NL9001777A - Transponder with glass housing - is enclosed by flexible cladding - Google Patents

Abstract

The transponder comprises a closed glass housing contg. electrical components. Flexible cladding encloses the housing, and can incorporate a sleeve and can be of plastic and shrinkable. It can be arranged to leave one or both ends of the housing free, and can be chamfered at the edges. The housing can be filled with a polysiloxane-base gel.

Description

Transponder.

The invention relates to a transponder, comprising a closed glass housing with electrical components incorporated therein.

Such a transponder is generally known in the prior art and is used, for example, as a housing for electronic components, which must be inserted into the body of, for example, an animal in order to identify this animal. However, transponders can also be used for many other purposes. In the prior art, two kinds of material have been used for the housing to date. Glass has the advantage that it is impermeable to body fluids and other aggressive substances, so that the electronic components contained within the housing cannot be affected even after a longer residence time. Glass also has the advantage that the body accepts this material. The drawback is that glass adheres less well to the body, so that it can move through the body, so that it is difficult to find the transponder at a later stage, for example during slaughter. A further drawback of glass is that breakage can occur, especially during insertion, and the resulting glass splinters can wander through the body and end up in flesh parts, acting as a source of infection or ultimately posing a danger to humans when the meat is consumed.

To overcome these drawbacks, it has been proposed to make the transponder housing of plastic. Plastic materials have the advantage that better adhesion to the body is possible, so that wandering can be prevented. In addition, it is possible to adhere disinfectant to the somewhat rough surface of plastic material, so that disinfection can be prevented to a greater extent. There is no danger of splinters resulting from breakage if the plastic material is selected correctly. Hitherto, however, a major drawback of plastic has been that it does not appear to be tight and substances eventually enter the housing through diffusion processes, which deteriorate the proper functioning of the electronic components contained in that housing. In addition, the compressive strength of plastic is considerably less than that of glass.

The object of the present invention is to provide a transponder which combines the advantageous properties of both the glass and the plastic housing, but does not have the drawbacks thereof.

This object is achieved with a transponder described above in that a flexible cover is arranged around the glass housing. By applying a flexible cover around the glass housing, it is prevented that glass splinters are released from the transponder in the event of breakage. These are held by the cover. The flexible cover can have a greater surface roughness than the exterior of a glass housing, so that good adhesion to the body is ensured and disinfectants can also be introduced to the surface thereof when the transponder is introduced. Because a glass housing is used, there is no danger of penetration of harmful fluids and the service life of the transponder is unlimited. The increased compressive strength of a glass transponder is a further advantageous property of the transponder according to the invention. Although any material can be used for the cover in any condition, such as a reticulated structure, it is preferred that the cover comprise a sleeve. In particular, the cover is made of plastic material. In order to achieve good contact and simple application of the cover to the glass housing, the cover is preferably made of shrinkable material. /

To avoid sharp protrusions as much as possible, the cover does not extend to the ends of the glass housing, but at least partially keeps it free. In addition, the end limit of the cover may be chamfered. After all, sharp protruding parts form a point where the body tissue dies and detaches from the transponder, so that a starting point is given for wandering the transponder.

According to a further advantageous embodiment, the housing is filled with a silicone-based gel.

Although the invention has been described above with reference to the application of a transponder into the body of living beings, it is to be understood that all other uses of transponders can be accomplished with the transponder described above.

The invention will be explained in more detail below with reference to an illustrative embodiment shown in the drawing. The only figure shows schematically in cross section a transponder according to the invention.

The transponder according to the invention is indicated in its entirety by 1 and comprises a glass housing 2, inside which electronic components are arranged, such as a ferrite rod 3. functioning as an antenna part, a carrier 4 and a chip 5. Such electronic components can be arranged such , that when a transmitting / receiving device is directed to the transponder, energy is first added to the chip 5 via ferrite rod 3, whereby it is energized and then emits a signal containing typical properties of the transponder in question. According to the invention, the glass housing 2 of the transponder is provided with a plastic cover 6, part of a heat shrink tubing. As it turns out, the ends 7 of the transponder are not covered by this sleeve. This is to prevent sharp edges from being created, so that the transponder does not adhere optimally to the surrounding tissue. The free ends of the ends 7 result in a chamfered boundary of the heat-shrinkable sleeve 6 and thus a smooth contour of the transponder. Number 8 denotes a silicone-based gel, which serves as a filling for the housing. Naturally, any gel material can be used for this, which has vibration-damping effect as well as good adhesive properties.

Obviously, both the glass housing 2 and heat shrink tubing 6 are selected from biocompatible material. The transponder described above is manufactured by first manufacturing a glass transponder in which the electronic components are mounted in the usual manner. Then, a sized piece of heat shrink tubing 6 with an internal diameter greater than the external diameter of the housing 2 is placed around it and, by some heating, it is tightly crimped onto the transponder. The external surface of the heat shrink tubing is rougher than the external surface of the glass housing 2, so that "wandering" can be prevented during insertion into a living creature, for example. It is also possible to apply a disinfectant ointment (such as "Betadine") on the outside of the heat-shrink tubing 6 before insertion. Due to its somewhat rough surface, this ointment will adhere well to it and prevent infection in the interior of the living being caused by contamination introduced by the transponder or other causes of infection in the body. If for any reason glass breakage should occur, which is very unlikely due to the high compressive strength of glass, the presence of shrinking housing 6 will prevent glass splinters from detaching from the transponder 1. In the event of breakage, only a shortened service life of the electronic components within the housing created by the penetration of body fluids, but it will at all times remain possible to find and remove transponder 1 at the defined location within the body.

It should be understood that the ratio between the wall thickness of the housing 2 and the shrink sleeve 6 in the drawing is not drawn to scale. All sorts of possible ratios are possible, but in view of the functions of the shrink housing 6, it can have a relatively small thickness compared to the thickness of the housing 2. The following are non-limiting examples of the material of the heat shrinkable sleeve:

Kynar and Thermofit are both marketed by Raychem under these brand names.

As indicated above, the transponder shown here can be used not only in living things, but also in other applications where identification of similar objects is desired. The application of a flexible cover in combination with a glass housing will in particular take place where only a glass housing does not suffice and only a plastic housing does not suffice either. An example of this is laundries.

Claims (7)

Transponder, comprising a closed glass housing with electrical components incorporated therein, characterized in that a flexible cover is arranged around the glass housing. The transponder according to claim 1, wherein the cover comprises a sleeve. Transponder according to one of the preceding claims, wherein the cover consists of plastic material. Transponder according to any of the preceding claims, wherein the cover consists of shrinkable material. Transponder according to one of the preceding claims, in which the cover is arranged such that at least one end of the glass housing remains at least partially exposed. The transponder according to claim 5, wherein the boundary of the cover is chamfered. Transponder according to any of the preceding claims, wherein the housing is filled with a silicone-based gel.