is obvious that the system described in Figure 2 can operate in the direction A, but also in the opposite direction and in this case, there is provided a second device according to the present invention not shown and located on the other side of the transfer device . When moving the transfer device, it may be advisable to retract the device according to the present invention which is located at the front of the transfer device thanks to the pivot link (15). Tests using a 2 mm contactless and an air cushion which acts on 5 cm have given excellent results with a 125 micron electroformed nickel stencil. Preferably, the air cushion is applied over the entire width of the image to be printed, on the other hand it is conceivable to cause it only locally if it is desired to promote demolding at a specific location of the stencil.

 In Figure 3 is shown another device (18) for producing an air cushion. In this case, the wall (6) is porous or pierced with a multitude of small orifices (17) distributed over the entire surface. On the rear of the wall (6), a cavity (16) makes it possible to supply all the orifices (17) with compressed air, the whole being connected to an air inlet (14) whose flow and pressure are controlled by means not shown. When the air is sent through the orifices (17), this has the effect of putting the device (18) in lift at a distance from the mask (3) which depends on the air flow in the device and the force d support P which tends to push the assembly against the mask (3). Thus a pressure is obtained distributed over the entire surface (6) which is adjustable thanks to the adjustment of the pressing force P. This arrangement is particularly advantageous because it operates with reduced air flow rates which makes it possible to maintain the kinetic energy of the air at low levels. The leaks F ensure a uniformity of the pressure prevailing between the device (18) and the mask (3), this is regulated automatically because as soon as the pressure varies, the leak is modified and allows a self-readjustment of the pressure. This device as shown in FIG. 3 can be used either:

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 - in contact screen printing and in this case the surface (6) covers the entire image to be screen printed and is put into action during the demolding phase which occurs after the filling phase of the entire mask, - in screen printing off contact and in this case, the surface (6) is at least the width of the image to be screen printed and extends over a distance of a few centimeters parallel to the scraping direction and acts progressively as the feed advances. rear of the transfer device in the direction of travel. In this type of configuration, it is possible that the surface (6) may be polluted by untimely contact with the product to be transferred, in particular when the air flow is stopped at the end or at the start of scraping. To overcome this difficulty, it is possible to bring a porous paper or fabric (19) onto the surface (6). This paper can be replaced in the event of pollution, without having to clean the complete device.

 Tests with a device of this type have made it possible to obtain good results with a pressure of 1000 Pa.

Claims (3)

claims  1) Method for pushing back the demolding limits during a th screen printing operation of a viscous product (10) on a substrate (1) through a mask (3), characterized in that it consists in applying a positive pressure difference between the filling face of the mask with respect to the face of the mask in contact with the substrate during the phase of separation of said mask from said substrate.  2) Method for pushing back the release limits during a screen printing operation of a viscous product (1 0) on a substrate (11) through a mask (3) according to claim 1, characterized in that the pressure positive is obtained by producing a gas cushion (5) on the filling face of said mask during the movement of separation of said mask with said substrate.  3) Device for pushing back the release limits of a viscous product (10) on a substrate (1) through a mask (3) occupying an out of contact position relative to the substrate during a rest phase and allowing a release from the mold as a transfer member (9) advances, characterized in that it consists of a lip (13) located upstream of the transfer member in the direction of movement of said member , said lip acting simultaneously on the mask (3) while maintaining it in contact with the substrate (1) while playing a role of deflector for directing air or gas between a wall (6) of an embodiment device of an air or gas cushion and the mask (3), said wall (6) making it possible to constitute an air cushion over the entire width of the image to be printed.