NL1019264C2 - Screen printing method for producing an electrically conductive image on a substrate. - Google Patents

Description

Brief description: Screen printing method for producing an electrically conductive image on a substrate.

The present invention relates to a method for manufacturing an electrically conductive image, comprising a step of screen printing conductive material on a substrate.

Such a method for manufacturing an antenna with a mostly spiral shape is known, for example, from French patent specification 2 769 440. Antennas manufactured in this way are used, for example, as transponders in electronic memory cards, etc., which can be read without contact, or hybrid cards which are both contactless be readable in contact via fixed contact points. Examples thereof include telephone cards, access badges, bank cards and other so-called smart cards for other purposes. With these cards, information is exchanged between the memory chip of such a card and a reading device by remote electromagnetic coupling between a first antenna provided on the card and a second antenna located in the read / write device to provide.

In the method for manufacturing the antenna known from the above-mentioned French patent specification, an electrically conductive ink 20 is applied to an insulating substrate by means of screen printing. Such a conductive ink comprises, for example, a content of metal particles between 60-95% in a polymer matrix and a suitable solvent. According to the French patent mentioned above, several antennas can be manufactured simultaneously on a substrate, whereafter the substrate is subsequently divided into pieces, with an antenna on each piece.

According to WO 98/11507, an integrated circuit can be provided by means of screen printing simultaneously with the antenna. In this patent publication an electrically conductive ink loaded with silver, copper or gold is used for screen printing the antenna on a substrate, for example a polymer substrate. US-A-6 137 444 and DE-A1-19 511 300 also use silver-based conductive screen printing inks in the manufacture of such antennas. Furthermore, it is known in the art that preforms of antennas deposited by screen printing, often spirals comprising multiple windings, can be reinforced with a suitable metal by means of electroplating.

Another method for the manufacture of such antennas is known, for example, from US Pat. No. 3,907,555, in which the antennas are etched from a foil, for example from a copper foil. The copper antennas thus formed can for example be plated with tin in order to increase the solderability and the corrosion resistance. Coating with tin to connect the antenna coil to a semiconductor chip has also been proposed in US-A-5 809 633.

Such antennas, which can transmit and receive signals, must have good conductivity, since no energy may be lost. A loss of energy means a reduction of the potential range. The thickness of the antenna is often limited by the application, e.g. the total thickness of the card, which must meet certain standards.

In the above-described method using a conductive ink, after solvent printing, the solvent used must be removed by drying, which requires relatively high temperatures. However, many of the substrates used from an organic polymeric material cannot withstand such a temperature, thereby affecting the physical properties and / or appearance of the substrate. In addition, the conductivity of the antennas thus produced leaves something to be desired.

The present invention has for its object to provide a method for manufacturing an electrically conductive image on a substrate by means of screen printing, wherein the above-mentioned problems do not occur or occur to a lesser extent. In particular, the present invention has for its object to provide a method for manufacturing such images, wherein the images thus obtained had a higher conductivity compared to the prior art.

In the method of the type mentioned in the preamble, the conductive material for this purpose is a molten metal or metal alloy. By screen printing an electrically conductive metal or metal compound, such as an alloy, with high conductivity, without a liquid or pasty carrier to be removed later, on a substrate, images with high conductivity can be obtained, whereby the scope thereof is large. Furthermore, no drying step is necessary, as a result of which attack of the substrate can hardly occur. Because a very thin layer of metal or metal alloy with high conductivity is applied, in the order of magnitude of a maximum of 100 micrometres, it will solidify immediately, and the heat transfer to the substrate is so low that deterioration thereof is omitted. Additional steps are therefore not necessary.

The electrically conductive image can have any shape or function. Examples include the aforementioned antennas, but also electrically conductive paths or tracks, for example of a printed circuit board (pcb), can be applied to a suitable substrate with the method according to the invention. Another application example is current collectors in solar cells.

Preferably, the high conductivity conductive material is selected from indium metal, tin metal, lead metal, bismuth, oxides thereof, and the alloys and alloy oxides, including indium tin oxide (ITO). Tin is advantageously used because of its high conductivity and its good corrosion resistance, which are, for example, greater than that of silver. Tin is also a good fastener. Furthermore, tin has the advantage of a high elongation, so that the use of tin antennas in highly flexible cards is permitted. Indium has a relatively low melting point, about 160 ° C, which is advantageous from the viewpoint of energy costs in the method according to the invention.

The substrate used in the method according to the invention can be paper or a polymer substrate. Paper is advantageously used, which lowers the cost of manufacture compared to the use of polymeric substrates. If necessary, the substrate can be of a fire-retardant type.

In view of the speed of manufacture and mass production, rotary screen printing is advantageously used.

In screen printing, multiple images can be produced simultaneously next to each other, which are then packaged separately. With further assembly, for example at the manufacturer of smart cards etc., the image, such as an antenna, can then be mounted on a carrier at the correct position.

The present invention also relates to a method for manufacturing a printed circuit board, as defined in claim 6.

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When the image is a track or track on the carrier, for example of plastic, of a printed circuit, it is possible to use a suitable temperature control to delay the solidification of the electrically conductive material, so that it is possible to position the electronic components on the applied track while the conductive material is still liquid - at least not yet solidified. By (controlled) cooling and solidification of the electrically conductive material, these components are then fixedly attached to the support. In this case, the image functions partly as a conductor, partly as a fastener. Examples of such components include resistors, batteries, capacitors, ICs, etc. Attaching fixed terminals to the ends of an antenna can be done in the same way.

The invention further relates to a method for manufacturing antennas, as defined in claim 7.

For the use of antennas, it is often necessary to connect the ends with a chip. This chip may not make electrical contact with the other windings of the antenna. In a further embodiment of the method according to the invention, the method comprises an additional step of applying an insulator over the previously deposited metal. This insulator is preferably arranged in a following (rotation) screen printing station.

Claims (7)

A method for producing an electrically conductive image, comprising a step of screen printing a conductive material on a substrate, characterized in that the conductive material is a molten metal or metal alloy. Method according to claim 1, characterized in that the conductive material is selected from indium metal, tin metal, lead metal, bismuth, oxides thereof, alloys and alloy oxides thereof. 3. Method as claimed in any of the foregoing claims, characterized in that the substrate is paper. Method according to one of the preceding claims, characterized in that the substrate is a paper or polymer substrate, which can be fire-retardant if desired. 5. Method as claimed in any of the foregoing claims, characterized in that the screen printing is rotary screen printing. 6. A method for manufacturing a printed circuit board with at least one electronic component, comprising the steps of screen printing a molten metal or metal alloy on a substrate to form an electrically conductive image, positioning at least at least one electronic component in the image, while the electrically conductive material is still liquid, and allowing the formed assembly to cool. 7. Method for manufacturing an antenna, comprising a step of screen printing a conductive, molten metal or metal alloy on a substrate to form an electrically conductive image, and applying an insulating material over the thus printed electrically conductive image .