The invention relates to a pen which is easy to carry in a handbag or jacket pocket and which allows a nail gel to be applied quickly and safely to a finger nail and then cured by means of UV light. In a particular embodiment, the pen can contain an RFID or NFC chip, i.e. a transponder chip, so that it can be placed on a finger nail using the nail gel or can be set onto the finger nail in a self-adhesive manner and be covered with gel so that it is held in place by the gel or gel varnish, either visibly in the case of clear varnish or invisibly in the case of a top coat or gel. The chip can be concealed under or on top of the nail varnish or a nail processing system (gel varnish, acrylic, wrap, or the like). In this way, an RFID chip can be elegantly attached to a natural or artificial finger nail or toe nail.
Ordinary nail varnish lasts for about 2 to 3 days after application, then it becomes brittle and can chip off. Nail gel or gel varnish, on the other hand, has to be applied far less often. After application, for example with a brush, the gel is cured with a special light source that emits UV light, and a finger nail coated in this way remains beautiful for about 2 weeks, and the gel lasts over this period of time without any loss of quality. When traveling, curing often remains a problem because a suitable UV light source is missing.
The main object of the present invention is therefore to create a portable utensil which contains everything necessary to safely apply a nail gel on the go and to cure it on the nail by means of UV light. The object of a particular embodiment is to create such a utensil, which also contains everything necessary to connect an RFID chip securely, inconspicuously, and non-invasively to a human body in such a way that the RFID chip can be carried securely on the body anywhere and for all activities, and yet it can be removed or exchanged at any time.
The main object is achieved by a pen having a closable cavity for receiving gel varnish and a brush for applying this to a finger nail, as well as a battery-operated LED/LEV light for UV light for curing gel varnish applied with a brush to a finger nail. The extended object is achieved by such a pen with an additional closable cavity for at least one RFID chip.
In the drawings, an embodiment of this pen is shown and the structure and function thereof are described and explained below.
In the drawings:
Seen from the outside, the pen is designed similarly to a writing pen, of similar thickness and length, as shown in
In
The brush 5 itself consists of a handle made of plastics material and having flat bristles 17 at the ends which are suitable for applying a liquid gel varnish 14 to a finger nail. In an optional embodiment, the pen body 1 can be designed so that it forms a flat compartment next to the blind hole 7 for the gel varnish 14, similar to a knife sheath into which a nailfile with or without a handle can be inserted. The lid cap 2 can then form a handle for this nailfile, for easier processing of a finger nail. The lower end of the pen body 1 has a further, downwardly open blind hole, which is designed as a battery compartment, for receiving a battery 15 or a rechargeable battery. The pen body 1 can also be equipped with a photovoltaic element to continuously charge the battery as soon as sufficient light hits this element. In addition, the pen body 1 can be equipped with an externally accessible USB socket for plugging in a charging cable. The lower end of the pen body 1 forms a step and a taper, which is provided with an external thread 10. The matching internal thread of a sleeve 18 can be screwed onto this external thread 10, enclosing and making electrical contact with the battery 15, for example a button battery for an LED or LEV light 11 at the other end of the sleeve 18, which is located there in an inner cone 13, which extends toward the outside to the lower edge of the sleeve 18. An on-off switch 12 is installed on the side of the pen body 1 in order to switch the light 11 on and off.
In the interior of the lid cap 2, a cylindrical cavity 22 is located in the form of a blind hole in the example shown. A plurality of RFID chips 21 can be inserted into this cavity 22 and stored therein. The cavity 22 can be closed on the lid cap 2 by means of a threaded cap 3. The lid cap 2 can be equipped with a clip-on clip 16, as in the case of a fountain pen.
Each of these RFID chips 21 can interact with an RFID or NFC system if it is held close enough to a transmitter/receiver of an RFID or NFC system. This RFID chip 21 acts as a transponder, also known colloquially as a wireless tag, and it can be located on an object or in a living being and contain an identifying code. The RFID or NFC system includes a reading device for reading out the identifier of a detected RFID chip 21. RFID transponders can be as small as a grain of rice and can be implanted, for example in pets or humans. In addition, there is the possibility of producing RFID or NFC transponders using a special printing process for stable circuits made of polymers. The advantages of this technology result from the combination of the small size, the inconspicuous readout option, and the low price of the transponder, sometimes in the euro cent range. The coupling takes place via magnetic alternating fields generated by the reading device within a short range or via high-frequency radio waves. This not only transfers data, but also supplies the transponder with energy. To achieve greater ranges, active transponders with their own power supply are used, but these are associated with higher costs. The reading device contains software in the form of a micro-program that controls the actual reading process, and an RFID middleware with interfaces to other IT systems and databases. By identifying the RFID chip 21 on a person, a connection to a software application can be established, which allows for a wide range of applications.
This pen, filled with gel varnish and equipped with a plurality of RFID chips 21, makes it possible to mount such a chip 21 anytime and anywhere on a natural or artificial finger nail. For this purpose, the finger nail is prepared as necessary with the nailfile. Subsequently, the desired RFID chip 21 is removed from the blind hole 22 after the threaded cap 3 has been unscrewed, and the threaded cap 3 is screwed on again in order to secure the remaining RFID chips 21 contained. The removal can also take place by pushing out the individual RFID or NFC chips 21. Then the lid cap 2 is unscrewed or pulled off the pen body 1. Now it can be applied to the finger nail with the brush 5 while removing gel varnish 14 from the blind hole 7 in the pen body 1. The removed RFID chip 21 can be placed directly on the natural or artificial nail since this can already be provided with adhesive. Or this chip can be placed on the applied varnish or gel varnish layer on the finger nail and then painted over with varnish so that it is completely enclosed by the varnish or gel varnish. A plurality of layers of gel 14 can be applied until the RFID chip 21 is completely covered by gel varnish. Thereafter, the lid cap 2 is screwed or plugged back onto the pen body 1 and then the switch 12 is set to ON, so that the LED or LEV light 11 is switched on. The emitted UV light is directed onto the gel varnish 14 on the finger nail, which ensures that it cures in a few seconds. After the gel varnish 14 is cured, the RFID chip 21 is secured and embedded into a layer of nail varnish or gel 14 on the finger nail either invisibly—or, if desired, also visibly, simply by thin coating.
In this way, different RFID chips 21 can be attached to the different finger nails of a hand. One RFID chip can serve, for example, to trigger a financial transaction through the NFC identification of the paying person, who, in this case, only has to hold their finger nail with the relevant RFID chip 21 near a transmitter/reading device set up for this purpose. Another finger nail with a different RFID chip 21 can be used, for example, to unlock and lock a car door, another for operating the lock on the apartment door, etc. One chip can also offer the possibility of triggering a plurality of applications.
With the help of this pen, filled with gel varnish, the gel varnish can be applied to a natural or artificial finger nail anywhere, including on the go. For this purpose, the finger nail is prepared as necessary using the nailfile. Gel varnish 14 is then removed with the brush 5 from the blind hole-like cavity 7 in the pen body 1 and applied to the finger nail so that it is covered completely or as desired by the varnish or gel varnish. Multiple layers of gel 14 can be applied. Thereafter, the lid cap 2 is screwed or plugged back onto the pen body and then the switch 12 is set to ON, so that the LED or LEV light 11 is switched on and emits UV light. The emitted UV light is directed onto the gel varnish 14 on the finger nail, which ensures that it cures in a few seconds. Thus, the gel can be cured instantly on the spot. In this way, gel varnish can be applied to the finger nails and cured on the various finger nails of one hand with the help of the other hand and this utensil.
Number | Date | Country | Kind |
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00021/19 | Jan 2019 | CH | national |
00875/19 | Jul 2019 | CH | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/050555 | 1/10/2020 | WO | 00 |