The present invention relates exclusively to the field of mail handling and it relates more particularly to an ink collection device in a postage meter or franking machine for franking mailpieces using inkjet printing technology.
It is well known that using an inkjet print head is affected by clogging-up of the ink ejection nozzles of the head.
Therefore, inkjet ejection nozzles need to be cleaned periodically and it is necessary to spit ink out during such cleaning so as not to leave dried ink in the nozzles. Since the lifespan of the print head of a franking machine can currently reach about 1.5 million cycles, such periodic spraying of ink represents a relatively large quantity of residual ink (typically, it is recommended to spit out 4000 droplets at each cleaning cycle). In current machines, that quantity is accumulated on a plane sponge disposed in a reservoir or “spittoon” mounted at the servicing station for servicing the print head.
Unfortunately, such a solution, as illustrated, for example, by Patent Application US2003/0142150 is not without drawbacks. Firstly, due to the large volume of ink spat out in a limited time during the cleaning cycle, the sponge must be a relatively long way away from the ink ejection nozzles, and this gives rise to ink-droplet aerosol phenomena that then soil the servicing station and more generally the structure of the franking machine as a whole, in particular the various cells for detecting presence of mailpieces. In addition, such aerosol phenomena are worsened by the flow of air generated by the fan when the temperature of the motor in the machine rises or by the movement of the mailpieces after a cleaning cycle.
The present invention proposes to mitigate those drawbacks with an ink collection device for a servicing station of a franking machine, said ink collection device comprising:
Thus, the fine ink droplets ejected by the nozzles are collected, and run off as thick drops before the aerosol phenomena occur as in the prior art. Ink sprays are avoided and there is no longer any soiling of the servicing station or of the franking machine, and in particular of the electronic circuits thereof and of the casing thereof.
Preferably, said determined distance between said ink ejection nozzles and said smooth pin lies in the range 3 millimeters (mm) to 5 mm, and the diameter of said smooth pin lies in the range 1 mm to 2 mm.
When said print module has two parallel rows of ink ejection nozzles, said drainage duct has two parallel pins that are united to form a hairpin-shape pin with two parallel open branches, the curved junction portion between the two branches of said hairpin-shape pin being held securely in said drainage duct by a fastener stud.
The present invention also provides a franking machine servicing station including the above-mentioned ink collection reservoir.
The characteristics and advantages of the present invention appear more clearly from the following description given by way of non-limiting indication and with reference to the accompanying drawings, in which:
During the periodic cleaning of the print modules, the ejection nozzles of those modules spit ink out and thus spray ink through the drainage ducts to the reservoir that faces them. Ink is also spat out when the machine is switched on, and after it has been put on standby for a prolonged period of time. However, although such spraying is, in theory, directed due to the action of the drainage ducts, it is impossible to avoid aerosol phenomena that take advantage of the gap 20 and quickly lead to the servicing station and the various elements of the surrounding franking machine being soiled. In practice, with one cleaning cycle every 300 printing operations, the inventors have observed that it takes only 30,000 print operations for the servicing station to be totally soiled.
That is why, in accordance to the invention, and as shown in
More particularly, the diameter of the pin is adapted to the diameter of the nozzles and to the distance between the nozzles and the pin. If the diameter of the pin is too small or if the pin is too far away from the nozzles, the dispersion of the droplets is not braked. If said diameter is too large, the formation of droplets is disrupted and, when the print module has two rows of nozzles, a bridge of ink forms between the two pins that are placed below respective ones of the two rows and that are then too close together.
In practice, for nozzle diameters of 0.04 mm and a pitch of 4.11 mm from row to row, each of which has a length of 12.66 mm, the inventors have obtained excellent results with a pin having a diameter of 1.5 mm and placed at a distance of 3.8 mm from the nozzles. For a distance between the nozzles and the pin lying in the range 3 mm to 5 mm and a nozzle diameter lying in the range 0.02 mm to 0.05 mm, a pin diameter lying in the range 1 mm to 2 mm is entirely satisfactory.
Thus, with the invention, by collecting ink drops as close as possible to the ejection nozzles, soiling of the servicing station and thus of the franking machine is delayed considerably, given that tests performed by the inventors show that even after 1.5 million print cycles, no significant soiling is observed, including on the casing of the franking machine.
Number | Date | Country | Kind |
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0758983 | Nov 2007 | FR | national |