BR102014009074A2 - non-destructible mechatronic seal - Google Patents

Abstract

nondestructible mechatronic seal nondestructible electronic sealing system, method and device with sensory detection and digital recording of tampering event for the sealing of containers (1) from the inside. This mechatronic seal consists of a transponder (2), constructed from a RFID - radio frequency identification microchip that communicates by radio frequency through an antenna (4) and is remotely activated by a reader (3). In order to activate the seal, the reader (3) activates the activation controller (6), which permanently changes the binary memory value (7) and simultaneously activates the sealing controller (9), putting the device in a surveillance state. During this surveillance period, a dc power supply (13) powers the sealing controller (9), which acts as a digital switch installed in series with the physical sensor switch (12), whose function is to detect the opening. any means of access to the container (1) or the invasion of its interior space, such that when this act is verified, it immediately reverses its contacts, causing the sealing controller (9) to permanently change the value of binary memory ( 10), thus being digitally configured the violation of sealing.

Description

NON-DESTRUCTIBLE MECHATRONIC LACRE The present invention relates to a non-destructible electronic sealing method and method with sensory detection and digital recording of tampering event. [002] Using RFID - Radio Frequency Identification technology, This seal is a new type of condition sensor designed for the safety and protection of containers with doors, windows or closure lids.

[003} This panel is designed to be applied in situations that need to identify the opening of this container by unauthorized persons or any other violation of its interior space »in a practical» safe and reliable manner. inside the container 'is a physically self-protected sealing system.

[005] After installation and closure of the container access means, the sealing is activated by the exfcmu side by an RFID reader, ie an electronic data read and write instrument, which communicates with the sealing transponder via of radio frequency waves.

Using the same means of remote communication, the seal also eliminates the need for visual verification of its integrity or the corresponding integrity of the sealed container, as the mere physical presence of the RFID reader within the range of the seal verifies the status. of the sealing.

Automatically and permanently, data associated with activation and sealing status are digitally recorded in the memory of the sealing RFID microcbip, the constructive technology of which is recognized as tamper-proof or tamper-proof.

The sealing surveillance sensor that detects the tampering event is compatible with any type of micro-switch or on / off sensors intended for general electro-electronic applications or installations. 1009] Due to its feature of operating quietly »out of sight and without physical resistance to a casual opening of the sealed container» this mechatronic seal is best suited to be fitted together with a conventional external mechanical lock, run for example; locks »padlocks, seals, rivets» dowels »clips» security screws and even mechanical seals.

[OfOJ Since the construction design of the seal is based on a technology that is used to produce a wide range of disposable labels, its manufacturing cost should be very small, making this product very cost-effective.

BACKGROUND OF THE INVENTION

[01 f 3 Theft by fraud in meters of utilities in Brazil is known periods, and this is an alarming finding in all electricity distribution companies in Brazil. Frauds on the meters of these devices are easy because the operating voltage level on the measuring instruments is of low risk to the fraudsters. These deviations constitute a difficult situation to control, because the population concentration of large urban centers, their social complexity and the culture that energy diversion is a minor offense have created this serious scenario of large-scale theft.

[012] Widespread and widely available seals do not provide practical results in reducing meter fraud or facilitating the identification of their occurrence due to the ease of counterfeiting of these seals and the lack of traceability, which does not allow verification. violating events quickly and unambiguously.

[013] Effective fraud detection currently requires constant inspection by dedicated staff. But this procedure requires huge staff and equipment resources to periodically cycle through all measurement points. Therefore there is too long a time lag between the occurrence of fraud and its proper detection. It is precisely in this detail that the security devices are faulty, since their function is not good for the leupferifes but they allow identification when the breach occurs.

[014] In addition to the losses accumulated by the delay in detecting fraud, there is the wear and tear of new collection actions, experts, and court costs 'that many of them do not mitigate with due compensation due to the claim of need' from defendants in return for the essentiality of the service provided by the energy companies. Adding to the fact that the company has its image eroded before society. Therefore, the best way to deal with power outages is to identify them immediately in order to minimize losses.

[015] The various players in this sector are constantly looking for new methods, systems or devices to counteract misuse of electricity by tampering with meters, or simply identifying them more simply and quickly. In this sense, seeking to solve the deficiency of conventional mechanical seals, the development of tracking systems was initiated using the radio frequency identification technology iRPÍP | »as a major advance and new direction in sealing systems for protective enclosures. equipments.

TECHNICAL STATE

[016] Document PI0503404-3 A2, published 06/03/2007, “Ufc LAOKfc fcLfc I RÕNICü PAKA ÜUNJUNIU Uh MEASURING ELECTRICITY SYSTEM”, and document PI0703181-5 A2, published on 28/04/2009, "ELECTRONIC ELECTRIC POWER MEASURING ASSEMBLY *" consists of a padlock-shaped external sealing device with a radio frequency identification system which, when broken, the RFID device is no longer responsive to reading equipment stimulus. This way »it is assumed that a violation event has occurred.

[G17J Authored by the same inventors as this IP »document MU900Q296-2, filed patent application on 15/03/2010» “RADIO FREQUENCY IDENTIFICATION DEVICE (Tag-RFID) INSERTED WITH SAFETY MECHANICAL SAFETY SCREW» INTEGRATED COMPUTER CONTROL AND DECISION-MAKING SYSTEM ', it consists of a single screw-shaped device that mechanically seals the protective case securely by having the secret inside your body' and with an electronic ID placed also on its bottom. The screw is installed with a standard screwdriver and no longer allows opening. When the sealing breach event occurs, both mechanical and electronic systems are disrupted and visually and electronically identified via the RFID data reader when the sealing becomes responsive to the equipment stimulus.

SUMMARY OF THE INVENTION

[018] The nondestructible mechatronic seal, object of this invention, was developed in order to remedy the deficiencies presented by both the conventional mechanical seals and the electronic devices mentioned above, bringing a significant gain of reliability in the sealing of containers, with greater speed. identifying your violation, accompanied by true authentication of this event.

[019] Its fundamental technical concept is not to destroy the RFID electronic component, but to exploit its technological resources and potentialities more advantageously.

[020] Its main constructive advantage is that it has a self-protected installation, ie the seal is physically protected within the container itself to be locked and sealed.

In this way »the following features stand out: [0213 1 - Universality The mechatronic beam can be installed in virtually any type of container made of plastic» glass, wood, metal, masonry or any other structural material and has a lid, door access or inspection window. The installation of the seal can be done without the need for any change in the container design.

[0223 2 - Interoperability The mechatron seal may be installed in conjunction with any conventional physical locking, latching or sealing system such as: locks »padlocks, seals» rivets, bolts, clamps, ü «Segui dtsyd and mechanical seals made plastic or metal.

[023] 3 ~ Self-Protected System The mechatronic seal is physically protected within the container itself to be locked and sealed.

[024j 4 - Cuneti utfãv á Filsificfi © (Anti-Piracy) Wire The impossibility of forgery is guaranteed by the very nature of the technology and manufacturing process of the RFID chips that will be used in the devices. The chips have digital identification protocols in their firmware, forming unique permanent aluminous codes »which are standardized to international standards» such as the EPC-Electronic Product Code standard.

[025] 5 - Long Range Multiple Reading eiiipieydua technology allows multiple seal data to be read and collected simultaneously over long distances by radio frequency communication without the risk of duplication of reading or repulsion. The process of identifying and collecting and storing data is filtered and controlled by the rriidleware software of portable electronic data collection instruments. I026J 6 - Irreconstituibiüdad · Following the violation of the Inaccuracy, any attempt to physically recompose or reconstitute its mechanical or electronic components will be futile, as the event record is digitally and permanently recorded, [0273 7 - Non-Destructive Electronic System O iníay or RPIP tag »as with any other electronic component of the seal, is not destroyed by tampering with the container, remaining fully functional 8 sending data to the collecting instruments. The great advantage of this operating logic is the elimination of false positive records, which mask the certification process of the violating event. False positive records are mainly due to • Device malfunction or technical defect, • Operational failure during RFID tag induction. • operational failure of the electronic chip power supply. • Failure to read or capture data from collector instrument, {02SJ 8 - Irresetability Unable to reset or reprogram the device's electronics after it is activated, this ensures that with tamper sealing this event will be permanently logged on the device. I029J 9 - Minfattirtzaçflo Due to its interoperability characteristic, there is no need for the mechatronic device to offer physical resistance when opening the box, as a reminder of the possible irregularity to be committed. Thus, the possibilities of mini-curing the seal components, including the sensor that detects the violating event, are significantly increased.

Since the constructive design of the seal is based on a technology designed for the large-scale production of disposable electronic labels, its cost of manufacture should be very small, making this product attempt a eu-tenefice relationship. quite favorable. Note that in contrast to previous IP, the construction of this seal uses only one RFID tag.

[031] 11 - Optional Features As a result, your iacre integrated circuit may contain a Real Time Clock (RTC) designed to time-stamp the following events: * RFID Mechatronic Seal Activation Date and Time, • Date and Time RFID Mechatronic Seal Violation.

In this configuration, these records may become important information for behavioral analysis of fraudsters and may also provide more accurate information on evidence supporting any legal claims or technical expertise.

TYPICAL APPLICATION OF THE INVENTION

[2] Figure 2 represents a typical example of application of this invention, with an illustration of the non-destructible mechatronic seal being employed in electricity meters. The seals were installed on the inside of the meter boxes, which in turn were physically closed and locked. RFID reader remotely monitors multiple seals simultaneously.

[033] Experience from electric utilities has shown that most fraud occurs in meters inside the boxes. To physically access the meters, fraudsters need to open the box or otherwise invade their interior space. Thus, any attempt at fraud will be detected by the mechatronic seal that will record this event in your memory digitally and permanently, including the date and time of its occurrence.

[034] Through periodic oversight, streamlined and simplified by the multi-seal remote monitoring system, the breach is easily identified, enabling immediate remedial action to be taken. In addition to the consequent loss reduction, the speed of these remedial actions will tend to discourage further attempts at power theft.

DETAILED DESCRIPTION OF THE INVENTION

[035] The invention described below is represented by Figure 1, which shows the electronic circuit diagram of the mechatronic seal, the components of which are related and described in the following caption: LEGEND OF FIGURE 1 [036] 1 Container to be Sealed [ 037] 2 RFID Transponder

[038] 3 RFID Reader-Writer Antenna

[039] 4 RFID Tag Antenna

[040] 5 ADC = Analog to Digital Signal Converter [041] 6 Activation Controller [042] 7 Activation Status Memory - Binary - Write-once [043] 8 DAC = Digital to Analog Signal Converter [044] 9 Sealing Controller [045] 10 Sealing Status Memory - Binary - Write-once [046] 11 DAC = Digital to Analog Sinai Converter [047] 12 Surveillance Sensor Switch = Sealing Trigger [048] 13 Microphone Power DC for Sealing [049] 14 Micro Power Source Memory Memory - Binary or Byte [050] 15 rume uc Eiteiyiâ lildUZiud pdet RdutoífieílCã [051] 16 RFID Tag ID Memory - Doubfe or String - ROM -Read-Oniy [052] 17 [Option 1] RTC = Real Time Clock - Date and Time of Events [053] 18 [Option 1] Activation Date Memory - Single or Double -Write-once | 054J 19 [Option 1] Memory Date of Violation - Single or Double - Write-once [055] 20 [Option 1] Power Source A.D

[056] 21 [[Option 2j] Activation Count Memory - Integer -ReWritabíE STANDARD CONSTRUCTION AND OPERATION

[057} A) The transponder (2) is physically installed inside the container (i) to be protected, together with its communication antenna (4) and its surveillance sensor (12).

[058] B) The sensor trigger (12) is internally installed between the container body and its lid or access door to detect any relative movement between the parts or even a minimal invasion of the container internal space if choose to use special sensor models such as optical sensors. | QS8} C) After the container (1) has been permanently closed, optionally accompanied by a conventional external mechanical locking of its covers, windows or access doors, an electronic data reading and writing instrument is approached from the container (1) by external state and through radio waves emitted by the antenna (3) excites the communication antenna (4) of the transponder (2).

[060J D) The induced magnetic field in the antenna (4) generates a small electrical current that feeds the power source (li), providing sufficient power for data exchange between the transponder (2) and the data reader (3). While this induction piueessu occurs, the data reader operator (3) sends to the transponder (2) the mechatronix seal activation command. (062] F) The analogue signal of the activation command is received by the antenna (4) 'converted to a signal by the ADC converter (5).

[063} 6} The activation controller (6) receives the digital signal and records in memory (7) the value corresponding to the ON state of the mechatronic seal.

[064] H} Next »the controller (6) informs the data reader instrument (3) of this dubbing status, having to send a signal converted from digital to analog by the DAC converter (8) and transmitted by the antenna \ 4) the transponder.

[065] I) During this data exchange, the transponder ID contained in the memory (16) is also sent to the data reader (3). This procedure sets the typical function of every RFID tag »whose ID is unique and unalterable, ie memory (16) is a read-only ROM type memory.

[066] J) When receiving the activation command simultaneously, the activation controller (6) iarnbérn activates a uoniiolddui uidudu (8), which acts as a type switch! installed in series with the physical sensor trigger switch (12). Thus, the seal is mechanically armed ', initiating the surveillance process against any breach of the container (1).

[067] K) During the surveillance period there will be no power at the source (15) as the reader instrument (3) will not be present. However, the energy required to power the sealing controller (9) is minimal. This energy is supplied by the micron (13).

[068] 11 When a breach of the container (1) occurs, the sine trigger 112) is released, reversing the position of its switch which can be either normally open or normally closed. | 069J M) This change in physical condition of the sensor (12) is immediately detected by the iatration controller (9), which records in memory (10) the value corresponding to the VIOLATED state of the mechatronic seal. | 070j N) After the occurrence of this event, the restoration of the initial physical condition of the sensor (12) becomes innocuous and irrelevant, as it will not be able to alter the memory (10), which will keep its new value permanently. Even using an electronic instrument like the data reader (3) may change the memory (10) except when the transponder configuration is performed in option 2, described below.

[071] O) When subsequent monitoring occurs, during monitoring or mechatronic seal status, the memory value (10) is converted to an analog signal by the DAC converter (tt) and sent by radio to the data reader (3), along with the other data of the RFID tag, that is, the values of the other transponder memories (2). The power for transmission of this data came back from the source (15). J072J P) During the surveillance period, the Iacration controller (9) also monitors the remaining power level of its Iacration source (13) and changes the memory value (14) when this power level reaches the acceptable limit. . Thus, whenever a mechatronic seal status check occurs, the data reader (3) will always receive information regarding the status of the power source (13). The value stored in memory (14) can either represent a minimum remaining energy alert or the percentage value of the remaining energy at the source (13). OPTION 1 - Constructive Variation for Event Dating [073] A) A real-time clock (17) is added to the transponder electronic circuit (2), together with memories (W) and (iyp {074] B) This clock (17) is permanently powered by the power source (20) and functions as a calendar and clock synchronized with the present time. {075] C) During the intratracheal seal activation procedure, when the activation controller (6) writes to the memory (7) the value corresponding to the ON state, it also records to the memory (18) the date and time when This event occurred, obtaining this data from the RTC clock (57). {076] D) Similarly »at the time of tampering with the container (1), when the sealing controller (9) writes to memory (10) the value corresponding to the VIOLATED state of the mechatronic seal, it also writes to memory (19) ) the date and time when this event occurred.

[077] E) During monitoring of mechatronic seal status, memory values (18) and (19) are transmitted to data reader (3) simultaneously to memory values (7) and (10), respectively. .

[078] ¥) Since the power supply (20) has a higher load capacity and is continuously requested, it can absorb the functions of the micron (13), which becomes unnecessary.

[079] G) In this configuration, the sealing controller (9) now monitors the remaining energy level at the power source (20), recording its status in memory (14), just as in the standard constructive form.

OPTION 2 - CONSTRUCTIVE VARIATION FOR MECHATRONIC SAFETY REUSE

[080] A) Memory (21) is added to the transponder electronic circuit (2) and is intended for counting the number of mechatronic seal activations.

[081] B) This memory (21) is positive incremental type and acts automatically and progressively with each seal activation procedure.

It can be read, but cannot be changed by the Data Recorder (3) or any other instrument.

[082} C) In this constructive configuration, memories (7), (10>. (18), and (19) leave üc iei υυ type Wflte-uitue and MctSSâffi d S6f ílo type ReWriíbie (rewritable).

[083] D) For seal reuse, simply reset or erase the memory values (7), (10). (18} and (19).

[084] E) The digital process of retesting these memories can be done by a specific equipment or by the data recorder itself (3). In this case, access to this function may be protected by a security password.

[085] F) The new e c e e e c e e t use when the activation controller (6) receives the activation command sent by the data-recorder operator (3) and writes to the memory (7) the value corresponding to the ON state, the memory value (21) is automatically incremented by 1.

[086] G) The controller (6) then informs the data reader instrument (3) of the new memory value (21), which will correspond to the amount of activation procedures performed on that seal.

M) Aitatively, larger memories can be used at positions (18) and (19). Thus, the values recorded in these memories do not need to be erased and the dates and times of each new activation and tampering are permanently stored, constituting an operational history of the intratracheal seal.

[088] (i) In this same context of using larger memory capacity, it becomes possible to record complementary historical data, such as the Reader-recorder fO (3) which activates the sealing and / or sealing. the user iogir »that operates this data reader. If the container (1) to be protected also has an ID, this data can also be stored in the seal memory, establishing a permanent digital link between them. f08S] J) It is noteworthy that this constructive option 2, which makes the reusable heading, has been construed as constructive option 1 above, that is, the transponder (2) can be constructed with memory (21) acting in addition to the standard system , being linked only to the reset of memories (?) and (10). CONTAINER (1) [090] Container (1) is the object to be sealed.

[091] Can be any type of enclosure or enclosure, containing one or more access points, such as covers, doors, windows, hatches, etc.

[092] These access means may be pivoting, sliding, tilting or removable.

[093] The container (i) could be made of plastic, glass, wood, metal, masonry or any other structural material.

[094] The container (1) may be of any shape and size, provided that it exceeds the physical dimensions of the mechatrenic seal itself which shall be installed within it.

[095] Among the possible types of containers to which the mechatronic seal may be applied are; boxes, crates, switchboards and electrical panels, ship containers and generic containers, safes, tanks, shells, chests, chests, bags »briefcases, cases» cabinets, drawers, bedrooms »skirts» etc. TRANSPONDER (2) [096] The transponder (2) is built on existing RFID chip and chip technology, which is configured, adapted and complemented with electronic components in order to perform the digital iacation functions described in this project, [087] The mechatronic seal design is compatible with passive, semi-passive and active RFiD systems. The choice will be derived from the constructive characteristics of the container (1) to be protected such as: materials »Size and shape. Consideration should also be given to the operational requirements necessary for an effective monitoring process of non-contractual iacres' such as. speed 'multi-seal readability and communication range between transponder (2) and data reader (3).

[098] The mechatronic seal block diagram (Figure 1) and its eoftsíruüwas forms described above were based on the use of a passive RFiD tag with data transmission via electromagnetic induction technology. However, the logic and functional concepts of the seal Mechatronics remain the same when using active or septi-passive RFID tags »with data transmission by Electromagnetic Coupling or Microwaves, as well as in any radiofrequency range used by these models. These constructive variations of the mechatronic seal need not be described, as the technology of these RFID tag models is already well known.

[099] Alternatively, the transponder design (2) also contemplates the use of the RuBee system, which although has a similar functional behavior to the RFiD system »its tag is not considered an RFiD tag, because data transmission is done by magnetic waves. * du instead of wave * u «radio. This system allows for high communication efficiency when it is necessary to install the mechatronic seal inside containers made entirely of metallic material. Despite the technical and conceptual differences between the RuSee and RFID systems, to simplify the description of this project, the RuBee system will be implicit in context in every reference made to the RFID designation.

[100] If an active RFID tag is used, is the power source (15) deleted and transposes it? (2) will be permanently powered by the power source (20).

[10] In the case of use of a separate RFiD tag, the power source (15) is maintained to detect the presence of the data reader (3) and to initiate the communication process. However, the energy used to transmit data from the transponder (2) to the data reader (3) will be multiplied by the source eitefyid (20) or even the ideal (13), which is a significant increase in communication range. DATA READER (3) [1023 The data reader-recorder (d) is a portable electronic instrument, similar to a PDA or palmtop (handheld).

[103] Generally referred to as RFID Rendering only, this type of instrument is systematically used in RFID tagged applications. [104] On an industrial scale, RFID readers are produced and marketed by various companies in the electro-electronics industry.

[105] RFID readers come in a wide variety of constructional models, from simple models with pre-built ugliness and tagging functions to more versatile models with advanced> ptugramation and software »applications running on the same operating systems. used on mobile devices such as PDAs, smartphones and tabs.

[106] Several of these reader models are fully capable of performing all tasks required by the mecatrõnlcc seal design. TRANSPONDER ANTENNA (4) [107] The material, size, shape and number of turns of the antenna \ 4 »vmmm direct impact on the communication range between the transponder (2) and the data reader (3). Likewise, the power of the data reader instrument (3) and the radio frequency band used by the transponder RFID cbip (2) are important variables that determine the maximum operating distance for data exchange. However, the type of RFID system to be employed is surely the factor that determines the effectiveness of communication. Passive RFID systems generally have a range of a few inches to just over three feet, while target and semi-passive RFID systems can now communicate over 150 meters using relatively small antennae.

[108] By default, the transponder antenna (4) should be physically integrated with the RFID chip, forming the so-called Snlay, labei or commercially designed RFID tag}, which in turn will be attached to the electronic circuit or mechatronic seal.

[109] Alternatively. The transponder antenna (4) may be a standalone component, which will be connected to the mechatronic seal integrated circuit through pluggable connectors and terminals, making it a very viable option for situations or applications that require larger or larger antennas. complex. In this embodiment, the antenna (4) may also be installed on the outside of the container (1), thus eliminating the amount of interference in radio frequency communication naturally caused by the walls of the container to be sealed. The benefits of this constructive alternative are greater and They become more evident when the walls of the container are made of metallic material.

[110] In cases where Antenna (4) is chosen to be installed on the outside of the container (2) to maintain the functionality and reliability of the iatrac system, the mechatronic seal transponder may be t * t: r built two antennas operating in paraieto. A main antenna mounted on the outside of the receptacle (2) and an in-house short-range secondary communication antenna which will act as a spare in cases where the main antenna is accidentally or voluntarily damaged as a result of vandalism ». as attempts to tamper with or deactivate the mechatronic seal. SURVEILLANCE SENSOR (12) [111] The surveillance sensor (12) is the mechatronic seal detection component. It is the event trigger of the event that proves the violation of the container cation condition (1).

[112] The Surveillance Sensor (12) is a small single-pole single throw (SPST) fast-acting switch, ie a one-position unipolar switch that can be either normally open or normally closed.

[113] By default, the surveillance sensor (12) is a gravitacone mechanical, magnetic, electrical switch! (barimetric) or any other medium that does not require a continuous power supply for its operation. This concept includes micro-swiiches, permanent magnet switches and spring-based displacement or motion sensors, pendulums, levels and the like.

Alternatively, the surveillance sensor (12) may be an on / off type sensor, that is, a detector that responds by reversing the position of electrical contacts but requiring auxiliary power to keep its sensory principle active. This category includes inductive, capacitive, photoelectric, magnetic and ultrasonic proximity sensors; motion or presence detectors based on infrared light, ultrasound waves, microwaves, and omen- graphs; infrared light, laser and optical fiber optical switches; the light curtains; etc.

[115] All of the variety of monitoring methods applicable to container (i) enables the surveillance sensor (12) to consist of a combination of two or more of these sensing technologies, making the level of safety and reliability of the monitoring system. sealing is considerably increased by eliminating any false-positive violation records. (ftij The surveillance sensor (12) may be physically iftteysddu <ju υυιμυ uu Mechatronic area forming a single piece and may be a standalone device that will be connected to the mechatronic seal integrated circuit via plugs or pluggable connectors.

[117] For large containers or those with more than one natural access point, or those with more vulnerable, penetrable, or otherwise tampering regions, more than one surveillance sensor ( 12) should be installed inside the container (1). to ensure fraud-proof yachting. In this type of mechatronic seal configuration, normally closed type sensors should be connected in series, while normally open type sensors should be connected in parallel. It should be noted that the design of the seal electronic circuit remains the same in this multi-sensor mode of use.

MEMOIRS

[118] All transponder memories (2) are of the Nio-Voláffl type, ie their values remain recorded even without power supply. | HSjf Memory (16) is ROM (Read Only Memory), ie read-only and cannot be erased or altered. It contains the transponder ID, which is represented by an alphanumeric code standardized by international standards such as: EPC (EPCglobal), ISO and IEC. This code is recorded by the manufacturer of the memory chip or the RFID chip that contains it. The code includes the end product manufacturer ID, the product or application type ID, and a unique serial number for each manufactured part.

[120] Memory (16) can be of type Dotibie or String, usually using 8 to 12 bytes (64 to 96 bits), according to the ciasse or normative standard followed in the manufacture of its cbip. ρ2í j The memories (?) and (10) are Binary, of the type 0 uu 1. They only need 1 bit.

[122] Memory (14) can be Binary and use only 1 bit to represent a minimum power level alert, or be Byte type and use 1 byte (6 bits) to represent percentage values of energy.

[123] Memories (18) and (19) can be of type Single or Doubie, requiring 4 or 8 bytes (32 to 64 bis). They are only necessary if the device uses the React RTC (1?) Time clock of constructive option 1.

[124] Memory 21 for the activation count in constructive option 2 is of type Integer and requires 2 bytes (16 bits).

[125] In the standard constructive form of transponder (2), as well as in constructive option 1, the memories (?), (10). (18) and (19) are Write-Once, that is, they can only receive write once.

[126] In constructive option 2. the memories (7), (10), (18), (19) and (21) are of type ReWritabie, ie they can be rewritten several times.

[127] All memories must form a Cynic piece, being integrated and linked to memóud (i6). that takes care of the! D of the transponder. This ensures the authenticity of the mechatronic seal and security against fraud by preventing any memory component from being physically replaced after the seal has been activated or after a sealed container tamper event.

[128] Currently, microchips intended for RFID applications are commercially manufactured. containing memory of sufficient size and characteristics to fulfill the functions required by the mechatronic seal design. These microchips are extremely small in size, making them in principle the best choice for the construction of the mechatronic seal transponder (2). {129] Optionally, all memories can be comprised of a single, removable, independent memory chip. Thus, in the standard construction of the transponder (2) or in constructive option 1, a breached mechatronic seal could be reused in new mm by simply replacing its memory chip.

POWER SOURCES ft 30] Does the power supply (15) generate direct current power for integrated transponder power? (2), only during the activation and data exchange processes between the mechatronic seal and the data reader (3). This direct current energy is due to the conversion of the alternating electric current that is generated in the antenna coil (4) due to the electromagnetic induction from the radio waves emitted by the data reader antenna (3). In summary, power source (15) is an electronic component composed primarily of a rectifier coupled to a voltage regulator and, in the context of transponder design (2), it is an integral part of RFIP microeps operating in the passive system or semi-passive. In the active RFID system, source (15) is non-existent and its functions are performed by power source (20). [131] The power supply (13) is a small primary eochemical cell, ie a non-rechargeable cfo battery, preferably in button shape. It can also be a new generation ultra thin disposable battery in film or film format.

[132] The power source (20) is also a battery with the same constructive characteristics as the micro source (13), but has a higher charging capacity.

[133] In constructive option 2, both the power source (20) and the micro source (13) can be rechargeable batteries, reconciling with the reusable character of the mechatronic seal in this configuration.

[134} In the case of receptacles <1) which can be supplied internally with mains electricity, the power source (20) as well as the micro source (13) may be a rechargeable battery, continuously powered by a small converter. operating on a UPS system, similar to a battery charger for mobile devices such as laptops, mobile phones. digital cameras and portable audio players. The objective is to increase the service life of the mechatronic seal, built in standard form or in the constructive option 1.

[135J Also in this concept of using rechargeable batteries, since recharging is required after long periods of time as the power consumption by the transponder (2) is very small, in the container (1) a connector may be installed. externe 'for the connection of a portable battery charger. In this context, information from memory 14 will be used to schedule the recharging process of batteries 13 and 20.

[136] In specific applications, “if the presence of electrical connectors facing the outside of the container (1) implies a possible reduction in the safety of the sealing system as a whole, wireiess replenishment technique may be adopted. ), ie using inductive type battery chargers, which transfer energy through electromagnetic induction without physical contact. This type of charger is commonly used in electric toothbrushes. If the container (1) is fitted with a transparent visor or a Uansiúckio glass or plastic lid and is exposed to sunlight or is located in a sufficiently bright environment, the batteries (13) and (20) may be replenished. electrical energy from photovoltaic cells installed inside the container (1), forming a power system similar to that used by solar pocket calculators.

[138] When using primary (disposable) or even secondary (rechargeable) batteries in positions (13) and / or (20), the mechatronic seal constructed in standard form or in construction option 1 will have its service life determined by life of these batteries. The life expectancy of electrochemical batteries usually does not reach S years, although some models may last up to 10 years. Therefore, after this period, it becomes necessary to replace the mechatronic seal and rewire the container (1), despite any other impositions resulting from dta-a-dsa. In constructive option 2, periodic replacement of these batteries is also necessary. (f39J Mechatronic seal life can be virtually unlimited through the use of EDLC (Electric Double-Layer Capacitor) capacitors, also known as supercapacitors or ultra-capacitors. Supercapacitors have a long operating life because they store energy in a fairly stable electrostatic process. and safe, without involving chemical reactions like batteries. Even though they have a high self-discharge rate, supercapacitors can be recharged numerous times quite quickly and have the ability to hold their energy wattage at levels sufficient to meet transponder needs ( 2) for several days and even months before being fully recharged.In this context, the use of photovoltaic cell-powered supercapacitors or any other type of battery charger gives the transponder (2) an uninterrupted and highly reliable power source. which can last decades without requiring perform any maintenance.

Claims (34)

1 - NON-DESTRUCTIBLE ELECTRONIC LACRATION DEVICE, intended for the sealing of containers (t) on the inner side, characterized in that it comprises a transponder (2) constructed from a RFID microchip that communicates by radio frequency through an antenna (4) and is remotely activated by an RFID reader (3), which, to activate the device, activates the activation controller (6), which permanently changes the binary memory value (7) and activates the loop controller (9), placing the device in a state of vigilance; During this surveillance period, a DC power supply (13) powers the loop controller (9), which operates a series-mounted digital switch (mm) and the physical switch of the surveillance sensor (12), whose function is to detect the opening. any means of access to the container (1) or the invasion of its lower space, such that when this act is verified, it immediately reverses its contacts, causing the sealing controller (9) to permanently change the value of binary memory ( 10), thus being configured digitally the violation of the sealing. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, as claimed in claim 1, characterized in that the iakracity controller (9) also monitors the power level of its loop source (13) and outputs the memory value (14) when this level of energy reaches the minimum acceptable limit or save the percentage value of the remaining energy. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE according to claim 1, characterized in that, optionally, a real time clock (17) is added to the transponder electronic circuit (2) together with memories (18) and (19). and a power source (20) for powering the RTC (17), which functions as a calendar and clock synchronized with the present time, whose function is to provide data for the activation controller (6) to record in memory (18) to The date and time when the 4th device activation occurred, and in the same manner, provide information for the loop controller (9) to record in memory (19) the date and time the device violation occurs. 4 - NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim 1, expensive or otherwise. In an optional way, the memory (21) is added to the transponder electronic circuit (2) to count the number of activations of the device, which is positive incremental type and acting automatically and progressively in each activation procedure, cf tai iumid d pemutii whose value is valid, but not altered by the RFID reader or any other instrument; In this constructive configuration, memories (7), (10), (18) and (19) are no longer write-once and are rewritable and for reuse of the seal, simply reset or erase m values of these memories, and with each new cycle of seal use, the memory value (21) is automatically incremented by 1. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claims 1 and 4, characterized in. d # Alternatively, use memories larger than 8 bytes (multiples) at positions (18) and (19), so that the values recorded in these memories do not have to be erased and the dates and times of each new activation and violation are stored permanent & menie , constituting an operational history of the mechatronic seal and also allowing complementary data to be recorded, such as the reader-recorder ID (3), its operator ID and the recipient ID. 6 - NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim 1, mm ................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................................... The fact that the transponder (2) is constructed from an RFID microchip operating in passive, semi-passive passive or active; with data transmission through electromagnetic induction, electromagnetic coupling or microwave technology, as well as any radio frequency range used by these models. NON-DESTRUCTIBLE BI LACRATION ELECTRONIC DEVICE according to claims 1 and 6, characterized in that the transponder (2) is alternatively constructed with RuBee microchip, whose transmission to and from aaaos is made by magnetic waves instead of radio waves. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim 1, characterized in that the AOu converter (t>) and the OAC converter (8) are original components of the transponder RFiD microchip (2), while the DAC converter (11) It is a component equal to the DAC converter (8) and can have its functions absorbed by it. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim t, characterized in that the antenna (4), by default, is physically integrated into the electronic circuit of the transponder (2) and, alternatively, is an independent component, which will be connected to the circuit. integrated via pluggable terminals or connectors to allow it to also be installed on the outside of the container (i). NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claims 1 and 9, because the transponder (2) alternatively is constructed with two antennas operating in parallel; a main antenna (4) installed on the outer side of the container (2) and a short-range secondary communication (4), internally installed, acting as a spare in cases where the main antenna will be damaged. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim 1. characterized by the fact that the vigilance sensor (t Z) is a small fast action switch of the type SPST-Single Single Throw, ie a unipolar single position switch; whereas it can either be normally open or normally closed, being by default a mechanical, magnetic, gravitaeional (barimetric) electric switch or any other means that does not require a continuous power supply for its operation, 12 - NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, as shown in Figure 1, caiacietkduu uwiu surveillance sensor fact (12), alternatively, be an ON / OFF sensor, ie a detector that responds by reversing the electrical contacts, but requiring auxiliary power to keep their sensing principle active, including capacitive, photoelectric, magnetic, and ultrasonic inductive proximity minima; motion or presence detectors based on infrared light »ultrasonic waves, microwaves and tomographs; epic infrared light switches »laser and fiber optic, light curtains» etc. NON-DESTRUCTIBLE ELECTRONIC LACRATION DEVICE according to claims 1, 11 and 12, characterized in that the surveillance sensor (12), all advantageous, consists of a combination of two or more of the sensory technologies referred to in claims 11. and 12. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim 1, characterized by the fact that the surveillance sensor (12) can be physically integrated into the mechatronic seal body, forming a single piece, as well as being an independent component, which will be connected. to the transponder integrated circuit (2) through good pluggable users, NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim 1, characterized in that the surveillance sensor (12), alternatively, may consist of more than one sensory component, and the normally closed sensors shall be connected in series, while normally open type sensors should be connected in parallel. 16 - ELECTRONIC DEVICE Hi Nondestructible LACRATION, according to claim 1, characterized in that it is constructed with all memories (7, 10, 14, 16, 18. 19 and 21) being of the non-volatile type, ie their values remain recorded. even with the absence of electricity. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim 1, characterized in that the memory (16) is of 8 or 12 byte ROM type, contains the 1D of the transponder (2), being an original component of the transponder RFID microchip ( 2). NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE, according to claim 1, characterized in that the memories (7) and (10) are binary with 1 bii, the memory (14) is 1 or 8 bits, the memories (18) and ( 19) are 4 or 8 bytes and memory (21) is 2 bytes. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE according to claims 1 and 3, characterized in that the memories (7), (10), <18) and (19) are of the write-once type and according to claim 4, they are of the rewritabie type. , including memory (21). NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE according to claims 1, 3 and 4. characterized in that all memories (7, to, 14, 16, 18, 19 and 21) form a single piece, preferably being an original component of the RFID transponder (2) or alternatively a single chip and memory, independent and removable. NON-DESTRUCTIBLE ELECTRONIC LACRATION DEVICE according to claim 1, characterized in that the power source (15) is an electronic component composed basically of a rectifier coupled to a voltage regulator e. In the context of the transponder design (2), it is an integral part of its RFID microchip operating in the passive or semi-passive system. NON-DESTRUCTIBLE ELECTRONIC LACRATION DEVICE, according to claims 1 and 3, characterized in that the power source (13) and the power source (20) are a small primary or secondary (rechargeable) eitrochemical mat or new generation. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE according to claims 1, 3 and 22. characterized in that the power source (13) and the power source (20), being rechargeable type batteries, can be continuously powered by a direct current converter connected to the public electricity grid. NON-DESTRUCTIBLE ELECTRONIC LACRATION DEVICE according to claims 1, 3 and 22, characterized in that the power supply (13) and the power supply (20), being rechargeable type batteries, can be recharged by a battery charger. portable, inductive wifêless type or directly coupled via connectors in container box (t) NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE according to claims 1, 3 and 22, characterized by the fact that the power supply wire) and the power supply (20), being rechargeable type batteries, can be recharged by photovoltaic cells installed outside the container (1), or internally when fitted with a transparent visor or a glass or translucent plastic lid. NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE according to claims 1 and 3, characterized in that the power supply (13) and the power supply (20) are EDLC (Electric Doufele-Layer Capacitar) capacitors, also known as supercapacitors or uftracapacitors. . NON-DESTRUCTIBLE ELECTRONIC LACRATION DEVICE according to claims 1, 3 and 26, characterized in that the power supply (ia> and power hunger (20), being EDLC capacitors, can be powered by a current converter. connected to the public power grid or a portable battery charger of the wireless type or directly coupled via connectors in the container box (1). NON-DESTRUCTIBLE LACRATION ELECTRONIC DEVICE according to claims 1, 3 and 26, characterized in that the power supply (13) and the power supply (20), being EDLC capacitors, can be fed back by internally installed lotovotta cells. or outside the container (1). 29 - NON DESTRUCTIBLE LACRATION METHOD, intended for electronic sealing of containers (1). non - sealing by the inner side of the container (1), taking the physically self - protected sealing device. - Activating the sealing device from the external side (1), there is an RFID reader (3), ie an electronic radio frequency or magnetic wave communication instrument. - detecting the opening of the container (1) or the invasion of its interior space by means of a surveillance sensor 02), modifying the violation of the sealing state in a non-destructive manner. - digitally and permanently record both the activation event and the sealing violation event in the device memories. - Monitor activation and tampering status from outside of container (1). via an RFID reader (3). - enable status monitoring and data collection from various faeration devices. Bimultaneously. NON-DESTRUCTIBLE LACRATION METHOD, according to claim 29, characterized in. Optionally, enter the date and time corresponding to the activation and tamper events using an RTC real-time clock (17), and this data is also subject to remote monitoring by the RFID reader (3). A non-destructible lacquering method, as claimed in claim 29, which is advanced by opdonalmenle making the reusable uronic laue, which by default would be disposable by the use of rewritable memories at positions (7) (10), (18) and (19) instead of write-once memories, together with the addition of a positive incremental type counting memory (21) to numerically index each new device activation procedure automatically and sequentially. Nondestructible LACRATION METHOD according to claim 29, characterized in that it allows the surveillance sensor (12) to be compatible with any commercial type of electrical switch or ON / OFF sensor as listed in claims 11 and 12. NON-DESTRUCTIBLE LACRATION METHOD according to claim 29, characterized in that, optionally, it monitors a container access point (1), simultaneously using different sensory technologies, represented by two or more sensor types, as listed in claims 11. and 12. A non-destructible lacquering method according to claim 29, characterized in that it optionally seals all access points in the same container (1) using a single mechatronic seal with several surveillance sensors (12) interconnected in series. or parallel.