1. Field of the Invention
This invention concerns a method to manufacture a prelaminated inlet, an inlet obtained by this method and a card including such an inlet.
2. Related Art
The manufacture of contactless smart cards involves the use of a radiofrequency (RF) microelectronic component connected to an antenna.
This RF assembly is fastened to a substrate, generally made of plastic. The assembly consisting of the RF component, the antenna and the substrate is called an inlet by the smart card industry.
This inlet is then laminated between several plastic layers to provide the thickness and rigidity required by the contactless card. The outer layers are printed with designs which are then protected by a thin layer of transparent plastic called an “overlay”.
The inlets either consist of a flexible substrate supporting the RF component and the antenna or a relatively thick substrate in which the RF component and the antenna are inserted. In the second case, the inlet is realised by lamination in several layers, hence the name of prelaminated inlet.
When manufacturing prelaminated inlets, electronic components previously encapsulated in an interconnection circuit known as a module are generally used. The module is then connected to the antenna which has previously been engraved on the substrate.
In another method of manufacture, the RF component is soldered directly on the substrate and the antenna according to the flip-chip technology. Although it reduces the number of manufacturing steps, this technology has the disadvantage of being more fragile since the component is not protected by the interconnection circuit.
In the method currently used to manufacture prelaminated inlets, the antenna is first deposited and bonded on the substrate, engraved on it, or inserted using an ultrasound method.
The component is now placed on the substrate and soldered to the antenna, then a plastic sheet is laminated on top to protect the assembly and produce an inlet of constant thickness.
The current method has numerous disadvantages. It is expensive and difficult, since numerous plastic sheets are required, often of different thicknesses and qualities.
In addition, cavities must be machined out on the various layers in order to insert the component, these cavities then having to be filled with a resin to remove the residual gaps between the component and the plastic layer.
The invention is a new method to manufacture prelaminated inlets which is easy to implement and therefore inexpensive.
The invention concerns a method to manufacture a prelaminated inlet, including the following steps:
According to other characteristics of the invention:
The invention also concerns a contactless integrated circuit card including an inlet and the corresponding inlet manufactured according to the method of the invention.
It will be easier to understand the invention on reading the description below, given as an example and referring to the attached drawings, on which:
In the figures, identical reference numbers refer to identical or similar parts.
When manufacturing an inlet with a component assembled using the flip-chip method according to the prior art,
When component 1 is assembled in a module,
In a well known mode of realisation of the prior art, not represented on a figure, the module has its contact areas on the side of the lead-frame opposite that on which the component is bonded. The module can therefore be soldered on the inlet support without first making a cavity. However, the thickness of the inlet obtained is equal to the sum of the thicknesses of the module and support 2, which is greater than that of the inlet obtained in the mode of realisation shown on
According to a preferred mode of realisation of the invention, illustrated by
At this step in the realisation, the RF component is electrically connected to the antenna via contact studs 13.
A second plastic layer 14 is deposited over the assembly which is then laminated to obtain a monobloc assembly of constant thickness, as illustrated on
It should be pointed out that carefully choosing the plastic for layer 14 avoids the need to first machine a cavity to accommodate component 11. The plastic chosen should therefore be soft enough to deform and take the shape of component 11 during lamination. Plastics of softening point, or VICAT point, less than 90° C. are ideal for this type of use and amongst these plastics good results have been obtained with polyvinyl chloride (PVC), polyethylene terephthalate glycol (PETg) and plastics based on acrylonitrile-butadiene-styrene (ABS), or PVC/ABS mixtures.
This choice can also be extended to the first support 10, in order to distribute the stresses and deformations during lamination over both supports.
Some applications, however, may have high mechanical requirements, especially regarding the bending strength. In this case, the monobloc obtained previously must be strengthened by laminating one or more layers of a stronger plastic to it. A first option consists in adding,
Plastics of softening points greater than 150° C. such as polycarbonate (PC) or polyethylene terephthalate (PET) provide the necessary mechanical strength, increasing the strength to 15 000 bending cycles instead of the 1 000 bending cycles generally encountered with a traditional prelaminated assembly.
A second mode of realisation of the invention is illustrated on
A cavity 20 is machined in a first support 10,
A second support 16 is positioned under the first support and a drop of resin 17 is deposited in the cavity formed by the first and second supports. As an alternative, the cavity machined in support 10 can be a blind hole, the drop of resin then being deposited at the bottom of this hole.
After depositing the resin 17, module 11 is positioned in the cavity,
Antenna 12, 13 is then deposited on support 10 and connected to module 11 by studs 13 as in the first mode of realisation,
A second drop of resin 18 is deposited on the top of module 11.
In addition, two plastic layers 14 and 19,
This assembly is then deposited,
Concerning the cavities machined in the first layer 10 and in the top layer 14, the type of plastic used is unimportant. Preferably, however, plastics of softening point less than 90° C. are used.
In a third mode of realisation illustrated by
Module 11 is then positioned inside the cavity. Preferably, the first support 10 is approximately the same thickness as the lead-frame of module 11,
As previously, antenna 12 is then deposited,
The assembly is then laminated between an upper layer 14 of relatively soft plastic and a lower layer 16 of relatively hard plastic which provides the mechanical strength of the assembly,
Obviously these various modes of realisation can be combined to form other modes of realisation.
For example, the third mode of realisation can be combined with machining of a cavity in the upper layer in order to use a relatively hard plastic for this upper layer.
Prelaminated inlets can therefore be realised using a method which, having a limited number of steps, is inexpensive to implement.
| Number | Date | Country | Kind |
|---|---|---|---|
| 032910812 | May 2003 | EP | regional |
| 032914715 | Jun 2003 | EP | regional |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/IB04/01575 | 5/4/2004 | WO | 12/14/2005 |