CA1294095C - Method of making cards, in particular memory cards - Google Patents
Method of making cards, in particular memory cardsInfo
- Publication number
- CA1294095C CA1294095C CA000549181A CA549181A CA1294095C CA 1294095 C CA1294095 C CA 1294095C CA 000549181 A CA000549181 A CA 000549181A CA 549181 A CA549181 A CA 549181A CA 1294095 C CA1294095 C CA 1294095C
- Authority
- CA
- Canada
- Prior art keywords
- card body
- electronic module
- mold
- main faces
- cavity
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Landscapes
- Credit Cards Or The Like (AREA)
Abstract
A B S T R A C T
According to the invention the card body is made by molding a plastic material such as ABS. The mold (20, 22) includes a core (24) serving to define a cavity in the card body for the purpose of receiving a card electronic module.
According to the invention the card body is made by molding a plastic material such as ABS. The mold (20, 22) includes a core (24) serving to define a cavity in the card body for the purpose of receiving a card electronic module.
Description
.7 '' .~ S
`:, 1 A method of making cards, in particular memory cards The present invention relates to a method of making cards, and in particular cards including memory and particularly electronic memory.
BACKGROUND OF THE INVENTION
Memory cards essentially comprise a card body which is generally made of a plastic material together with a memory module. In cards having an electronic memory, the memory module is an electronic module essentially comprising a semi-conductor chip having an integrated circuit formed thereon together with a piece of printed circuit having the chip fixed thereto and serving to define external contact tabs. The electronic module is fixed in the body of the card so that the electrical contact tabs are level with one of the main faces of the card body.
The card bod~ is in the form of a rectangular parallel~
ipiped having a thickness which must be less than 1 mm. The edges of the card body serve as references for positioning the card in a card reader so that the contact tabs of the card come into electrical contact with a connector in the card reader.
Twa main techniques are used for making the card body and for implanting the electronic module therein. In the first technique, the card body is made by hot rolling a plurality of sheets of plastic material such as PVC. The electronic module is put into place in the stack of sheets of plastic material prior to rolling. After the rolling operation, the electronic module is solidly retained in the card body. This method has the advantage of making the card body and implanting the electronic module therein in a single step. However, it is a difficult method and requires the periphery of the card body to be re-machined.
The second technique consists in making the card body in a ;
first step, in machining a cavity in the card body to receive the electronic module, and in gluing the electronic module in the cavity. The machining of such a card body is always a difficult operation and is therefore expensive bacause very ; accurate tolerances must be maintained, in particular to ensure :; -w ; lZ~95 ; 2 that the electronic module is properly positioned relative to the edges of the card and relative to the main face of the card body with which the electrical contact tabs are to be level.
It should also be added -that the card body must additionally satisfy other specifications concerning the quality of its surface state and concerning well-defined bending properties both longitudinally and transversely relative to the card body. In addition, the card body must not encourage the storage of electrostatic chargeO
An aim of the present invention is to provide a method of making cards, in particular cards having an electronic memory, and in particular for making the card body in such a manner as to reduce the cost of making a card body while also simplifying the operation of fixing the electronic module in the card body and yet still satisfying the above-mentioned specifications.
SUMMARY OF THE INVENTION
In order to achieve this aim, the present invention provides a card-making method comprising the following steps:
a mold is provided having a cavity which is substantially in the form of a rectangular parallelipiped with two substantially rectangular parallel main faces with the distance betwean said aces being about one millimeter;
a plastic material is injected into said cavity, said plastic material being selected from the group comprising:
acrylonitrile butadiene styrene, polystyrene, polypropylene, and polyamine 11; and the part obtained in this way is unmolded.
; The method of making a memor~ card comprising a memor~
module and a card body in the form of a rectangular parallelipiped is characterized in that it comprises the following steps:
the card body is made by molding a plastic material by injection into a mold defining the two main faces of tha card body, the edges of the card, and at least one cavity suitable for receiving a memor~ module and opening out into one of said main faces;
.
4~
after unmolding, the memory module is put into plaGe in said cavity; and said memory module is fixed to the card body.
The memory module is preferably an electronic module comprislng a semiconductor chip together with electrical contact tabs.
In a preferred implementation, injection takes place through a mold face correƦponding to one of the main faces of the card body and level with said cavity.
Also preferably, the material used for injection i6 an - 10 acrylonitrile butadiene styrene.
Thus, according to one broad aspect of the invention, there is disclosed a method for making an electronic memory card comprising a card body which is ~ubstantially in the form of a rectangular parallelipiped having two main faces, said card body satis~ying the requirements of the ISO standard regarding the dimensions of the card body and the bendlng properties oi said card body, said card body containing an electronic module constituting a data medium, the method comprising the steps of:
~, (a) providing a mold having an inner mold volume limited by two parallel main faces substantially rectangular and an edge, said main faces being separated by a distance less than 1 mm, one of sald main faces be~ng provided with a projection for defining a cavity in the card body; (b) injecting into said mold volume a ; thermoplastlc material, for said plastic material to fill all of said mold volume to form the entire card body therewith; (c) unmolding the card body ~o obtained; (d~ providing an elec~ronic ~ ~ module; and (e~ fixing said electronic module into the cavity : ~ ' S
produced by the projection on said one of said main faces of said mold.
According to another broad aspect of the invention, there is disclosed a method of making an electronic memory card comprising a card body having bending properties satisfying the requirements of the ISO standard and an elec~ronic module constituting a data medium, the method comprising the steps of:
(a) providing a mold having a mold volume limited by two parallel main faces substantlally rectangular in shape and an edge, said main faces having a width of about 55 mm and a length of about 85 mm, the distance separating said two main faces being approximately 0.8 mm, one of said maln faces being provided with an extension for defining a cavity in the card body; (b) injecting an acrylonitrile butadiene styrene (ABS) to fill all of said mold volume to form the entire card body ~herewith; (c) unmolding the card body so obtained; (d) providing an electronic module comprising an insulating support having electrical contact tabs on one of its two faces and a semiconductor chip fixed on the other face of said insulating support; an~ (e) placing said electronic ~ 20 module within said cavity and fixing said electronic module to : said card body.
According to a further broad aspect of the invention, there is disclosed a method of making an electronic memory card having dimensional bending properties satisfying tbe re~uirements of the ISO standard and an electronic module fastened within a cavity formed in said card body, comprising the step~ of:
providing a mold having an inner mold volu~e limited by two 3a gs 6~216-4 parallel main faces subs~antially rectangular and an edge, said main faces being separated by a distance less than 1 mm, providing a projection on one of said two main faces for defining said cavity in the card body, providing an injection point on the other of said two main faces, said in~ection point being opposite said projection, injecting into ~he mold through said injection point a thermoplastic materlal to fill said mold volume, thereby forming said card body, unmolding the card body from said mold, and fastening said electronic module into the cavity of said card body.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be better understood from reading the following description of several implementa~ions of the inven~ion given by way of non-limiting example. The description refers to the accompanying drawings, in which;
Figure 1 is a plan view of a card body in ac~ordance with the invention;
Flgure la is a detail view of Figure ~ showing the cavity provided in the card body;
Figure 2 is a fragmentary sec~ion on line II-II of Figure la;
Figure 3 is a simplified horizontal section through a mold for making a card body in accordance with the invention;
Figure 4 is a vertical section view through the Figure 3 mold on line IV-IV;
Figure 5 is a vertical section view through an : 3b , . . .
~LZ9~95 electronic module for mountlng on the card body o~ Eigures 1 and 2;
Figures 6 and 7 show the printed circult of the electronic module as seen from above and from below, respectively;
Figure 8 is a fragmentary view of the card showing the electronic module implanted in the card body; and Figures ~ and 9a show an embodiment of the card body in which the memory module is magnetic.
MORE DETAILED DESCRIPTION
:; 10 With reference initially to Figures 1 and 2, there follows a description of one particular form of card body made in accordance with the invention.
3c .
lZ~95 -The body 2 has the form of a rectangular parallelipiped with two main faces 4 and 6 which are generally rectangular in shape. The dimensions of the main faces are approximately 85 mm (length L) by 55 mm (width l). The thickness of the card body is about 0.8 mm. As can be seen in Figure 1, the card body also includes a cavity 8 which opens out into main face 4.
The cavity 8 has a constant depth of 0.25 mm and its dimensions `~ in the plane of the main face 4 are 11 mm by 13 mm.
Figure 1 shows that the cavity 8 includes eigh-t studs 10 10 which project from its bottom 12. The studs are disposed in two parallel lines.
Figure 2 shows that each stud 10 comprises a base 14 having a diameter of 2 mm and a thickness of 0.05 mm, together with a terminal portion 16 of diameter 1 mm and of thickness 0.19 mm.
In accordance with the invention, the card body is made by hot injection molding. The plastic material used is an acrylo-nitrile butadiene styrene. The material is in;ected into the mold at a temperature lying between 180C and 280C, and 20 preferably between 220C and 260C, and -the mold is maintained at a temperature lying between 5C and 100C, and preferably between 10C and 50C.
Other plastic materials could also be used, e.g. poly-styrene, polypropylene, and polyamine 11, in which case the ; 25 injection parameters will need changing.
With reference to Figures 3 and 4, there follows a description in greater detail of an example of a mold for implementing the invention. The mold comprises a fixed front portion 20 and a moving rear portion 22. The front portion 20 has a main face 20a which defines the main face 6 of the card body and a side wall 20b which defines the edge of the card.
The rear portion 22 has a face 22a which defines the second main face 4 of the card body. A core 24 is mounted in the portion 22 and serves to make the cavity 8. The core therefore occupies the same position in the face 22a of the portion 22 as is occupied by the cavity 8 in the face 4 of the card body.
The face 24a of the core 24 defines the bottom 12 of the cavity 3~2~ 95 ... ~
a~d includes eight s-tepped hollows 26 which define the shape of the studs 10.
Returning to the portion 20, it can be seen that the face 20a includes a portion 28 which projects slightly and faces the 5 core 24. The in;ection channel 30 opens out into the pro;ection 28. This channel opens out opposite the center of the face 24a of the core 24, i.e. opposite the center of the cavity 8. Naturally, when the two portions 2G and 22 are fixed together, the space between them defines the mold volume and thus the volume of the card. It should be added that the core 24 placed opposite the injection point is provided with a cooling system represented by cooling liquid flow duct 32.
Various tests have been performed and have shown that the above method makes it possible to obtain card bodies under highly satisfactory economic conditions while satisfying the above-mentioned specifications, in spite of the general shape of the part which is unfavorable for molding, in particular in spite of its thinness (0.8 mm).
In particular, by virtue of the particular injection technique, the card body has good bending characteristics and its longitudinal dimension (L) and its transverse dimension (l) are good and satisfy the requirements of the IS0 standard.
More precisely, this standard requires that after 250 bending operations with a central offset of 5 mm when bending across the width and a central offset of lO mm when bending along the length,--the apparent width of the card should remain less than 0.94 mm.
In addition, the advantages of the method in accordance with the invention appear clearly. The card body with the shape in particular of its cavity including the studs is obtained in a single operation and the position of the cavity ; relative to the edges is fully repeatable.
Returning to Figure 3, it is obvious that the core 24 could be omitted providing the face 22a of mold portion 22 is machined in such a manner as to define itself a shape corres-ponding to the end 24a of the core. It should also be added that the method of the invention may be applied to making other I .
~2~9S
.... ~
shapes of card body, in particular bodies having different cavity shapes and different numbers of cavities. In a card body having a plurality of cavities, it may be advantageous to provide one injection point level with each cavity.
Another important advantage of the method in accordance with the invention is that the card body may be embossed using conventional techniques. In many card applications the manufacturer is required to emboss personalizing information on one of the faces of the card.
It must also be underlined that the card body obtained in this way is capable of receiving a magnetic track and of being silk-screen printed with igures or text.
There follows a description with reference to Figures 5 to 8 of the method of manufacturing an electronic memory card using a card body obtained by the molding method in accordance with the invention.
Figure 5 shows an electronic module 40 which is to be implanted in the card body 2. The electronic module essentially comprises a single sided printed circuit 42 and a semiconductor chip 44 having appropriate electronic circuits made thereon, and in particular having memory circuits.
The printed circuit 42 includes an insulating support 46 ~` made of polyester with a layer of conductive material, typically copper, being disposed on one of the faces thereof.
` 25 As can be seen better in Figure 7, the insulating support 46 is pierced by a central window 50, by eight bonding holes 52 surrounding the central window 50, and by eight pre-fastening holes 54. The eight pre-fastening holes 54 occupy the same physical dispositions as -the eight studs lO of the card body and they are of very slightly larger diameter than the terminal portions 16 of the studs.
With reference to Figure 6, it can be seen that the layer ~; of metallization 48 is etched so as to define:
a) eight electrical contact tabs 56 to 70 which are disposed over the pre-fastening holes;
b) nine electrical contact points 72 to 88 corresponding to the central window 50 and to the eight bonding holes 52; and .
i :12g~5 ; c) conducting tracks for interconnecting each contact point to an electrical connection tab and also for connecting the central metallization 72 to contact point 74.
Returning to Figure 5, it can be seen that the semi-5 conductor chip 44 is placed in the central window 50 and isfixed on the central metallization 72 by a conductive glue 90.
In addition, each terminal 92 of the chip 44 is connected to a corresponding one of the contact poin-ts 74 to 88 by a conducting wire 94 whose opposite end passes through the corresponding 10 bonding hole 52 and is bonded to the face of the contact point which closes the bottom of the bonding hole. Thus, each terminal 92 of the semiconductor chip together wi-th the rear face thereof is electrically connected to a contact tab.
The insulating support 46 is 150 microns thick and the metallization layer 48 is 50 microns thick. It may be observed that the thickness of the insulating support of the printed circuit is less than the height of the terminal portion 16 of each stud 10.
Figure 8 shows the electronic module 40 implanted in the card body as made by molding.
In a prior step, a hole 100 is made which opens out firstly into the cavity 8 between the two lines of studs 10 (see the dashed line circle in Figure la) and secondly into a hollow 102 provided in the face 6 of the card body by the ; 25 projecting portion 28 of the injection mold.
The electronic module 40 is put into place in the cavity 8 of the body 2 in such a manner that the terminal portions 16 of the studs penetrate into the pre-fastening holes 54. The face 48a of the printed circuit is not in contact with the bases 14 of the studs. The space remaining is about 0.040 mm across.
In the following step, the metallizations 48 over the pre-fastening holes 54 are heated. As a result the ends of the terminal portions 16 of the studs are deformed and expand as ; shown at 16a in Figure 9. This gives rise to pre-fastening and positions the electronic module 40 on the card body 2, In particular, the face 48a of the printed circuit 42 comes into contact with the bases 14 of the studs 10.
., ~-' lZ~
The card body can then be turned over in order to terminate fixing of the electronic module 40.
Glue is caused to penetrate through the hole 100, e.g. a hot setting epoxy glue (104) which fills the hole 100 together ; 5 with the space left free between the bottom 12 of the cavity 8 and the printed circuit. As a result the module is finally glued to the card body and the hole 100 is filled, thereby simultaneously providing the protective covering for the semiconductor chip 44 and its connection wires 94. By virtue 10 of the hollow 102, it is possible to mill the face 104a of the glue deposit 104 without running the risk of spoiling the face 6 per se of the card body.
The above description relates more particularly to putting an electronic of the type shown in Figure 5 into place.
However, it should be understood that the method of the invention may be used to making electronic memory cards including other types of electronic modules. In particular, instead of providing electrical connection tabs, the connection with the card reader could be provided by inductive coupling.
Similarly, instead of having studs on the bottom of the cavity in order to position and pre-fasten the electronic module, other forms of relief could be provided, on the condition that they can be made by molding. The method may also be implemented without making the hole 100.
In this case, the glue is inserted into the cavity through the front face of the electronic module, or else the glue is put onto the rear facs of the printed circuit before the electronic module is put into place on the card body. Finally, the memory module could be a magnetic memory component.
Fi~ures 9a and 9b show the body of a card made in accordance with the invention and suitable for receiving a memory module constituted by a magnetic track. The card body 120 has the same rectangular shape as the card body shown in Figure 1 and the same outside dimensions. It includes two main 35 faces 122 and 124 which are mutually parallel and it is 0.8 mm thick. A cavity 126 running parallel to one of the long sides of the card is formed in the face 122 and said cavity extends . ~
over the entire length of the card. As seen better in Figure 9b, cavity 126 has a uniform rectangular cross-sec-tion. The depth of the cavity is about 0.2 mm.
Such a card body 126 is obtained by molding in accordance with the above-described technique. The only difference lies in the shape of the molding core which must be complementary to the shape of the cavity. The plastic material injection duct opens out into the core defining the cavity.
The magnetic track is put into place in the cavity and is fixed to the card body either by gluing or by hot-rolling.
':
, 25 :
`:, 1 A method of making cards, in particular memory cards The present invention relates to a method of making cards, and in particular cards including memory and particularly electronic memory.
BACKGROUND OF THE INVENTION
Memory cards essentially comprise a card body which is generally made of a plastic material together with a memory module. In cards having an electronic memory, the memory module is an electronic module essentially comprising a semi-conductor chip having an integrated circuit formed thereon together with a piece of printed circuit having the chip fixed thereto and serving to define external contact tabs. The electronic module is fixed in the body of the card so that the electrical contact tabs are level with one of the main faces of the card body.
The card bod~ is in the form of a rectangular parallel~
ipiped having a thickness which must be less than 1 mm. The edges of the card body serve as references for positioning the card in a card reader so that the contact tabs of the card come into electrical contact with a connector in the card reader.
Twa main techniques are used for making the card body and for implanting the electronic module therein. In the first technique, the card body is made by hot rolling a plurality of sheets of plastic material such as PVC. The electronic module is put into place in the stack of sheets of plastic material prior to rolling. After the rolling operation, the electronic module is solidly retained in the card body. This method has the advantage of making the card body and implanting the electronic module therein in a single step. However, it is a difficult method and requires the periphery of the card body to be re-machined.
The second technique consists in making the card body in a ;
first step, in machining a cavity in the card body to receive the electronic module, and in gluing the electronic module in the cavity. The machining of such a card body is always a difficult operation and is therefore expensive bacause very ; accurate tolerances must be maintained, in particular to ensure :; -w ; lZ~95 ; 2 that the electronic module is properly positioned relative to the edges of the card and relative to the main face of the card body with which the electrical contact tabs are to be level.
It should also be added -that the card body must additionally satisfy other specifications concerning the quality of its surface state and concerning well-defined bending properties both longitudinally and transversely relative to the card body. In addition, the card body must not encourage the storage of electrostatic chargeO
An aim of the present invention is to provide a method of making cards, in particular cards having an electronic memory, and in particular for making the card body in such a manner as to reduce the cost of making a card body while also simplifying the operation of fixing the electronic module in the card body and yet still satisfying the above-mentioned specifications.
SUMMARY OF THE INVENTION
In order to achieve this aim, the present invention provides a card-making method comprising the following steps:
a mold is provided having a cavity which is substantially in the form of a rectangular parallelipiped with two substantially rectangular parallel main faces with the distance betwean said aces being about one millimeter;
a plastic material is injected into said cavity, said plastic material being selected from the group comprising:
acrylonitrile butadiene styrene, polystyrene, polypropylene, and polyamine 11; and the part obtained in this way is unmolded.
; The method of making a memor~ card comprising a memor~
module and a card body in the form of a rectangular parallelipiped is characterized in that it comprises the following steps:
the card body is made by molding a plastic material by injection into a mold defining the two main faces of tha card body, the edges of the card, and at least one cavity suitable for receiving a memor~ module and opening out into one of said main faces;
.
4~
after unmolding, the memory module is put into plaGe in said cavity; and said memory module is fixed to the card body.
The memory module is preferably an electronic module comprislng a semiconductor chip together with electrical contact tabs.
In a preferred implementation, injection takes place through a mold face correƦponding to one of the main faces of the card body and level with said cavity.
Also preferably, the material used for injection i6 an - 10 acrylonitrile butadiene styrene.
Thus, according to one broad aspect of the invention, there is disclosed a method for making an electronic memory card comprising a card body which is ~ubstantially in the form of a rectangular parallelipiped having two main faces, said card body satis~ying the requirements of the ISO standard regarding the dimensions of the card body and the bendlng properties oi said card body, said card body containing an electronic module constituting a data medium, the method comprising the steps of:
~, (a) providing a mold having an inner mold volume limited by two parallel main faces substantially rectangular and an edge, said main faces being separated by a distance less than 1 mm, one of sald main faces be~ng provided with a projection for defining a cavity in the card body; (b) injecting into said mold volume a ; thermoplastlc material, for said plastic material to fill all of said mold volume to form the entire card body therewith; (c) unmolding the card body ~o obtained; (d~ providing an elec~ronic ~ ~ module; and (e~ fixing said electronic module into the cavity : ~ ' S
produced by the projection on said one of said main faces of said mold.
According to another broad aspect of the invention, there is disclosed a method of making an electronic memory card comprising a card body having bending properties satisfying the requirements of the ISO standard and an elec~ronic module constituting a data medium, the method comprising the steps of:
(a) providing a mold having a mold volume limited by two parallel main faces substantlally rectangular in shape and an edge, said main faces having a width of about 55 mm and a length of about 85 mm, the distance separating said two main faces being approximately 0.8 mm, one of said maln faces being provided with an extension for defining a cavity in the card body; (b) injecting an acrylonitrile butadiene styrene (ABS) to fill all of said mold volume to form the entire card body ~herewith; (c) unmolding the card body so obtained; (d) providing an electronic module comprising an insulating support having electrical contact tabs on one of its two faces and a semiconductor chip fixed on the other face of said insulating support; an~ (e) placing said electronic ~ 20 module within said cavity and fixing said electronic module to : said card body.
According to a further broad aspect of the invention, there is disclosed a method of making an electronic memory card having dimensional bending properties satisfying tbe re~uirements of the ISO standard and an electronic module fastened within a cavity formed in said card body, comprising the step~ of:
providing a mold having an inner mold volu~e limited by two 3a gs 6~216-4 parallel main faces subs~antially rectangular and an edge, said main faces being separated by a distance less than 1 mm, providing a projection on one of said two main faces for defining said cavity in the card body, providing an injection point on the other of said two main faces, said in~ection point being opposite said projection, injecting into ~he mold through said injection point a thermoplastic materlal to fill said mold volume, thereby forming said card body, unmolding the card body from said mold, and fastening said electronic module into the cavity of said card body.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be better understood from reading the following description of several implementa~ions of the inven~ion given by way of non-limiting example. The description refers to the accompanying drawings, in which;
Figure 1 is a plan view of a card body in ac~ordance with the invention;
Flgure la is a detail view of Figure ~ showing the cavity provided in the card body;
Figure 2 is a fragmentary sec~ion on line II-II of Figure la;
Figure 3 is a simplified horizontal section through a mold for making a card body in accordance with the invention;
Figure 4 is a vertical section view through the Figure 3 mold on line IV-IV;
Figure 5 is a vertical section view through an : 3b , . . .
~LZ9~95 electronic module for mountlng on the card body o~ Eigures 1 and 2;
Figures 6 and 7 show the printed circult of the electronic module as seen from above and from below, respectively;
Figure 8 is a fragmentary view of the card showing the electronic module implanted in the card body; and Figures ~ and 9a show an embodiment of the card body in which the memory module is magnetic.
MORE DETAILED DESCRIPTION
:; 10 With reference initially to Figures 1 and 2, there follows a description of one particular form of card body made in accordance with the invention.
3c .
lZ~95 -The body 2 has the form of a rectangular parallelipiped with two main faces 4 and 6 which are generally rectangular in shape. The dimensions of the main faces are approximately 85 mm (length L) by 55 mm (width l). The thickness of the card body is about 0.8 mm. As can be seen in Figure 1, the card body also includes a cavity 8 which opens out into main face 4.
The cavity 8 has a constant depth of 0.25 mm and its dimensions `~ in the plane of the main face 4 are 11 mm by 13 mm.
Figure 1 shows that the cavity 8 includes eigh-t studs 10 10 which project from its bottom 12. The studs are disposed in two parallel lines.
Figure 2 shows that each stud 10 comprises a base 14 having a diameter of 2 mm and a thickness of 0.05 mm, together with a terminal portion 16 of diameter 1 mm and of thickness 0.19 mm.
In accordance with the invention, the card body is made by hot injection molding. The plastic material used is an acrylo-nitrile butadiene styrene. The material is in;ected into the mold at a temperature lying between 180C and 280C, and 20 preferably between 220C and 260C, and -the mold is maintained at a temperature lying between 5C and 100C, and preferably between 10C and 50C.
Other plastic materials could also be used, e.g. poly-styrene, polypropylene, and polyamine 11, in which case the ; 25 injection parameters will need changing.
With reference to Figures 3 and 4, there follows a description in greater detail of an example of a mold for implementing the invention. The mold comprises a fixed front portion 20 and a moving rear portion 22. The front portion 20 has a main face 20a which defines the main face 6 of the card body and a side wall 20b which defines the edge of the card.
The rear portion 22 has a face 22a which defines the second main face 4 of the card body. A core 24 is mounted in the portion 22 and serves to make the cavity 8. The core therefore occupies the same position in the face 22a of the portion 22 as is occupied by the cavity 8 in the face 4 of the card body.
The face 24a of the core 24 defines the bottom 12 of the cavity 3~2~ 95 ... ~
a~d includes eight s-tepped hollows 26 which define the shape of the studs 10.
Returning to the portion 20, it can be seen that the face 20a includes a portion 28 which projects slightly and faces the 5 core 24. The in;ection channel 30 opens out into the pro;ection 28. This channel opens out opposite the center of the face 24a of the core 24, i.e. opposite the center of the cavity 8. Naturally, when the two portions 2G and 22 are fixed together, the space between them defines the mold volume and thus the volume of the card. It should be added that the core 24 placed opposite the injection point is provided with a cooling system represented by cooling liquid flow duct 32.
Various tests have been performed and have shown that the above method makes it possible to obtain card bodies under highly satisfactory economic conditions while satisfying the above-mentioned specifications, in spite of the general shape of the part which is unfavorable for molding, in particular in spite of its thinness (0.8 mm).
In particular, by virtue of the particular injection technique, the card body has good bending characteristics and its longitudinal dimension (L) and its transverse dimension (l) are good and satisfy the requirements of the IS0 standard.
More precisely, this standard requires that after 250 bending operations with a central offset of 5 mm when bending across the width and a central offset of lO mm when bending along the length,--the apparent width of the card should remain less than 0.94 mm.
In addition, the advantages of the method in accordance with the invention appear clearly. The card body with the shape in particular of its cavity including the studs is obtained in a single operation and the position of the cavity ; relative to the edges is fully repeatable.
Returning to Figure 3, it is obvious that the core 24 could be omitted providing the face 22a of mold portion 22 is machined in such a manner as to define itself a shape corres-ponding to the end 24a of the core. It should also be added that the method of the invention may be applied to making other I .
~2~9S
.... ~
shapes of card body, in particular bodies having different cavity shapes and different numbers of cavities. In a card body having a plurality of cavities, it may be advantageous to provide one injection point level with each cavity.
Another important advantage of the method in accordance with the invention is that the card body may be embossed using conventional techniques. In many card applications the manufacturer is required to emboss personalizing information on one of the faces of the card.
It must also be underlined that the card body obtained in this way is capable of receiving a magnetic track and of being silk-screen printed with igures or text.
There follows a description with reference to Figures 5 to 8 of the method of manufacturing an electronic memory card using a card body obtained by the molding method in accordance with the invention.
Figure 5 shows an electronic module 40 which is to be implanted in the card body 2. The electronic module essentially comprises a single sided printed circuit 42 and a semiconductor chip 44 having appropriate electronic circuits made thereon, and in particular having memory circuits.
The printed circuit 42 includes an insulating support 46 ~` made of polyester with a layer of conductive material, typically copper, being disposed on one of the faces thereof.
` 25 As can be seen better in Figure 7, the insulating support 46 is pierced by a central window 50, by eight bonding holes 52 surrounding the central window 50, and by eight pre-fastening holes 54. The eight pre-fastening holes 54 occupy the same physical dispositions as -the eight studs lO of the card body and they are of very slightly larger diameter than the terminal portions 16 of the studs.
With reference to Figure 6, it can be seen that the layer ~; of metallization 48 is etched so as to define:
a) eight electrical contact tabs 56 to 70 which are disposed over the pre-fastening holes;
b) nine electrical contact points 72 to 88 corresponding to the central window 50 and to the eight bonding holes 52; and .
i :12g~5 ; c) conducting tracks for interconnecting each contact point to an electrical connection tab and also for connecting the central metallization 72 to contact point 74.
Returning to Figure 5, it can be seen that the semi-5 conductor chip 44 is placed in the central window 50 and isfixed on the central metallization 72 by a conductive glue 90.
In addition, each terminal 92 of the chip 44 is connected to a corresponding one of the contact poin-ts 74 to 88 by a conducting wire 94 whose opposite end passes through the corresponding 10 bonding hole 52 and is bonded to the face of the contact point which closes the bottom of the bonding hole. Thus, each terminal 92 of the semiconductor chip together wi-th the rear face thereof is electrically connected to a contact tab.
The insulating support 46 is 150 microns thick and the metallization layer 48 is 50 microns thick. It may be observed that the thickness of the insulating support of the printed circuit is less than the height of the terminal portion 16 of each stud 10.
Figure 8 shows the electronic module 40 implanted in the card body as made by molding.
In a prior step, a hole 100 is made which opens out firstly into the cavity 8 between the two lines of studs 10 (see the dashed line circle in Figure la) and secondly into a hollow 102 provided in the face 6 of the card body by the ; 25 projecting portion 28 of the injection mold.
The electronic module 40 is put into place in the cavity 8 of the body 2 in such a manner that the terminal portions 16 of the studs penetrate into the pre-fastening holes 54. The face 48a of the printed circuit is not in contact with the bases 14 of the studs. The space remaining is about 0.040 mm across.
In the following step, the metallizations 48 over the pre-fastening holes 54 are heated. As a result the ends of the terminal portions 16 of the studs are deformed and expand as ; shown at 16a in Figure 9. This gives rise to pre-fastening and positions the electronic module 40 on the card body 2, In particular, the face 48a of the printed circuit 42 comes into contact with the bases 14 of the studs 10.
., ~-' lZ~
The card body can then be turned over in order to terminate fixing of the electronic module 40.
Glue is caused to penetrate through the hole 100, e.g. a hot setting epoxy glue (104) which fills the hole 100 together ; 5 with the space left free between the bottom 12 of the cavity 8 and the printed circuit. As a result the module is finally glued to the card body and the hole 100 is filled, thereby simultaneously providing the protective covering for the semiconductor chip 44 and its connection wires 94. By virtue 10 of the hollow 102, it is possible to mill the face 104a of the glue deposit 104 without running the risk of spoiling the face 6 per se of the card body.
The above description relates more particularly to putting an electronic of the type shown in Figure 5 into place.
However, it should be understood that the method of the invention may be used to making electronic memory cards including other types of electronic modules. In particular, instead of providing electrical connection tabs, the connection with the card reader could be provided by inductive coupling.
Similarly, instead of having studs on the bottom of the cavity in order to position and pre-fasten the electronic module, other forms of relief could be provided, on the condition that they can be made by molding. The method may also be implemented without making the hole 100.
In this case, the glue is inserted into the cavity through the front face of the electronic module, or else the glue is put onto the rear facs of the printed circuit before the electronic module is put into place on the card body. Finally, the memory module could be a magnetic memory component.
Fi~ures 9a and 9b show the body of a card made in accordance with the invention and suitable for receiving a memory module constituted by a magnetic track. The card body 120 has the same rectangular shape as the card body shown in Figure 1 and the same outside dimensions. It includes two main 35 faces 122 and 124 which are mutually parallel and it is 0.8 mm thick. A cavity 126 running parallel to one of the long sides of the card is formed in the face 122 and said cavity extends . ~
over the entire length of the card. As seen better in Figure 9b, cavity 126 has a uniform rectangular cross-sec-tion. The depth of the cavity is about 0.2 mm.
Such a card body 126 is obtained by molding in accordance with the above-described technique. The only difference lies in the shape of the molding core which must be complementary to the shape of the cavity. The plastic material injection duct opens out into the core defining the cavity.
The magnetic track is put into place in the cavity and is fixed to the card body either by gluing or by hot-rolling.
':
, 25 :
Claims (13)
1. A method for making an electronic memory card comprising a card body which is substantially in the form of a rectangular parallelipiped having two main faces, said card body satisfying the requirements of the ISO standard regarding the dimensions of the card body and the bending properties of said card body, said card body containing an electronic module constituting a data medium, the method comprising the steps of: (a) providing a mold having an inner mold volume limited by two parallel main faces substantially rectangular and an edge, said main faces being separated by a distance less than 1 mm, one of said main faces being provided with a projection for defining a cavity in the card body; (b) injecting into said mold volume a thermoplastic material, for said plastic material to fill all of said mold volume to form the entire card body therewith; (c) unmolding the card body so obtained; (d) providing an electronic module; and (e) fixing said electronic module into the cavity produced by the projection on said one of said main faces of said mold.
2. The method according to claim 1, wherein said main face of the mold volume has a width of about 55 mm and a length of about 85 mm, and the distance between said two main faces is approximately 0.8 mm.
3. The method according to claim 1 wherein said plastic material is injected into said mold volume through an injection hole located in one of said main faces of said mold.
4. The method according to claim 3 wherein said injection hole is located in the part of the main face remote from said projection.
5. The method according to claim 1 wherein said thermoplastic material is an acrylonitrile butadiene styrene which is injected at a temperature lying between 220 degrees Centigrade and 260 degrees Centigrade, and the mold is kept at a temperature lying between 10 degrees Centigrade and 50 degrees Centigrade.
6. A method of making an electronic memory card comprising a card body having bending properties satisfying the requirements of the ISO standard and an electronic module constituting a data medium, the method comprising the steps of: (a) providing a mold having a mold volume limited by two parallel main faces substantially rectangular in shape and an edge, said main faces having a width of about 55 mm and a length of about 85 mm, the distance separating said two main faces being approximately 0.8 mm, one of said main faces being provided with an extension for defining a cavity in the card body; (b) injecting an acrylonitrile butadiene styrene (ABS) to fill all of said mold volume to form the entire card body therewith; (c) unmolding the card body so obtained; (d) providing an electronic module comprising an insulating support having electrical contact tabs on one of its two faces and a semiconductor chip fixed on the other face of said insulating support; and (e) placing said electronic module within said cavity and fixing said electronic module to said card body.
7. The method according to claim 1, wherein, after said electronic module has been fixed in place, symbols are embossed on the card body.
8. The method according to claim 6, wherein after said module has been fixed in place, a magnetic track is affixed to the main face of said card body.
9. The method according to claim 6, wherein said electronic module includes a printed circuit component comprising an insulating support having a plurality of holes therethrough together with metallization to define said electrical contact tabs, said metallization closing one end of each of said holes, and wherein a plurality of studs projecting into said cavity are formed when the card body is made by injection molding, with the diameter of such studs being smaller than the diameter of said holes, placing the electronic module into said cavity with said studs on the card body penetrating, respectively, into said holes through the insulating support, and heating said electronic module locally to soften and crush the ends of said studs so that the crushed stud ends spread to engage the periphery of the holes, thereby fastening the electronic module to the card body.
10. A method of making an electronic memory card having dimensional bending properties satisfying the requirements of the ISO standard and an electronic module fastened within a cavity formed in said card body, comprising the steps of: providing a mold having an inner mold volume limited by two parallel main faces substantially rectangular and an edge, said main faces being separated by a distance less than 1 mm, providing a projection on one of said two main faces for defining said cavity in the card body, providing an injection point on the other of said two main faces, said injection point being opposite said projection, injecting into the mold through said injection point a thermoplastic material to fill said mold volume, thereby forming said card body, unmolding the card body from said mold, and fastening said electronic module into the cavity of said card body.
11. The method of claim 10, further comprising the steps of providing said projection with hollows to define studs extending from a bottom of said cavity in the card body.
12. The method of claim 10, wherein the steps of providing a projection on one of said two main faces comprises providing a core.
13. The method of claim 12, further comprising the step of cooling said core.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000549181A CA1294095C (en) | 1987-10-15 | 1987-10-15 | Method of making cards, in particular memory cards |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000549181A CA1294095C (en) | 1987-10-15 | 1987-10-15 | Method of making cards, in particular memory cards |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1294095C true CA1294095C (en) | 1992-01-14 |
Family
ID=4136635
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000549181A Expired - Fee Related CA1294095C (en) | 1987-10-15 | 1987-10-15 | Method of making cards, in particular memory cards |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1294095C (en) |
-
1987
- 1987-10-15 CA CA000549181A patent/CA1294095C/en not_active Expired - Fee Related
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| US5030309A (en) | Method for making cards, in particular memory cards | |
| US4961893A (en) | Method for manufacturing memory cards | |
| EP0377937B1 (en) | IC card | |
| US5550402A (en) | Electronic module of extra-thin construction | |
| US5057460A (en) | Method of making an electronic module, for insertion into an electronic memory-card body | |
| US6013945A (en) | Electronic module for data cards | |
| JPS63239097A (en) | Manufacture of memory card and memory card manufactured by executing said method | |
| JP2002535784A (en) | Micro module combined with chip card with loop antenna | |
| KR100487175B1 (en) | Data carrier having a module including an electronic component and having a coil, and method of manufacturing such a data carrier | |
| US5913110A (en) | Method for producing a plastic material composite component, a plastic material composite component and a mold for injection molding same | |
| EP1346316B1 (en) | Electronic data storage medium | |
| CA1294095C (en) | Method of making cards, in particular memory cards | |
| KR100480522B1 (en) | Data carrier having a module including a component and having a coil, and method of manufacturing such a data carrier | |
| US20040238210A1 (en) | Electronic module with protective bump | |
| WO2004023386A1 (en) | Combination-type ic card and method of manufacturing the combination-type ic card | |
| JPS61133489A (en) | Memory card | |
| JP2524606C (en) | ||
| EP1176547B1 (en) | Labeled chipcard | |
| CN208367728U (en) | Smart card | |
| EP0600501A1 (en) | Resin molded semiconductor device | |
| JPH10247232A (en) | Semiconductor device and its manufacture | |
| JPH0559808B2 (en) | ||
| JPS63139794A (en) | Manufacture of ic card | |
| JPS60209888A (en) | Manufacture of ic card | |
| JP2002109488A (en) | Production method for composite ic card |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| MKLA | Lapsed |