• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
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  • 法律状态
  • 优先权
    • 专利摘要:
    System and method of monitoring cargo containers of metal walls. The system comprises: Sensors (1) installed inside a cargo container (10) to monitor different variables; A first ultrasound transducer (3) located on an internal wall (26) of the container (10); An internal node (2) located inside the container (10) and configured to receive information from the sensors (1), process said information and excite the first ultrasound transducer (3) to transmit an acoustic signal with the processed information ; A second ultrasound transducer (6) in contact with an external wall (27) of the container (10) and configured to convert the acoustic signal into an electrical signal; An external node (7) located outside the container (10) and configured to receive and process the electrical signal from the second ultrasound transducer (6) to extract information from the sensors (1). (Machine-translation by Google Translate, not legally binding)
    公开号:ES2639765A1
    申请号:ES201630546
    申请日:2016-04-29
    公开日:2017-10-30
    发明作者:Ramón González Carvajal;Eduardo HIDALGO FORT;José Ramón GARCÍA OYA;Fernando Muñoz Chavero;Luis Onieva Giménez;Pablo CORTÉS ACHEDAD;José GUADIX MARTÍN;Jesús MUÑUZURI SANZ
    申请人:Agencia De Obra Publica de la Junta De Andalucia;
    IPC主号:
    专利说明:

    Field of the Invention The present invention is encompassed in the freight transport sector, specifically for applications in the field of intermodal, sustainable, intelligent and integrated transport. The invention implements a non-invasive communication between inside and outside of the
    10 cargo containers for the purpose of variable sensorization, merchandise monitoring and tracking of goods throughout their transport.
    BACKGROUND OF THE INVENTION At present, the monitoring of different variables within the containers of
    15 loading, such as temperature, humidity, movement, or chemical or radioactive levels, is essential for the maintenance of said load, also assuming an increase in the level of safety with respect to the transport of dangerous loads or with respect to the prevention of possible intrusions or thefts . Such monitoring generates economic benefits to all agents involved in the transport of goods: to the port authorities or
    20 railways, to exporting companies, to companies that own the goods, to importing companies, to final customers and even to insurance companies.
    Taking into account that more than 90% of freight transport worldwide is
    25 carried out by containers, the positive impact on the economy and society that has a proper monitoring of unwanted effects on the goods, such as intrusions, attacks, contraband or environmental damage can be predicted.
    Usually, to monitor the results obtained by the sensor networks
    30 located inside the containers, the current commercial equipment has the disadvantage of being intrusive systems when using a wired transmission between the inside and outside of the container, because the metallic environment in which they are located greatly hinders the transmission wireless through conventional communication standards. Thus, said wired transmission implies the
    There is a need to drill at some point on the surface of the container, which does not respect the sealing property required for most freight transport. This way of extracting the information, in turn, implies an additional cost in terms of the installation of the devices, as well as by the fact of supposing a permanent modification in the surface of the container.
    Some of the current commercial equipment, such as Globe Tracker, Triton, TREC or WiFi Smart Chip Tags (WSCT), are complete systems that include merchandise tracking and variable monitoring functionalities such as temperature, container location, opening of doors, or detection of explosives, using wireless communication standards such as GPS, GPRS, WiFi, GSM or ZigBee for sending information from outside the container. However, none of these systems solves the problem of non-intrusion inside the container.
    Most of the works published for container monitoring and tracking applications have not solved the problem of conserving container tightness. Some examples are the scientific publications of S. Mahlknecht, S.A. Madani, "Qn Architecture of Low Power Wireless Sensor Networks for Container Tracking and Monitoring Applications", 5th IEEE International Conference on Industriallnformatics, pp. 353-358, 2007, Y by W. Lang et al., "The" Intelligent Container "-A Cognitive SensorNetwork for Transport Management", IEEE Sensors Joumal, vol. 11, no. 3, pp. 688-698, 2011; as well as patents US 0094209 (e.M. Braun, 2008) and US 7324921 (B.M. Sugahara el al., 2008).
    However, non-invasive systems for inspecting the interior of containers are also known, such as the one disclosed in US7,106,244-B2, which is based on the transmission of an electromagnetic wave and on the reading of the reflected resonant wave. This system has the objective of implementing a correlation between both waves to detect possible manipulations of the contents of the container, as well as the possible presence of explosive or radioactive elements. The means of transmission used are electromagnetic waves where only a comparison is made with a standard wave to detect possible changes inside the container, without actually implementing a communications channel for data transmission. In addition, the system disclosed in US7,106,244-B2 requires the transmission and reception of waves in the range of 100-800 MHz, which implies an increase in the cost of circuits and power consumption, mainly those related to implementation of a very high precision ADC converter at the required sampling rates. In addition, when varying the resonance frequency depending on the area of the container in the range of 100800 MHz (implying that the system is dependent on the container where it is installed) the power on the transmitting side must be very high, because the attenuation of the wave in the metal increases proportionally with the frequency. US7,397,377-B1 presents a solution similar to that disclosed in US7.1 06.244-B2.
    In US8,571, 829-B2, a system based on the detection of objects from the resonance frequency produced by the vibrations inside the container is used, using accelerometers. But in this case a communications channel is not implemented either, its application being very specific for this type of sensorization and without the ability to monitor variables of other natures.
    Finally, there are other non-invasive systems for inspection from inside the containers, such as those shown in US7,376,216-B2, which does not specify the technology used for communication abroad, or US7,156,129 -B2, which proposes the use of an RF transmitter located inside the container in a generic way, for any frequency range and type of modulation. However, these systems do not present a solution to the problems posed by the difficulty of communication and high consumption when transmitting information through metal channels.
    On the other hand, there are other non-invasive techniques dedicated specifically to the tracking of goods such as those based on RFID or OCR (Optical Character Recognition). The first one can be an efficient technology (SJ Barro-Torres et al., "Maritime Freight Container Management System Using RFID", The Third International EURASIP Workshop on RFID Technology, pp. 93-96, 2010), but it has disadvantages such as the cost of readers and labels, collision problems between identifiers, fading problems and multi-path effects of the electromagnetic wave in metallic environments, as well as the possibility of activation of explosives inside the containers making use of The RFID tags themselves. On the other hand, OCR-based techniques (TC Lirn, MS Chiu, "Study of the SMART container monitoring system in the ocean shipping industry", Proceedings of the 14th ISL, 2009) have more complexity in solving related problems with the recognition of characters on the surface of the containers, which suffer numerous damages in parameters such as their shape and color. In addition to these inconveniences, these techniques do not solve the problem of communication between the interior and the exterior of the container.
    In summary, in the field of monitoring cargo containers and, in particular, internal variables such as temperature or humidity, the following are known: -Intrusive monitoring systems, via cable between the interior and exterior of the container, for which there are to perform a drill, causing loss of tightness.
    - Non-intrusive monitoring systems by transmitting an electromagnetic wave and reading the reflected resonant wave, in which a communications channel is not properly established nor can any type of internal variable of the container be obtained.
    - Non-intrusive monitoring systems by transmitting RF waves from inside the container, with the inconvenience of high consumption due to the loss of the signal when traveling through the metal walls of the container.
    The present invention proposes a container monitoring system that solves the problems of the state of the art, being at the same time non-intrusive and low consumption, and that allows obtaining any internal variable of the container by establishing a communication channel between the interior and the outside
    DESCRIPTION OF THE INVENTION The invention relates to a system and a method of monitoring cargo containers that employs a transmission / reception system that solves the disadvantages of existing commercial systems, allowing the monitoring of numerous variables inside the container and communication with the outside through a robust and mature wireless standard, offering as an additional advantage the property of being a non-intrusive system.
    The system comprises at least one sensor installed inside a cargo container, a first ultrasonic transducer located in an internal wall of the container, an internal node located inside the container, a second ultrasonic transducer located in an external wall of the container, and an external node located outside the container. The system may also comprise at least one impedance matching network of the RLC type.
    The internal node is responsible for receiving information from at least one sensor, processing said information and exciting the first ultrasonic transducer to transmit an acoustic signal with the processed information. The second ultrasonic transducer is configured to convert the acoustic signal from the first ultrasonic transducer into an electrical signal. The external node is adapted to receive and process the electrical signal from the second ultrasonic transducer to extract information from at least one sensor.
    In a preferred embodiment, the first and second ultrasound transducers are facing and aligned with each other. Preferably, the first and second ultrasonic transducers are respectively in contact with the surface of the inner and outer wall of the container by means of an acoustic impedance coupling gel.
    The internal node preferably comprises a data processing unit and a DAC converter, the internal node being configured to process the data received from the at least one sensor, modulate the processed data and convert it to the analog domain at the output of the internal node to excite the First ultrasound transducer. For its part, the external node may comprise a data processing unit and an ADC converter, the external node being configured to convert the electrical signal from the second ultrasonic transducer to the digital domain and demodulate said digital signal.
    The internal node is preferably configured to perform a digital modulation of the processed DBPSK type data. In a preferred embodiment, the first and second ultrasound transducers are piezoelectric transducers, where the carrier frequency of the analog signal transmitted by the first ultrasound transducer is the resonant frequency of the piezoelectric material.
    In another possible embodiment the system comprises a second ultrasonic channel, independent of the communication channel formed by the first and second ultrasonic transducer. Said second ultrasonic channel comprises a second pair of piezoelectric transducers, internal transducer and external transducer located respectively in the internal and external wall of the container, where the external transducer is configured to transmit the excitation energy from a power signal to the internal transducer. to store energy in an energy accumulator located inside the container.
    The communication channel formed by the first and second ultrasonic transducer can be bidirectional, the system comprising in this case a selection device to control whether each ultrasonic transducer acts as a transmitter or receiver, selecting between a first mode of operation dedicated to the data communication or a second mode of operation dedicated to the transmission of energy from outside the container to an energy accumulator located inside the container.
    The external node may comprise a wireless network adapter to wirelessly communicate information from at least one sensor. The at least one sensor can be used for, among others, any of the following functions: monitoring the condition of the container load; monitoring of environmental variables inside the container, including temperature, humidity, movement, and / or chemical levels
    or radioactive; container location; opening of container doors; and explosives detection.
    A second aspect of the present invention relates to a method of monitoring metal wall cargo containers. The method comprises:
    Monitor at least one variable inside a cargo container using at least one sensor.
    Process information from at least one sensor.
    Transmit an acoustic signal with the information processed by a first ultrasonic transducer in contact with the inner wall of the container. The acoustic signal is preferably modulated with a digital modulation of the DBPSK type.
    Convert said acoustic signal into an electrical signal by means of a second ultrasonic transducer (6) located on an external wall of the container.
    Process said electrical signal to extract information from at least one sensor.
    Optionally, the method may also comprise wirelessly communicating the information extracted from at least one sensor.
    Unlike previous inventions, the present invention implements the transmission / reception of information in a non-intrusive manner through the wall of a cargo container for monitoring the values given by a sensor network located therein. In the present monitoring system, the transmission of the data is carried out using ultrasound signals through a metal channel and, therefore, the operating frequencies are in the KHz range, also greatly reducing consumption. The external node itself where the ultrasonic receiver is located in turn integrates the functionality of sending the tracking information of the containers.
    The present invention uses an ultrasonic transmission and reception system for applications for monitoring the state of the container load and the environmental variables inside, with the aim of implementing a non-invasive system that respects the tightness of the container, to while allowing a transmission of information from the excitation of piezoelectric transducers with low voltage levels, so as to reduce the energy consumption inside the container, extending its life time and need for maintenance.
    The proposed invention employs piezoelectric transducers to transmit ultrasound signals through the metal wall of cargo containers for use in sensing and monitoring applications, with the aim of solving the problem posed by transmitting information through a metal channel, maintaining the tightness of the container and avoiding the use of cables that modify its surface. The non-intrusive nature of the system, together with the low consumption it presents, represent the main advantages over the prior art.
    The system comprises a node located inside the container, which collects the information of a network of sensors that monitor the different environment variables in said interior. The information collected will serve as an input of a digital-analog converter (DAC) that excites with a modulated signal to the piezoelectric material located on the inner wall of the container. Said information has a carrier frequency equal to the resonance frequency of the piezoelectric material, and the information can be modulated in the microcontroller itself digitally. In a preferred embodiment, a DBPSK (Differential Binary Phase Shift Keying) modulation is used, due to its robustness and compliance with the bandwidths required by the application. Thus, the fact that the ultrasonic transmission through a metal channel is not excessively robust requires that the modulation implemented be so, so that the chosen DBPSK modulation is optimal due to the low bit error rate it presents. Another factor when choosing this modulation for this specific application is the fact that a non-coherent demodulation is required (that is, without sharing clock reference), due to the complexity of keeping the synchronism between the transmitter and the receiver on both sides of the metal wall if a differential modulation is not used. However, the present invention is not necessarily limited to a DBPSK modulation, and it is possible to use any other type of modulation supported by the resonant frequency and the bandwidth of the chosen piezoelectric material.
    On the other hand, the system comprises another transducer of similar characteristics located in the outer wall of the container, being the first element of the receiving chain. Said transducer is excited by the acoustic wave that travels through the metal channel, generating from it the electrical signal that, with the correct signal conditioning and amplification circuit, serves as input to an analog-digital converter (ADC), which generates digital data for processing and subsequent shipment. In this way, a real-time monitoring system is obtained, of low consumption (using KHz transmission rates), and non-invasive, avoiding the use of cables and, thus, maintaining the tightness of the container, which means The main advantage over current systems for the same type of applications.
    The proposed invention therefore consists of a non-invasive monitoring system for cargo containers, based on the transmission and reception of ultrasound waves through the metal channel formed by the metal wall of said containers. The invention is presented as part of a complete container monitoring and tracking system. This system is made up of a network of sensors distributed inside the container, with the objective of measuring variables such as temperature, humidity
    or movement The outputs of said sensors are collected, by a wired connection, by an internal node located in the internal wall of the container. Said node has a low consumption microprocessor that orders said information in data frames, which serve as input for the device that is responsible for exciting the piezoelectric ultrasound transducer. Said voltage generation circuit is based on a digital-analog converter (DAC) located at the output of said node, which generates a wave with carrier frequency equal to the resonance frequency of the piezoelectric transducer, and modulated from a scheme that supports the bandwidth required by the application. The modulation of the information is carried out in the microcontroller itself digitally and is preferably of the DSPSK (Differential Binary Phase Shift Keying) type. Additionally, a buffer is used between the DAC converter and the transducer in order to decouple its impedances.
    The modulated acoustic wave travels through the metal channel formed by the container wall until the piezoelectric transducer located on the outer wall is excited. Both piezoelectric transducers are brought into contact with the container wall through the use of an acoustic impedance matching gel. In this way, the external transducer generates voltage levels that serve as input to an amplification stage that compensates for the attenuation suffered by the wave through the metal channel and adjusts the voltage levels to those required by the demodulator. The demodulator can be implemented in the digital domain using an analog-digital converter (ADC) at the input of the external node of the system. In this way, the digital levels of information are demodulated in the microprocessor of the external node located on the external wall of the container, ordering said information and sending it, through a wireless network, with the aim of managing the monitoring of the measured variables inside the container. The values of these variables are stored in a database in order to provide the information collected to the end user of the system.
    Finally, as an additional advantage, the ultrasonic-based communications channel itself can be used for the transmission of energy from the outside to the inside of the container, in order to extend the life of the circuits installed in it. This functionality can be implemented based on the bidirectional configuration of the channel (or the use of a second communication channel in the opposite direction) and the use of the necessary circuits for the transmission and storage of energy, such as power amplifiers or rectifiers .
    BRIEF DESCRIPTION OF THE DRAWINGS A series of drawings that help to better understand the invention and that expressly relate to an embodiment of said invention that is presented as a non-limiting example thereof is described very briefly below.
    Figure 1 represents a general scheme of the complete system where the invention is integrated, that is, the sensor network inside the container, the ultrasonic transmission and reception system through the metal channel, and the implementation of the wireless network that collects and manages the data.
    Figure 2 shows an example description of the modulation used.
    Figure 3 represents a transmission / reception scheme of the ultrasonic-based monitoring system, with description of each of the blocks that compose it.
    Figure 4 illustrates, by way of example, the load amplification circuit necessary for signal conditioning, and its characteristic curve.
    Figure 5 illustrates, in another alternative embodiment, an implementation of a second ultrasonic channel for the transmission of energy from outside the container.
    DETAILED DESCRIPTION OF THE INVENTION The monitoring system of the present invention utilizes an ultrasonic transmission and reception system for applications for monitoring the state of the cargo of the containers and the environmental variables therein, with the aim of implementing a system Non-invasive that respects the tightness of the container, while allowing a transmission of information from the excitation of piezoelectric transducers with low voltage levels, reducing in turn the energy consumption inside the container, extending its time of life and minimizing the need for maintenance.
    The present invention has merchandise monitoring and tracking applications, especially when the preservation of the watertightness of the systems to be monitored is required, using ultrasonic communication through metal channels. As a preferred implementation, modulation-demodulation stages are proposed for load monitoring applications, as well as the use of the possible amplification circuits of the electrical signal generated by the piezoelectric transducer on the receiving side for this type of applications. Additionally, the ultrasonic-based communications channel itself can be used for the transmission of energy from outside to inside the container, with the aim of extending the life of the circuits installed in it. In this way, the maintenance of the system is facilitated, reducing the frequency of access to the container in order to replace the batteries.
    A preferred embodiment of the invention is shown in Figure 1, where the use of ultrasonic transmission and reception technologies for variable monitoring applications inside cargo containers is shown. Thus, the variables obtained from the sensor network 1 inside the container 10 are collected by an internal node 2 generally based on a low-consumption microcontroller, or other similar device with signal processing capabilities. The processed data is modulated and converted to the analog domain at the output 4 of said internal node 2 to excite a first ultrasonic transducer 3, in contact with the surface of the inner wall of the container 10 by using a coupling gel of acoustic impedance The first ultrasound transducer 3, excited at its resonance frequency, generates an acoustic wave that travels through the channel formed by the metal wall of the container 5 until it reaches the entrance of a second ultrasound transducer 6 located on the outer wall of the container 10. The second ultrasonic transducer 6 is responsible for converting the received acoustic signal into an electrical signal that is amplified to the voltage levels required by an ADC converter located at the input of the external node 7 of the system.
    The digital data obtained is demodulated by a data processing unit, preferably a low consumption microprocessor, installed in the external node 7. Said data processing unit can also be implemented with any other type of signal processing device, being possible In turn, the received signal is demodulated in the analog domain. Finally, the information obtained is sent, generally through one or several wireless networks 8, with the objective of remotely managing the monitoring of the variables measured inside the container. The values of said variables are stored in a database 9 in order to provide the information collected to the end user of the system 11, for example through a web interface from a computer.
    The modulation implemented in a preferred embodiment is described more specifically in Figure 2. Although the invention does not exclude the possibility of any other modulation technique, analog or digital, depending on the transmission rate required and the bandwidth of the ultrasonic transducer used, in this example the use of a digital modulation of type is proposed. DBPSK 12, for which the transmission of a logical '1' results in the maintenance of the phase of the transmitted analog signal and the transmission of a logical 'O' in the phase change of said signal. Said phase change will be 180 °, as it is a binary modulation, which implies an increase in robustness in demodulation, increasing the distance between the decision thresholds and thus reducing the bit error rate ( BE). A second advantage of this demodulation lies in the fact that it is not coherent, that is, synchronization with the transmitter is not necessary, since the value received depends only on the previous one, which greatly reduces the complexity in demodulation.
    The carrier frequency of the transmitted analog signal is equal to the resonance frequency of the piezoelectric transducer, where the operating frequencies are in the KHz range. For example, in an evaluated system 40 KHz is used, for which a transmission bandwidth of 10KHz is obtained, which is supported by that specified by the transducer manufacturer. Additionally, this bandwidth is sufficient to support the transmission rate required to implement a reading of the outputs of the sensor network in real time. Figure 2 also illustrates, illustratively, an experimental capture of the transmitted signal 13.
    An example of the implementation of the transmission and reception chain based on ultrasound is illustrated in Figure 3. It is observed how the data obtained from the sensors 1 by the microprocessor 20 of the internal node 2 are stored in logic tables 21 in order to obtain words (for example, 12 bits) that serve as input to a DAC converter 22 thereof resolution. For the specific case shown in Figure 3, we work with a clock frequency 23 of 640 KHz, which is chosen since it is the maximum integer multiple power of 2 of the carrier frequency (40 KHz) less than 1 MHz (maximum rate of conversion of the DAC in particular), with the aim of reducing the complexity and calculation power required in the transmission, although other carrier frequencies and other clock frequencies could be used. Each bit of data is transmitted using eight cycles of the carrier signal, which decreases the impact on the result of demodulation in case of loss of synchronization, that is, of the loss of one or more transmitted cycles. Said bit-level coding assumes a bit time of 0.2 ms and, therefore, for this particular binary modulation, the transmission bandwidth is 10KHz.
    After the analog signal is sent, it goes through an impedance adaptation stage, which can be implemented by a buffer 24 or an impedance adaptation network 25 of the RLC type, to subsequently attack the first ultrasound transducer 3 located in the inner wall 26 of the container 10, to which an acoustic impedance coupling gel 30 is applied in turn. Said acoustic impedance coupling gel 30 is also applied to the second ultrasonic transducer 6 located on the external wall 27 of the container 10, which receives the acoustic wave that travels through the metal channel formed by the wall of the container 28. The metal channel presented by the wall of the container 28 is usually between 3 and 10 cm thick, so it must be ensured that the attenuation in the material (usually steel) does not prevent the recovery of the signal in reception. Because the attenuation in the metal is proportional to the carrier frequency, transmitting at a relatively low frequency (eg 40 KHz) is an additional advantage because the transducer can be excited with relatively low voltages, in this case concrete equal to 3.3 V, being generated from the microprocessor 20. This fact increases the savings in total energy consumption, which is critical especially inside the container 10, thus reducing the need for maintenance and access to its interior.
    Likewise, the use of a low transmission frequency also means saving energy consumption in the receiving part of the external node 7t when an ADC converter 71 with a low sampling rate is required. A final advantage of the use of low transmission frequencies lies in the fact that in this way the effects of fading and multi-path in the channel are reduced, thus avoiding the use of equalizers in reception that increase the complexity of its implementation
    However, the object of the present invention is also applicable for systems that require a higher transmission rate, thereby raising the total consumption of the system, but maintaining the rest of its properties.
    Prior to analog-to-digital conversion, an impedance matching network 31 of the RLC type can be implemented, if necessary, and an amplification stage 32 to achieve the levels required by the ADC converter 71. The digital values, once converted, they are stored in a logic table 72 to be demodulated from the comparison 73 of the current bit with the previous bit received, so that it is detected if it exists
    or not a phase change. In turn, this type of modulation has the additional advantage of being able to be implemented by software in the same microprocessor 70 of the external node 7. The demodulated and processed data may be sent by a wireless network 8 to the management system or stored for Be treated later.
    The proposed invention also allows the use of two or more ultrasound transducers on one or both walls of the cargo container 10 when the application requires redundancy in the communication channel in order to increase its reliability. It also includes the possibility that both ultrasonic transducers are not completely aligned, as well as the possibility of transmitting the information by ultrasound from one container to another container or several in contact with it (for example, inside a warehouse or a means of transporting goods) from the transmission of the ultrasonic vibrations produced between said adjacent walls.
    Figure 4 illustrates an example of the implementation of the amplification stage 32 of Figure 3 and its characteristic curve 42, at whose input the second piezoelectric ultrasound transducer 6 is connected (in this figure the impedance matching network is not shown 31 being an optional element), the current output of the latter being integrated by means of the use of an IC capacity and a resistance Rf in the feedback loop of an operational amplifier 40, in order to obtain an amplified voltage value V .
    The values chosen for this specific circuit are Rf = 20KO and Cr = 3nF, with the aim of placing the fe cutoff frequency of the high pass filter (fe = 1 / 2TTRtC), which is implemented at least a decade below the resonance frequency (40 KHz). In addition, for the choice of these values, it is necessary to take into account that a capacity as small as possible is of interest (since its value is inversely proportional to the sensitivity of the amplification stage (SvQ = v! Q = 1 / C, », furthermore, it is recommended that it not be less than the capacity of the piezoelectric transducer itself (2.4 nF, according to the manufacturer's specifications.) Thus, in this particular case a load amplifier architecture with adjustment of the filter cutoff frequency is used high-pass, but variations of this amplification stage may also be used, such as voltage amplifiers when the transducer output is not given in current, amplifiers with internal sensitivity adjustment stage, or differential amplification stages with input connection from the circuit to both terminals of the ultrasonic transducer 6, when the two pins of the latter are accessible.
    Finally, Figure 5 illustrates an example of the functionality of energy transmission from the outside to the inside of the container 10, with the aim of extending the useful life of the circuits installed therein. In said example, a second ultrasonic channel 51 independent of the communication channel 50 described above is used. The second ultrasound channel 51 makes use of a second pair of piezoelectric transducers (internal transducer 56 and external transducer 57) located on the external wall 27 and internal 26 of the container 10. The external transducer 57 is excited by a power signal 52 a its resonance frequency, generally from the use of a power amplifier 53, a harmonic rejection filter 54 and an impedance matching network 55 or an adaptation buffer. Inside the container 10 the internal transducer 56 excited to its resonance frequency generates an electrical signal that is adapted by means of an impedance matching network 58, prior to the passage of the signal through a rectifier circuit 59 to subsequently store its energy ( for example, in a capacitor bank 60).
    As an alternative to the embodiment shown in Figure S, this power transmission functionality can be implemented using the same transducers (3, 6) as those used for data communication, based on the use of a single bidirectional ultrasound channel. Using this architecture, a selection device (such as a switch or multiplexer) is placed on each side of the container wall, so that it controls whether the piezoelectric transducer acts as a transmitter or receiver, selecting one of the corresponding circuitry described above, either the one dedicated to data communication. or the one dedicated to the transmission of energy.
    权利要求:
    Claims (15)
    [1]
    1. Monitoring system for metal wall cargo containers, characterized in that it comprises:
    at least one sensor (1) installed inside a cargo container (10);
    a first ultrasound transducer (3) located on an inner wall (26) of the container (10);
    an internal node (2) located inside the container (10) and configured to receive information from at least one sensor (1), process said information and excite the first ultrasound transducer (3) to transmit an acoustic signal with the processed information;
    a second ultrasonic transducer (6) located on an external wall (27) of the container (10) and configured to convert the acoustic signal from the first ultrasound transducer (3) into an electrical signal;
    an external node (7) located outside the container (10) and configured to receive and process the electrical signal from the second ultrasonic transducer (6) to extract information from at least one sensor (1).
    [2]
    2. System according to claim 1, characterized in that the first (3) and second (6) ultrasound transducers are facing and aligned with each other.
    [3]
    3. System according to any of the preceding claims, characterized in that the first (3) and second (6) ultrasound transducers are respectively in contact with the surface of the inner (26) and outer (27) wall of the container by means of a coupling gel acoustic impedance (30).
    [4]
    Four. System according to any of the preceding claims, characterized in that the internal node (2) comprises a data processing unit (20) and a DAC converter (22), the internal node (2) being configured to process the data received from the minus a sensor (1), modulate the processed data and convert it to the analog domain at the output (4) of the internal node (2) to excite the first ultrasound transducer (3).
    [5]
    5. System according to any of the preceding claims, characterized in that the external node (7) comprises a data processing unit (70) and a converter
    ADC (71), the external node (7) being configured to convert the electrical signal of the second ultrasonic transducer (6) to the digital domain and demodulate said digital signal.
    [6]
    6. System according to any of the preceding claims, characterized in that the internal node (2) is configured to perform a digital modulation of the processed data of type DBPSK (12).
    [7]
    7. System according to any of the preceding claims, characterized in that the first (3) and second (6) ultrasound transducers are piezoelectric transducers, where the carrier frequency of the analog signal transmitted by the first ultrasound transducer (3) is the frequency of resonance of the piezoelectric material.
    [8]
    8. System according to any of the preceding claims, characterized in that it comprises at least one impedance matching network (25, 31) of the RLC type.
    [9]
    9. System according to any of the preceding claims, characterized in that it comprises a second ultrasonic channel (51), independent of the communications channel (50) formed by the first (3) and second (6) ultrasonic transducer, said second channel comprising ultrasound (51) a second pair of piezoelectric transducers, internal transducer (56) and external transducer (57) located respectively on the inner (26) and external wall (27) of the container, where the external transducer (57) is configured to transmit the excitation energy from a power signal (52) to the internal transducer (56) to store energy in an energy accumulator (60) located inside the container (10).
    [10]
    10. System according to any of the preceding claims, characterized in that the communication channel (50) formed by the first (3) and second (6) ultrasonic transducer is bidirectional, the system comprising a selection device for controlling whether each ultrasonic transducer (3, 6) acts as a transmitter or receiver, selecting between a first mode of operation dedicated to data communication or a second mode of operation dedicated to the transmission of energy from outside the container to an energy accumulator (60) located inside the container (10).
    [11 ]
    eleven . System according to any of the preceding claims, characterized in that the external node (7) comprises a wireless network adapter for wirelessly communicating information from at least one sensor (1).
    [12]
    12. System according to any of the preceding claims, characterized in that the at least one sensor (1) is used for any of the following functions:
    - container load status monitoring (10);
    - monitoring of environmental variables inside the container (10), including any of the following: temperature, humidity, movement, and / or levels
    chemical or radioactive: - container location (10); -opening container doors (10); -explosive detection.
    [13]
    13. Method for monitoring metal wall cargo containers, characterized in that it comprises: monitoring at least one variable inside a cargo container (10)
    using at least one sensor (1); process information from at least one sensor (1); transmit an acoustic signal with the information processed by a first
    ultrasonic transducer (3) in contact with the inner wall (26) of the container (10); converting said acoustic signal into an electrical signal by means of a second ultrasonic transducer (6) located on an external wall (27) of the container (10); process said electrical signal to extract information from at least one sensor (1).
    [14]
    14. Method according to claim 13, characterized in that the acoustic signal is modulated with a digital modulation of type DBPSK (12).
    [15]
    fifteen. Method according to any of claims 13 to 14, characterized in that it comprises wirelessly communicating the information extracted from at least one sensor (1).
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP3772635A1|2019-08-07|2021-02-10|Sulzer Management AG|Sensing arrangement for a closed container and method for transmitting data through the container wall|
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