JP2002150248A - Data carrier device with impact sensor - Google Patents

Abstract

(57) [Problem] To provide a data carrier device provided with a resonance circuit, having an antenna coil for communicating with an external device, equipped with an impact sensor for disconnecting by applying a predetermined or more impact, Accordingly, a data carrier device capable of detecting the presence or absence of an impact is provided. Furthermore, when the data carrier device is attached to luggage and the luggage or the like is sent by Takkyubin (registered trademark) or the like, it is possible to provide a system that can check and guarantee how to handle the luggage. SOLUTION: This data carrier device is provided with a resonance circuit having an antenna coil for communicating with an external device, and is connected to a wire of the antenna coil by connecting a shock sensor which is disconnected by giving a predetermined impact or more. If the shock sensor breaks due to an impact,
The inductance and / or the capacitance of the wiring of the antenna coil are changed, thereby changing the resonance frequency.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data carrier device having an antenna coil for communicating with an external device and having a resonance circuit, and more particularly to a data carrier device having a shock sensor.

[0002]

2. Description of the Related Art As IC cards have been gradually spread from the aspect of confidentiality of information, in recent years, non-contact type IC cards which exchange information without contacting a read / write device (reader / writer) have been proposed. I have. Above all, a method of exchanging signals with an external read / write device (reader / writer), or exchanging signals and supplying power by electromagnetic waves is generally used. On the other hand, in recent years, various non-contact IC tags in the form of a sheet or a tag, in which an IC carrying data is connected to an antenna coil, have been proposed and applied to products and packaging boxes to prevent shoplifting, distribution systems, and the like. It is being used. In such a non-contact type data carrier such as a non-contact type IC card and an IC tag, signal exchange with the outside, or signal exchange with the outside and power supply are performed by electromagnetic waves. , From the viewpoint of productivity. In some cases, in order to achieve a sufficient number of turns and obtain a sufficient inductance in an area having a limited size, a method of forming a coil wiring in two layers has been adopted.
The resonance frequency f0 of the coil is generally represented as follows, where L is the inductance of the coil and C is the capacitance. f0 = 1 / (2π (LC) ^1/2 ) That is, to lower the resonance frequency f0, it is necessary to increase the inductance L and to increase the number of turns of the coil.

[0003] On the other hand, in the past, when luggage and the like were sent by courier service and the like and the luggage was damaged, it was not known where the luggage was damaged. That is, it was not possible to distinguish whether it was damaged from the beginning or during transportation. For this reason, a system for checking and guaranteeing how to handle the luggage has been required.

[0004]

As described above, when a non-contact type data carrier such as a non-contact type IC card and an IC tag is being used, if the luggage or the like is sent by courier service, the handling of the luggage should be changed. A system that can be checked and guaranteed was required. The present invention corresponds to this, and more specifically, a data carrier device provided with a resonance circuit having an antenna coil for communicating with an external device, wherein the data carrier device is disconnected by applying a predetermined or more impact. It is an object of the present invention to provide a data carrier device equipped with an impact sensor and capable of detecting the presence or absence of an impact. Furthermore, this data carrier device is attached to luggage,
When sending luggage or the like by Takkyubin or the like, it is intended to provide a system capable of checking and guaranteeing how to handle the luggage.

[0005]

A data carrier device with a shock sensor according to the present invention is a data carrier device provided with a resonance circuit having an antenna coil for communicating with an external device, and gives a predetermined or more shock. The shock sensing sensor that is disconnected by being connected to the wiring of the antenna coil is provided. When the shock sensing sensor is disconnected by an impact, the inductance and / or the capacitance of the wiring of the antenna coil are changed, Thereby, the resonance frequency is changed. In the above, the shock sensor is connected in series to the wiring of the antenna coil, the wiring is in a DC conduction state, and a predetermined capacitance Cv is arranged in parallel with the shock sensor to form an antenna. When the shock sensor is disconnected due to an impact, the wiring of the antenna coil is connected in series via the capacitance Cv to change the resonance frequency. It is characterized by being. and again,
In the above, a data carrier chip and / or a capacitance chip having a predetermined resonance capacitance is connected to an antenna coil to form a resonance circuit, and the data carrier chip and / or the capacitance chip and the shock sensor Are connected to the innermost wiring of the antenna coil and are arranged in the inner region of the antenna coil. Further, in the above, the capacitance component Cv is laminated using a capacitance chip or a planar conductor layer provided by being connected to a coil wiring layer forming an antenna coil, and laminated on this via a dielectric layer. The capacitor is formed using a capacitor formed by a planar conductor layer having a flat shape. Further, in the above, the shock sensor is characterized by being manufactured by micro-machine technology, the shock sensor is:
The two beam portions that also serve as wiring, the weight portion that electrically and mechanically connects the two beam portions, and the insulating holding / fixing portion are provided. The weight portion is supported in a suspended state, and the two beam portions are fixed and held by a holding / fixing portion. Each of the two beam portions is electrically connected to another end of the wiring of the antenna coil. To connect the wiring in a DC conduction state, wherein the beam portion is broken by a predetermined impact or more, and the wire portion between the two beam portions is disconnected. . In the above, the data carrier device is a non-contact IC tag or a non-contact IC card.

[0006]

The data carrier device with an impact sensor according to the present invention, having the above-described structure, is a data carrier device having a resonance circuit having an antenna coil for communicating with an external device. The present invention makes it possible to provide a data carrier device capable of sensing an impact when the above impact is applied. Thereby, when the data carrier device with the impact sensor is attached to a package, a product, or the like, and when the package, product, or the like is moved or delivered, it is possible to confirm whether or not the package, the product, or the like has a predetermined impact or more. It is intended to provide a system that can check and guarantee how to handle luggage, products, and the like. Specifically, a data carrier device provided with a resonance circuit having an antenna coil for communicating with an external device, wherein a shock sensor that is disconnected by applying a shock equal to or more than a predetermined amount is connected to the wiring of the antenna coil. More specifically, when the shock sensor is disconnected due to an impact, the inductance and / or the capacitance of the wiring of the antenna coil are changed, thereby changing the resonance frequency. In
The shock sensor is connected in series to the antenna coil wiring, the wiring is in a DC conduction state, and a predetermined capacitance Cv is connected in parallel to the shock sensor and connected in series to the antenna coil wiring. When the shock sensor is disconnected due to an impact, the wiring of the antenna coil is connected in series via the capacitance Cv to change the resonance frequency. This has been achieved. That is, when the mounted shock sensor is subjected to a shock equal to or more than a predetermined amount, the wire is disconnected, so that the capacitance and / or inductance of the resonance circuit is changed to change the resonance frequency, and as a result, communication is performed. This is to shorten the communication distance with the external device.

[0007] As the impact sensing sensor, a minute sensor manufactured by micromachine technology is preferable from a practical point of view. As the structure of the impact sensing sensor, for example, the impact sensing sensor includes two beam portions serving also as wiring, a weight portion electrically and mechanically connecting the two beam portions, and an insulating holding and fixing. The weight part is supported in a suspended state by two beam parts also serving as wiring, and the two beam parts are fixed and held by the holding and fixing part. The two beam parts are Each is electrically connected to another end of the wiring of the antenna coil, and the wiring is connected in a DC conduction state. The beam portion is destroyed by a predetermined impact or more, and the two beam portions are damaged. There is one that breaks the gap. Further, as the data carrier device, a non-contact IC tag or a non-contact IC
Applicable and valid for cards.

The capacitance component Cv is defined by a planar conductor layer provided on a coil wiring layer forming an antenna coil, and a planar conductor layer laminated on the planar conductor layer via a dielectric layer. In the case of forming using the part, the mounted shock sensing sensor is given a shock equal to or more than a predetermined value, and even after disconnection, by contacting the planar conductor layers sandwiching the dielectric layer, The continuity is easily established, so that
A circuit equivalent to the resonance circuit before disconnection is formed, and can be easily recycled as a data carrier device.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a data carrier device with an impact sensor according to the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram of a first example of an embodiment of a data carrier device with an impact sensor according to the present invention, and FIG. 2 is a diagram of a second example of an embodiment of a data carrier device with an impact sensor of the present invention. FIG. 3 is a schematic view of a third embodiment of a data carrier device with a shock sensor according to the present invention, and FIG. 4 is a schematic diagram of a third embodiment of the data carrier device with a shock sensor according to the present invention. FIG. 5 is a schematic diagram of an example of FIG.
FIG. 5A shows an example of an impact sensor, and FIG.
(B) is a cross-sectional view taken along line D1-D2. In FIGS. 1 to 4, a protective layer is not shown for simplicity, but is provided on one or both sides so as to cover each part. 1 to 5, reference numerals 101 to 104 denote a data carrier device (with an impact sensor), 110 denotes an insulating sheet, 120 denotes an antenna coil, 121, 122, and 1
23 and 125 are wirings, 130 is an impact sensor, 131
Beam portion, 131a beam fastening portion, 132 weight portion, 1
32a and 132b are parts of the weight, 133 is a holding and fixing part, 135 is a supporting part, 140 is a data carrier chip, 150 is a capacity chip, 160 is a capacity part, 161, 1
62 is a planar conductor layer, and 165 is a connection relay terminal.
A1 to A8 are connection relay terminals (also simply referred to as relay terminals).

First, a first example of an embodiment of a data carrier device with an impact sensor according to the present invention will be described with reference to FIG. A first example is a data carrier device 10 for an IC tag provided with a resonance circuit having an antenna coil 120 for communicating with an external device (a reader / writer or the like).
1, an impact sensor 130 that is disconnected by applying a predetermined impact or more is connected in series to the innermost wiring 121 of the antenna coil 120, the wiring 121 is in a DC conduction state, and has a predetermined capacity. Capacitive chip 150
Are provided in parallel with the shock sensor 130 and connected in series to the wiring 121 of the antenna coil 120. Each part is provided on one surface of the insulating sheet 110. The data carrier chip 140 is connected in series to the wiring 121, and the resonance circuit is formed by the antenna coil 120, the shock sensing sensor connection wiring 122, and the capacitance C0 of the data carrier chip 140. I have. The data carrier chip 140 and the shock sensor 130 are respectively connected to the innermost wiring 1 of the antenna coil.
21 and is disposed in an area inside the antenna coil 120. Note that the relay terminals A1 and A2 are connected by a wiring 125 on the surface of the insulating sheet 110 opposite to the antenna coil 120. The connection between the front and back of the insulating sheet 110 at the positions of the relay terminals A1 and A2 is a caulking connection in which the insulating layer is crushed between the conductor layers on the front and back.
Each part is provided on the insulating sheet 110 and is covered with a protective layer (not shown).

In the case of the first example, when the shock sensor 130 is disconnected due to a predetermined impact or more, the wiring 121 of the antenna coil 120 is connected in series via the capacitance Cv of the capacitance chip 150, and the resonance frequency is changed. As a result, the communication distance with the external device to be communicated becomes shorter than before disconnection. From this, it can be seen that a shock was applied to the data carrier device 101.

An example of the shock sensor 130 will be described with reference to FIG. Impact sensor 130 shown in FIG.
Is manufactured by micro-machine manufacturing technology.
As shown in FIG. 7, the impact sensor 130 includes two beam portions 131 also serving as wiring, and two beam portions 131 electrically connected to each other.
In addition, the two beam parts 1 each including a weight part 132 for mechanical connection, an insulating holding and fixing part 133, and a supporting part 135 for supporting the insulating holding and fixing part 133, and also serving as wiring.
At 31, the weight 132 is supported in a suspended state.
The beam 131 of the book is fixed and held by the holding and fixing portion 133. The insulating holding and fixing portion 133 is made of Si (silicon), and a part 132b of the weight portion is also made of Si. Beam 131 and part of weight 132 connected to beam 131
The portion where a is formed is made of the same conductive metal. Specifically, a single layer or a stacked layer of a diffusion layer formed by implanting ions into Si is formed. Pyrex (registered trademark) glass or the like is used as the support portion 135, but is not limited thereto. In the case of this example, each end of the wiring 121 is connected to another beam fastening portion 131a. Thus, the beam 13
When 1 is not disconnected, each end of the wiring 121
Although the beam portion 131 and the weight portion 132a are electrically connected to each other, the beam portion is broken when a predetermined impact or more is applied. Thereby, the two beam portions 13
1 is disconnected.

In the data carrier chip 140, an input signal from the wiring 121 of the antenna coil 120 is accessed to a memory via a receiving circuit and a control unit, and a signal from the memory is transmitted to a transmission circuit via the control unit. To the external circuit via the antenna coil 120. The memory stores various information necessary for the data carrier device. The non-contact type data carrier device 111 for an IC tag of the present example forms a resonance circuit by the antenna coil 120 and the capacitance C0 of the data carrier chip 140, and transmits and receives a radio wave of a constant frequency. In general, in the 13.56 MHz frequency band, the communication distance is about 20 cm, but the actual communication distance varies greatly depending on the antenna area and the output power of the reader / writer.
Normally, a 50 mm × 50 mm size IC tag (data carrier device) can provide a communication distance of 50 to 60 cm.

The insulating sheet 110 is selected according to the purpose of use of the data carrier device, but a hard vinyl chloride sheet or polyester sheet (PET), a polyimide or glass epoxy resin sheet, or the like is used. The thickness of the insulating sheet 110 is about 20 to 150 μm, and preferably about 25 to 100 μm. Usually, a material in which aluminum, copper foil, or iron foil having a thickness of 5 to 50 μm is laminated on one surface of the base material is used, and the aluminum, copper foil, or the like is etched to form the antenna coil 120 and the wiring.

A similar substrate may be used for a protective sheet (not shown), but an inexpensive material such as paper may be used. A data carrier device for an IC tag is generally used in a production or distribution process, and a decorative element is not so required except for being carried by a person such as a commuter pass. In the case other than the special purpose, a small data carrier semiconductor chip is desired.
It is manufactured in a unit size within 0 mm x 50 mm.

Next, a second embodiment of the data carrier device with an impact sensor according to the present invention will be described with reference to FIG. Similarly to the first example, the second example is a data carrier device 101 for an IC tag provided with a resonance circuit having an antenna coil 120 for communicating with an external device (a reader / writer or the like). Is an example in which the innermost wiring 121 of the antenna coil 120 is connected to the impact sensor 1
3 and short-circuited and connected. The data carrier chip 140 is connected in series to the wiring 121, and the resonance circuit includes the antenna coil 120, the shock sensing sensor connection wiring 122, and the capacitance C0 of the data carrier chip 140.
And formed. The data carrier chip 140 and the shock sensor 130 are connected to the innermost wiring 121 of the antenna coil, respectively.
0. Note that the relay terminals A3 and A
4 is connected by wiring 125 on the surface of the insulating sheet 110 opposite to the antenna coil 120. The connection between the front and back of the insulating sheet 110 at the positions of the relay terminals A3 and A4 is a caulking connection that connects the conductor layers on the front and back by crushing the insulating layer. In the case of the second example, when the shock sensing sensor 130 is disconnected due to a predetermined or more impact, the length of the wiring portion of the antenna coil 120 changes, the inductance changes, and the resonance frequency changes. as a result,
The communication distance with the external device to communicate with becomes shorter than before disconnection. From this, it can be seen that a shock was applied to the data carrier device 111. Each part is the same as in the first example, and the description is omitted here.

Next, a third embodiment of the data carrier device with an impact sensor according to the present invention will be described with reference to FIG. A third example is a data carrier device 10 for an IC tag provided with a resonance circuit having an antenna coil 120 for communicating with an external device (such as a reader / writer).
1, the antenna coil 120 and a planar conductive layer 161 connected to the antenna coil 120 are provided on one surface of the insulating sheet 110, and the planar surface is provided on the other surface via the insulating sheet 110 which is a dielectric layer. A conductor layer (not shown) is provided facing the conductor layer 161 of FIG. Then, similarly to the first example, the shock sensor 130 that is disconnected by giving a shock equal to or more than a predetermined amount is connected to the innermost wiring 121 of the antenna coil 120.
Are connected in series to each other, the wiring 121 is in a DC conduction state, and a capacitance section 160 having a predetermined capacity is connected in parallel with the shock sensing sensor 130 so that the wiring 1 of the antenna coil 120 is connected.
21 connected in series. The relay terminals A5 and A6 are connected to the antenna coil 1 of the insulating sheet 110.
20 are connected by a wiring 125 on the surface on the opposite side. Insulating sheet 11 at relay terminals A5 and A6
0 The connection on the front and back is a caulking connection in which the insulating layer is crushed between the conductor layers on the front and back. Then, similarly to the first example, the data carrier chip 140 is connected in series to the wiring 121, and the resonance circuit is formed by the antenna coil 120 and the capacitance C0 of the data carrier chip 140. Also, as in the first example, the data carrier chip 1
40 and the impact sensor 130 are connected to the innermost wiring 121 of the antenna coil, respectively, and are arranged in an area inside the antenna coil 120. The third example has a configuration in which the capacitance chip 150 is replaced by a capacitance section 160 in the first example, and the description of the operation and the like is omitted here. In the case of this example, the mounted shock sensor is subjected to a predetermined shock or more, and after the disconnection, the planar conductor layers sandwiching the dielectric layer are brought into contact with each other, so that conduction can be easily taken. Thereby, a circuit equivalent to the resonance circuit before the disconnection is formed again, and can be recycled as a data carrier device. The conductor layer 161 and the connection relay terminal 165 of the capacitance section 160 are connected to the antenna coil 120 and the wiring 1
Similarly to 25, it can be formed by etching aluminum or copper foil. The other components are the same as in the first example, and description thereof is omitted.

Next, a fourth embodiment of the data carrier device with an impact sensor according to the present invention will be described with reference to FIG. The fourth example has basically the same structure as the third example. However, in the third example, the impact sensor 1
The position of the capacitor 30 and the position of the capacitor 160 are changed. Also in this example, a planar conductor layer (not shown) facing the planar conductor layer 162 via the insulating sheet 110 is provided, and the capacitance section 160 is formed in that portion.
Each part is the same as in the third example, and a description thereof will be omitted. The relay terminals A7 and A8, and A7 and the conductor layer 16
2 is connected by wiring 125 on the surface of the insulating sheet 110 opposite to the antenna coil 120. The connection between the front and back of the insulating sheet 110 at the positions of the relay terminals A7 and A8 is a caulking connection in which the insulating layer is crushed between the conductor layers on the front and back.

[0019]

As described above, the present invention relates to a data carrier device provided with a resonance circuit having an antenna coil for communicating with an external device. A sensor is mounted, thereby making it possible to provide a data carrier device capable of detecting the presence or absence of an impact. Thereby, when the data carrier device with the impact sensor is attached to a package, a product, or the like, and when the package, product, or the like is moved or delivered, it is possible to confirm whether or not the package, the product, or the like has a predetermined impact or more. It is possible to provide a system that can check and guarantee how to handle luggage and products.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of a first example of an embodiment of a data carrier device with an impact sensor according to the present invention;

FIG. 2 is a schematic view of a second example of the embodiment of the data carrier device with an impact sensor according to the present invention.

FIG. 3 is a schematic diagram of a third example of the embodiment of the data carrier device with an impact sensor according to the present invention;

FIG. 4 is a schematic diagram of a fourth example of the embodiment of the data carrier device with the impact sensor according to the present invention;

FIG. 5A is a diagram showing an example of an impact sensor, and FIG. 5B is a cross-sectional view taken along line D1-D2.

[Explanation of symbols]

101 to 104 (with impact sensor) Data carrier device 110 Insulating sheet 120 Antenna coil 121, 122, 123, 125 Wiring 130 Impact sensor 131 Beam 131a Beam fastening 132 Weight 132a, 132b Part of weight 133 Holding and fixing part 135 Support part 140 Data carrier chip 150 Capacitance chip 160 Capacitance part 161, 162 Planar conductor layer 165 Connection relay terminal A1 to A8 Connection relay terminal (also simply referred to as relay terminal)

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G06K 19/00 N

Claims (7)

[Claims] 1. A data carrier device provided with a resonance circuit having an antenna coil for communicating with an external device, wherein a shock sensing sensor that is disconnected by applying a predetermined impact or more is connected to a wire of the antenna coil. When the shock sensor breaks due to an impact,
A data carrier device with an impact sensor, wherein the resonance frequency is changed by changing the inductance and / or the capacitance of the wiring of the antenna coil. 2. The method according to claim 1, wherein the shock sensor comprises:
It is connected in series to the wiring of the antenna coil, the wiring is in a DC conduction state, and a predetermined capacitance Cv is provided in parallel with the shock sensor and connected in series to the wiring of the antenna coil. Wherein when the shock sensor is disconnected by an impact, the wiring of the antenna coil is connected in series via the capacitance Cv to change the resonance frequency. With data carrier device. 3. The data carrier chip according to claim 1, wherein a data carrier chip and / or a capacitance chip having a predetermined resonance capacitance is connected to an antenna coil to form a resonance circuit. And / or the capacitance chip and the shock sensor are connected to the innermost wiring of the antenna coil, respectively, and are arranged in a region inside the antenna coil. 4. The capacitor according to claim 2, wherein
Is formed by using a planar conductor layer provided using a capacitor chip or connected to a coil wiring layer forming an antenna coil, and a planar conductor layer laminated thereon via a dielectric layer. A data carrier device with an impact sensor, wherein the data carrier device is formed by using a capacitance part to be formed. 5. The data carrier device with a shock sensor according to claim 1, wherein the shock sensor is manufactured by a micromachine technology. 6. The shock sensor according to claim 5, wherein:
The two beam portions that also serve as wiring, the weight portion that electrically and mechanically connects the two beam portions, and the insulating holding / fixing portion are provided. The weight portion is supported in a suspended state, and the two beam portions are fixed and held by a holding / fixing portion. Each of the two beam portions is electrically connected to another end of the wiring of the antenna coil. And the wire is connected in a DC conduction state, and the beam portion is destroyed by a predetermined impact or more, thereby breaking the wire between the two beam portions. With data carrier device. 7. The data carrier device according to claim 1, wherein the data carrier device is a non-contact IC tag or a non-contact IC card.