JP2007329782A - Intra-case information management apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make it possible to simply read/write information from/in a data storage means by using a present wall surface as it is without requiring the formation of a new through hole or the like even when the data storage means is covered with a metallic shield such as a case. <P>SOLUTION: Ultrasonic wave transmitting/receiving means 5, 11 are attached to respective inner and outer wall surfaces of a case and electromagnetic wave/ultrasonic wave conversion means 6, 12 are arranged between respective ultrasonic wave transmitting/receiving means 5, 11 on the inside and outside of the case and electromagnetic wave transmitting/receiving means 4, 21 of a data management means 23 and a data storage means 3 to execute communication between the inside and outside of the case by ultrasonic waves. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an in-case information management apparatus, and in particular, when an RF tag or ID tag as a data storage means used for article management, inventory management, etc. is housed together with an article to be managed in a metal case. The present invention relates to an in-case information management apparatus that reads and writes information related to articles from outside the case.

  The frequency of the carrier used for the RF tag or ID tag (hereinafter referred to as RF tag) is currently permitted by laws and regulations such as less than 135 kHz, 13.56 MHz, UHF band, 2.45 GHz, etc. There are roughly two types of writing methods using electromagnetic induction electromagnetic waves and microwave electromagnetic waves.

  In the microwave system, information is exchanged by microwaves such as 2.45 GHz. Transmission information from the reader / writer is modulated and emitted as microwaves from the antenna. The RF tag receives this microwave and demodulates it to obtain information.

  Transmission of information from the RF tag is based on a reflected wave method in which a microwave emitted from the reader / writer antenna is received, modulated by return information including transmission information, and then emitted again to the reader / writer antenna. . The microwave type is resistant to external noise and can realize a communication distance of several meters.

  In the electromagnetic induction method, an induction electromagnetic field is generated in the vicinity of the antenna by applying a carrier frequency to the coiled antenna, and when the RF tag enters the induction electromagnetic field, an electromagnetic wave is applied to the coiled antenna of the RF tag. Current flows by induction. Electric power is supplied to the RF tag by the induced electromotive force to operate the RF tag. The maximum communication distance is about 1 (m), and a relatively wide communication area can be secured.

  Many types of RF tags and reader / writers are commercially available, and have been used conventionally.

  However, when both systems are in contact with a metal surface or have a metal in the vicinity, normal data communication by electromagnetic waves cannot be performed.

  In the microwave system, radio waves are reflected on the surface of a metal surface, and the signal is often attenuated by interference with the reflected waves. When such attenuation occurs, the RF tag information cannot be read.

  In the electromagnetic induction method, an eddy current is generated on the surface of the metal surface, a magnetic field in the direction opposite to the original direction of the magnetic field is generated, and the cancellation signals are greatly attenuated.

  In particular, when the RF tag is housed in a metal case (including the case where some metal is used) and is shielded by a metal plate or the like, communication is possible for both electromagnetic induction and microwave systems. Extremely difficult and practically unusable.

  There is a conventional technique described in Patent Document 1 below, in which data communication between the inside and outside of the case is performed by electromagnetic waves even in the case where the periphery is covered with metal.

  In this prior art, an antenna is provided on both the inner and outer sides of a case in which the inside is a metal case and a data storage means (ID tag) for the management object is housed inside the case. , And data communication using an electromagnetic wave from the data management means to the external antenna, the electromagnetic wave is transmitted from the internal antenna to the ID tag, so that a reply can be performed. Data communication is performed with data management means outside the case.

JP-A-8-48337

  However, the antennas that relay electromagnetic waves are connected to each other by forming a through hole in the case body and insulating with a non-metallic spacer. A through hole must be formed in the case body, and when it is necessary to maintain airtightness, it is necessary to fill with a sealing material or the like.

  The management target to which the RF tag is attached does not necessarily exist as a single management target in an empty space. In many cases, the management target is often covered with a cover or stored in various cases. Often, the cover or case is made of metal, and high airtightness in the case is sought for the purpose of maintaining humidity, etc., and there is often no perforation allowed.

  Therefore, even if the object of the present invention is covered with a metal shield such as a case, it is not necessary to newly form a through hole or the like, and the data storage means can be simply used in the state where the current wall surface is used as it is. It is an object to provide an in-case information management apparatus that can read and write information.

  A feature of the device of the present invention that achieves the above object is that ultrasonic transmission / reception means are provided on each of the inner and outer wall surfaces of the case, and electromagnetic waves in the ultrasonic transmission / reception means, data management means, and data storage means inside and outside the case An electromagnetic wave and ultrasonic wave conversion means are provided between the transmission / reception means, and the inside and outside of the case communicate with ultrasonic waves.

  According to the present invention, information can be communicated without providing a hole in the case, the airtightness of the case can be secured, and the quality of the management object can be maintained.

  Hereinafter, embodiments shown in the drawings will be described.

  In FIG. 1, reference numeral 1 denotes a metal case that stores an article 2 that is a management object, and 3 is an RF tag (data storage means that stores information about the management object) that stores information about the article 2. It is attached.

  As shown in FIG. 2, the RF tag 3 is of the microwave type, has an antenna 3a on the surface portion, and includes an amplifier, a demodulator, a modulator, a controller, a carrier wave oscillator, and the like. The controller includes a storage unit that stores unique information derived from the item 2 (information related to the item, hereinafter abbreviated as transmission information), a storage unit that stores a program for transmitting and receiving information, and the like.

  4 is a reader / writer which is a means for transmitting and receiving electromagnetic waves in the RF tag 3 provided on the inner wall of the case 1. As shown in FIG. 3, an antenna 4a is provided on the surface, and an amplifier, demodulator, modulator, controller, It has a carrier wave oscillator.

The controller includes a storage unit that stores information (transmission information) related to the article 2 obtained (received) by communicating with the RF tag 3, a storage unit that stores a program for transmitting and receiving information, and the like. The content (communication information) that the reader / writer 4 should communicate with the RF tag 3 is sent from the host device 23 side described later.

The RF tag 3 and the reader / writer 4 are of the microwave type that has been used in the past.
A 2.45 GHz carrier wave is used, and transmission / reception is performed via the antennas 3a and 4a.

When transmitting from the reader / writer 4 side to the RF tag 3 side, when the control unit of the reader / writer 4 sends the communication information stored in the storage unit to the modulator, the modulator obtains 2.45 from the oscillator.
A GHz carrier wave is modulated with communication information and emitted as a microwave from the antenna 4a.

  The RF tag 3 receives and demodulates this microwave to obtain communication information. The communication information is stored in the storage unit of the control unit and decoded. The communication information from the reader / writer 4 side includes a reply request, decodes the communication information according to the request, prepares an answer (including transmission information), stores it in the storage unit of the control unit, and reads the reader / writer The response information to the 4th side.

When a reply is sent from the RF tag 3 side to the reader / writer 4 side based on a reply request from the reader / writer 4, when the control unit inputs reply information to the modulator, the 2.45 input from the oscillator here.
A GHz carrier wave is modulated with reply information, and the carrier wave modulated by the modulation unit is emitted from the antenna 3a, which is caught by the antenna 4a on the reader / writer 4 side, and enters the demodulator on the receiving side. Reply information obtained by removing the carrier wave in the demodulator is temporarily stored in the control unit.

  Since the microwave method has a high frequency and the antenna 3a on the RF tag 3 side can be downsized, the entire RF tag 3 can be reduced in size.

  In order to enable communication between the inside and outside of the case 1, ultrasonic transducers (hereinafter abbreviated as transducers) 5 and 11 are provided as ultrasonic wave transmitting / receiving means on both the inner and outer wall surfaces of the case 1.

The transducers 5 and 11 are electrical and mechanical energy converters using the piezoelectric effect. When an electrical signal of a certain frequency is given, an ultrasonic wave (vibration) of that frequency is emitted and a vibration (sound) of a certain frequency is caught. An electric signal having that frequency can be obtained, and both vibration generation and vibration detection can be performed. The ultrasonic wave used here is several tens KHz, that is, the frequency of the carrier wave transmitted and received via the transducers 5 and 11 is several tens KHz.

  As shown in FIG. 4, the transducers 5 and 11 are both placed in contact with the wall surface of the case 1 and faced across the case 1. If an acoustic coupling material (echo jelly) Z made of a polymer, a surfactant or the like is applied to the contact surface between each transducer 5, 11 and the wall surface of the case 1 in order to eliminate an air layer, ultrasonic waves are applied. Attenuation can be kept low.

  An analog controller 6 that is a means for converting electromagnetic waves and ultrasonic waves, which has the configuration and operation described later, so that the electromagnetic waves communicated between the RF tag 3 and the reader / writer 4 can be converted into ultrasonic waves by the transducer 5. It is provided.

  Further, the transducer 11 outside the case 1 is also provided with an analog controller 12 which is a means for converting electromagnetic waves and ultrasonic waves, which has the configuration and operation described below so that the electromagnetic waves can be converted into ultrasonic waves.

  The controller 12 can communicate with the repeater 21 wirelessly by electromagnetic waves, and the repeater 21 is connected to a host machine 23 which is a data management means via a network 22 using a LAN cable or the like. In 23, the information is managed in a comprehensive manner by creating a database.

  Reference numeral 24 denotes another repeater connected to the network 22.

  Since the case 1 arbitrarily approaches the repeater 21, the repeater 21 always transmits communication information including a reply request for a response to the unspecified case 1 on a carrier wave.

  Hereinafter, the configuration and operation of the controllers 6 and 12 will be described.

  In FIG. 5, the controller 6 corresponds to the host device 23 that is directly connected to the conventional reader / writer 4 when the case 1 is not provided. Therefore, the input device and the output device are directly connected to the reader / writer 4. The same input device and output device in the conventional host machine 23 to be connected are used.

  Further, since the controller 12 should be the RF tag 3 that communicates with the relay device 21 equivalent to the conventional reader / writer 4 with respect to the host device 23 when the case 1 is not present, its input device and output device are The antenna in the conventional RF tag 3 is used.

  Further, since the repeater 21 corresponds to the conventional reader / writer 4 with respect to the host machine 23 without the case 1, its input device and output device use an antenna in the reader / writer 4. Yes.

  When an arbitrary case 1 approaches the repeater 21, when the input device (antenna) of the controller 12 receives a carrier wave including communication information transmitted from the repeater 21, the input system is activated and a filter (in FIG. The same applies hereinafter), the carrier wave is removed, the carrier wave (about several tens of KHz) is modulated with the communication information by the modulation circuit via the ALC amplifier, and the communication information placed on the carrier wave is sent to the filter, transmission amplifier, and switching circuit. Then, it is sent to the transducer 11.

  When the transducer 11 emits an ultrasonic wave as a mechanical signal in accordance with the communication information having the form of an electrical signal, the transducer 5 in the case 1 receives and converts it into an electrical signal and sends it to the controller 6.

  In the controller 6, the output system is activated and sent to the demodulation circuit through the switching circuit, the reception amplifier, the filter, and the ALC amplifier. In the demodulation circuit, the carrier wave and the communication information are separated by modulation to obtain communication information, and the communication information is sent from the output device to the reader / writer 4 shown in FIG.

  The reader / writer 4 puts the communication information on the 2.45 GHz carrier wave by the above operation and sends the communication information to the RF tag 3, and the RF tag 3 separates the communication information from the carrier wave by the above operation and converts it into the communication information from the repeater 21. Based on this, the reply information including the information derived from the article 2 (information related to the article 2) stored in the storage unit in the control unit is created, and a reply (response) is issued by the above-described operation.

Then, the mode opposite to that described above is entered, and the input device of the controller 6 receives the reply via the reader / writer 4 and the input system operates in the same manner as the input system of the controller 12, and the filter The carrier wave is removed, the ALC amplifier, the modulation circuit, the filter, the transmission amplifier, the switching circuit, the transducer 5 in the form of an electric signal in the modulation circuit through the switching circuit, the carrier wave (several 10
Reply information posted on KHz) is sent.

  The transducer 5 is converted into a mechanical signal, and the external transducer 11 returns the electrical signal to the controller 12 through the wall of the case 1 and sends it to the controller 12.

  In the controller 12, the output system is operated, the carrier wave is removed by the filter through the switching circuit and the reception amplifier, and the return information is sent to the modulation circuit through the ALC amplifier. The modulation circuit modulates the carrier wave with the reply information, puts the reply information on the carrier wave, returns the reply information to the repeater 21 from the output device through the filter and amplifier, and returns the reply information as a response.

  Accordingly, even if the article 2 is covered with the case 1 including a metal shield, the case 1 can be used from the outside of the case 1 in a state where the case 1 is used as it is without newly forming a through hole or the like. In addition to being able to read and write information on the article 2 in the RF tag 3 in 1, the case 1 does not need to be provided with a through hole, so that the airtightness of the case 1 can be maintained.

  The relay machine 13 extracts the transmission information from the reply information obtained from the case 1 through the network 22 to the host machine 23 and other relay machines 24, and distributes the transmission information.

  The bidirectional transmission / reception in the form of a reply to transmission has been described above. However, the controllers 6 and 12 function well even in the case of unidirectional transmission / reception.

  In the examples of the controllers 6 and 12, the analog signals are input / output.

The RF tag 3 and the reader / writer 4 may be coupled by an electromagnetic induction method.
In the case of the electromagnetic induction method, the RF tag 3 is placed in an induction electromagnetic field created by the antenna 4 a of the reader / writer 4, and RF is generated by electromagnetic induction between the antenna 3 a of the RF tag 3 and the antenna 4 a of the reader / writer 4. A current is induced in the antenna 3 a of the tag 3. The RF tag 3 is activated using this current (power energy), and information is communicated with the control unit on the reader / writer 4 side. The antenna 4a of the reader / writer 4 is divided into two types, ie, a transmission antenna and a reception antenna, and a type shared by one antenna.

  In the 13.56 MHz short wave band, the number of turns of the coil in the antenna 3a of the RF tag 3 can be reduced, so that it is easy to realize a thin shape. Widely used for product tags and logistics tags.

Next, another embodiment that does not rely on ultrasonic waves will be described.
In the embodiment shown in FIG. 6, a vibrator (mechanical vibration generating means) 8 is used instead of the transducer 5 shown in FIG. The vibrator 8 includes a solenoid 8a and a knocker 8b that moves in the forward and reverse directions toward the inner wall of the case 1 by the solenoid 8a and strikes the inner wall surface of the case 1. The solenoid 8a is sent from the controller 6 The knocker 8b is moved according to the contents of the incoming transmission information, and the case 1 is vibrated by striking the inner wall surface of the case 1. In the case 1 knocking by the knocker 8b, information related to the article (transmission information) is replaced with the number of knocks within a predetermined time.

  The vibration occurring in the case 1 is received by an acceleration pickup (mechanical vibration detecting means) 14 provided on the outer wall of the case 1 in place of the transducer 11 shown in FIG. Send to.

  The controller 12 counts the number of knocks within a certain period of time, converts it into transmission information, recognizes it, transmits it to the repeater 21 shown in FIG.

  In order to send information from outside the case 1 into the case 1, a vibrator is provided on the outer wall of the case 1, and an acceleration pickup is provided inside the case 1.

  The controllers 6 and 12 receive the vibration generated by the vibrator with the accelerometer that is connected to them, but the same signal as the signal sent from them will be returned. It is removed as a signal, and when a signal different from the signal transmitted from itself is received, it is received and transmission / reception is executed.

  In this way, even if the article is covered with a metal shield, it is not necessary to newly form a through hole or the like, and it is possible to read and write information of the RF tag while using the current case 1 as it is. In addition, since it is not necessary to provide a through hole in the case, the airtightness of the case 1 can be maintained.

It is the schematic of the information management apparatus in a case which shows one Embodiment of this invention. It is a figure which shows the circuit block of RF tag shown in FIG. It is a figure which shows the circuit block of the reader / writer shown in FIG. It is a figure which shows the contact part of the ultrasonic transducer shown in FIG. 1 and a metal plate surface. It is a figure which shows the circuit block of the controller shown in FIG. It is a figure which shows the information communication condition using the mechanical vibration means which is other embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Case, 2 ... Management object (article), 3 ... RF tag (data storage means), 4 ... Electromagnetic wave transmission / reception means (reader / writer), 5, 11 ... Ultrasonic transmission / reception means (transducer), 6, 12 ... Electromagnetic wave and ultrasonic wave conversion means (controller), 21 ... Electromagnetic wave transmission / reception means (relay machine), 23 ... Data management means (host machine).

Claims (2)

Data storage means storing information related to the management object together with the management object is stored in a metal case, and there is data management means outside the case, and reading and writing of the information in the data storage means is performed using electromagnetic waves. In the case information management apparatus to be used from outside the case using,
Ultrasonic wave transmitting / receiving means is provided on each of the inner and outer wall surfaces of the case, and the electromagnetic wave and ultrasonic wave are respectively transmitted between the ultrasonic transmitting / receiving means inside and outside the case, the data management means, and the electromagnetic wave transmitting / receiving means in the data storage means. An in-case information management apparatus characterized in that a conversion means is provided. Data storage means storing information related to the management object together with the management object is stored in a metal case, and there is data management means outside the case, and reading and writing of the information in the data storage means is performed using electromagnetic waves. In the case information management apparatus to be used from outside the case
Mechanical vibration generating means and detecting means are provided on the inner and outer wall surfaces of the case, respectively, and between the mechanical vibration generating means and detecting means inside and outside the case, the data managing means, and the electromagnetic wave transmitting / receiving means in the data storage means. An in-case information management device characterized in that a means for converting electromagnetic waves and mechanical vibrations is provided in the case.

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