EP2341488A1 - Sensor module for monitoring the target value of an indicator and method - Google Patents

Abstract

The module (101) has display units (106) for representation of states e.g. alarm states, of the module. A printable surface carrier element (102) accommodates an electronic circuit (104), a sensor (103) and the display units. The display units are designed such that an electrical pulse of the electronic circuit produces an electrochemical induced spectroscopic alteration in an electro-chromic element of the display units for visually displaying the state of the module. A memory is connected with a radio frequency identification transponder. The electronic circuit is designed as an organic electronic circuit or polymer electronic circuit. An independent claim is also included for a method for monitoring a reference value of a measured variable.

Description

The invention relates to a sensor module for monitoring at least one predetermined desired value of a measured variable. The sensor module comprises at least one sensor for detecting the measured variable and at least one display for representing states of the sensor module, wherein the sensor and the display are in connection with an electronic unit and the measured variable measured by the sensor can be transmitted to the electronics.

The invention further relates to a method for monitoring at least one predetermined desired value of a measured variable in which such a sensor module is used.

In the field of logistics, it is often necessary to monitor a given measurand when transporting a good. For example, a temperature-controlled transport is necessary to ensure the quality and durability of temperature-sensitive products, such as food, laboratory samples or medicines, during transport. It is particularly important to monitor the temperature profile during the entire transport. For this u.a. Temperature and time data recorded and recorded and the exceeding or falling below of predetermined setpoints determined.

In order to monitor such measurands when transporting a good, transport containers may include integrated sensor modules. Such transport containers preferably also include insulation and / or refrigeration units for temperature-sensitive goods. In order to read out the data recorded during the transport, the sensor module can have a connection for a reading device and / or a contactless one Have interface for reading data, for example by means of RFID technology.

However, it is also possible to use mobile sensor modules that are inserted, for example, in addition to the goods to be transported in a transport container or a transport packaging. For monitoring the temperature during transport, in particular mobile sensor modules without display and with an antenna have been established in the past, which can continuously record temperature data and can be read out without contact by means of a reading device. For this purpose, a sensor module is removed from the transport container after transport. The measured data read out are then prepared, for example, stored on a server and are available there for quality control.

However, such sensor modules without display usually have the disadvantage that only after a readout and storage of data on a server, the possibility of an assessment of the recorded measurement data is. The entire process is thus equipment-intensive, since appropriate technical facilities for the reading, processing and provision of the data are required. In addition, overshooting or undershooting setpoint values is not immediately apparent when a sensor module is removed from a transport container.

It is thus desirable to provide such mobile sensor modules with a display to visually display various states of the sensor module. These states to be displayed include at least the overshoot and / or undershooting of setpoints during a carried out transport, so that a person can immediately read a kind of alarm from a sensor module when it removes the sensor module from a transport container.

Furthermore, however, it is often also necessary to visually indicate on a sensor module whether the measurement of the relevant measured variable is currently activated or deactivated. The measuring process is usually activated only when the sensor module is placed in a transport container and the transport begins. Once the transport is completed and the sensor module is removed again from the transport container, the measuring process can be terminated. If a person activates a sensor module and places it in a transport container, it is thus advantageous if the activation is displayed so that the person can be sure that the activation has taken place. The same applies to the person who withdraws the sensor module from the transport container and should be visually indicated that it is an activated sensor module that has documented the transport of the relevant goods in accordance with the regulations. If this second person now deactivates the sensor module, the successful deactivation should also be displayed.

In order to achieve such a display of various status information of a sensor module, sensor modules with an LED or LCD display are usually used. However, these displays are expensive and require special manufacturing techniques for their manufacture. If you want to provide very flat and inexpensive sensor modules, for example, for a single use, these displays are therefore not suitable.

The object of the invention is therefore to provide a sensor module for monitoring a predetermined desired value of a measured variable, with the aid of which different states of the sensor module are optically quickly and easily displayed. The sensor module should be able to be made very flat and inexpensive and easy to produce by means of simple manufacturing processes.

A further object of the invention is to provide a method for monitoring a predetermined desired value of a measured variable in which such a sensor module can be used.

This object is achieved by a sensor module having the features of independent claim 1. Advantageous developments of the sensor module will become apparent from the dependent claims 2 to 10. The object is further achieved by a method according to claim 11. Advantageous embodiments of this method will become apparent from the subclaims 12 to 15.

The invention provides a sensor module for monitoring at least one predetermined desired value of a measured variable. The sensor module comprises at least one sensor for detecting the measured variable and at least one display for representing states of the sensor module, wherein the sensor and the display are in connection with an electronic unit and the measured variable measured by the sensor can be transmitted to the electronics. The sensor module further comprises a sheet-like, printable carrier element which receives the at least one sensor, the electronics and the display. The electronics are designed as organic electronics and the display is printed on the carrier element and irreversibly changed. The display comprises at least one electrochromic element and is configured such that an electrical pulse of the electronics effects an electrochemically induced spectroscopic change of the at least one electrochromic element of the display that is irreversible and visually indicates a condition of the sensor module.

Such a sensor module can be formed very flat due to the printed display and the organic electronics, and still can be displayed by the display with electrochromic elements states of the sensor module in a simple manner.

In one embodiment of the sensor module, the display has a plurality of electrochromic elements and is designed so that different electrochemically induced, spectroscopic changes can be effected by a pulse of the electronics in the plurality of electrochromic elements, whereby a text can be generated on the display, a state of the sensor module. For example, words such as "START", "STOP" and / or "ALARM" may be displayed on an ad.

In another embodiment of the sensor module, in turn, the display has one or more electrochromic elements and is designed so that the same electrochemically induced spectroscopic change in the one or more electrochromic elements can be effected by a pulse of the electronics, whereby a color change of entire display can be generated. For example can be provided that a field changes its color from green to red to visualize an alarm.

A development of the sensor module is characterized in that a text is printed next to the display, which reflects the state of the sensor module. For example, the word "ALARM" may be imprinted and an adjacently located display changes color to indicate the alarm. Another development of the sensor module is characterized in that a plurality of displays are mounted on the carrier element, and next to each display, a text is printed, which reflects the state of the sensor module, the texts are different. Thus, different texts such as "START", "STOP" and / or "ALARM" can be printed on the sensor module, and by the color change of an arranged respectively next to the text display the relevant states are visualized.

In one embodiment of the sensor module, the electronics and / or the sensor are printed on the carrier element. In one embodiment, the electronics and / or the sensor are printed on the carrier element by means of a screen printing process. This production makes it possible to realize very flat sensor modules.

A development of the sensor module provides that an energy source is part of the electronics and in one embodiment of the sensor module is provided that the sensor is designed as a temperature sensor.

The sensor module is characterized in a further development in that the sensor module comprises a memory in connection with the electronics and an RFID transponder, wherein via the RFID transponder data can be read without contact from the memory. States of the sensor module can not only be visualized, but data can also be read without contact.

The invention further comprises a method for monitoring at least one predetermined desired value of a measured variable with a sensor module according to the preceding description. In the process, the electronics transmits for display a state of the sensor module an electrical pulse to the at least one display, said electrical pulse causes an electrochemically induced, spectroscopic change of the at least one electrochromic element of the display, which is irreversible and indicates a state of the sensor module.

In one embodiment of the method, the electronics of the sensor module comprises means for detecting the overshoot and / or undershooting of a desired value of the measured variable and means for generating an electrical alarm pulse when overshooting and / or falling below this setpoint, the electronics a so generated alarm pulse to the Indicated, which causes the electrochemically induced spectroscopic change of the at least one electrochromic element of the display. An overshoot and / or undershoot of a desired value thus causes an alarm, which is visually displayed on the sensor module according to the invention.

In another embodiment of the method, the electronics of the sensor module comprises means for starting the measuring operation of the at least one sensor and generating an electrical start pulse, wherein the electronics transmits an electrical start pulse thus generated to the display, which is the electrochemically induced spectroscopic change of the at least one electrochromic element of the display causes.

Another development of the method provides that the electronics of the sensor module comprises means for canceling the measuring operation of the at least one sensor and for generating an electrical termination pulse, wherein the electronics transmits a so generated electrical termination pulse to the display, which is the electrochemically induced spectroscopic change of causes at least one electrochromic element of the display.

Also, the starting and stopping of a measurement process is thus visually displayed on the sensor module according to the invention.

An embodiment of the method is characterized in that an alarm pulse, a start pulse and a Abbruchimpuls each from the electronics to another Display of the sensor module are transmitted, wherein on the support member of the sensor module, a plurality of displays are attached, and next to each display, a text is printed, which reflects the state of the sensor module, the texts are different.

The sensor module described and the associated method for monitoring at least one predetermined setpoint value of a measured variable to be monitored have the advantage that a display printed on the sensor module maps the overshoot and / or undershoot of the setpoint and, in addition, different states of the sensor module. For this purpose, the display comprises at least one electrochromic element, to which an electronic unit transmits an electrical impulse, which in turn causes an electrochemically induced spectroscopic change of the electrochromic element of the display.

The invention thus turns away from sensor modules without display, in which deviations of a monitored measured variable of a setpoint value can be recognized only when all measurement data has been read out and processed stored on a server, from which they still have to be retrieved.

An advantage of the invention over these sensor modules is thus in the directly readable display of the sensor module, on which the monitoring result is shown. Since the monitoring result is immediately available on this display, the reaction time is reduced to any deviations in the monitored measured variable. In addition, additional technical facilities are not required for an assessment of the recorded measurement data.

The invention also makes it possible that not only the display of monitoring results, but also the representation of various other states of the sensor module is possible on the display. For example, it is possible to display whether a monitoring process has been started and / or stopped. Thus, the proper operation of the sensor module can be checked at any time without much time or equipment technical effort.

Furthermore, the invention turns away from sensor modules with an LED or LCD display, which indeed also offer the possibility of displaying various states of the sensor module, but which are usually expensive and require special manufacturing techniques. The use of a printed display thus results in that the sensor module can be made flat, whereby it can be produced inexpensively and by generally available manufacturing methods.

The above and other advantages, features and expedient developments of the invention will become apparent from the embodiments, which are described below with reference to the figures.

Fig. 1a

ein Sensormodul mit einer Anzeige;

Fig. 1 b ein

Sensormodul mit einer Text-Anzeige;

Fig. 1c

ein Sensormodul mit einer Anzeige mit einem zugehörigen Text;

Fig. 2a

ein Sensormodul mit mehreren Anzeigen und

Fig. 2b

ein Sensormodul mit mehreren Anzeigen mit jeweils zugehörigem Text.

From the figures shows:

Fig. 1a

a sensor module with a display;

Fig. 1 b a

Sensor module with a text display;

Fig. 1c

a sensor module with a display with an associated text;

Fig. 2a

a sensor module with several displays and

Fig. 2b

a sensor module with several displays, each with its own text.

In Fig. 1a schematically shows the example of a sensor module 101 for monitoring a predetermined setpoint for a measured variable. The sensor module 101 has as components a carrier element 102, a sensor 103, an electronics 104 with a battery 105 and a display 106.

The task of the sensor module 101 is to monitor a desired value of a measured variable. For this purpose, measured values are acquired by the sensor 103, which are transmitted to the electronics 104 and evaluated by the latter. The result of this evaluation is then displayed on the display 106 as a monitoring result of the setpoint monitoring.

The carrier element 102 of the sensor module 101 serves to receive the individual components for the sensor module 101. It is designed as a flat, printable surface element, which consists of one or more material layers. As a material for the support member 102, for example, various plastics or films, paper, cardboard or the like can be used.

The sensor 103 is, for example, a temperature sensor for recording and recording temperature measurement data. However, it is also possible to use other sensors, for example for detecting moisture or pressure measurements. In addition, the integration of several different sensors on the sensor module 101 is possible. There is an electrical connection between the sensor 103 and the electronics 104.

The electronics 104 is designed as organic electronics, which is also well known under the term of polymer electronics. Organic electronics use electronic circuits of conductive polymers. Circuits and electronic components are formed from macromolecules, which are printed on a carrier substrate in the form of thin films. For receiving the organic electronics, the carrier substrate comprises an organic film on which the organic electronics are printed.

A component of the electronics 104 is a battery 105 as an energy source. The battery 105 has various pressure layers and includes an anode, such as zinc, and a cathode, such as manganese. Both substances react with each other and generate electricity. During the course of this chemical reaction, both substances are consumed, so that a lifetime is definable for the battery 105 as a function of the anode and cathode layer thicknesses.

Also electrically connected to the electronics 104 is the display 106, which is designed as a printable sheet-like element, which is in its initial state as, for example, transparent surface. The display 106 has at least one electrochromic element with electrochromic substances which during the Applying an electrical voltage change their molecular structure and thus their absorption and reflection behavior for electromagnetic radiation, in particular for visible light. These electrochemically induced, spectroscopic changes in the electrochromic substances are irreversible until a polarity change of the applied voltage occurs.

The molecules of the electrochromic substances of the electrochromic element are located on a carrier foil in which very thin electrodes are embedded. In addition, there is a conductive and transparent plastic film, which acts as a counter electrode and at the same time ensures the visibility of color changes. The power supply of the electrochromic element of the display 106 is realized via the battery 105 of the electronics 104.

Electrochemically induced spectroscopic changes cause the electrochromic substances to absorb and reflect other wavelengths, altering their color. Possible colors that can be displayed for electrochromic substances after the application of an electrical voltage are, for example, red, green, blue, brown or gray. The reproducible color change depends on the electrochromic substance used. A color change from transparent to green is achieved, for example, by the use of polyaniline, a color change from transparent to red, for example by the use of poly-o-phenylenediamine or else of 3,4-polyethylene-dioxypyrrole.

If the display 106 originally already shows a color, the electrochemically induced, spectroscopic change results in a color change of the display 106. For example, by using polythiophene, a color change from green to brown can be achieved by applying a voltage.

Not only the electronics 104 with the battery 105 but also the electrical connections, as well as the sensor 103 and the display 106 are applied to the carrier element 102 by means of a printing process. With the use of a printing method for the design of the components on the carrier element 102, the realization of a very flat construction height for the sensor module 101 allows. In addition, a simple, fast and in particular cost-effective production of the sensor module 101 is thus possible.

For the printing of the individual components, for example, a screen printing process can be used. In the screen printing process, printing paste is applied to a carrier substrate, wherein a template covers the locations of the carrier substrate that are not to be printed. This process can be repeated as often as desired with different printing pastes and different stencils. The actual definition of the individual components to be traced takes place via the selection and composition of the corresponding printing pastes and associated templates.

Other possibilities for printing the individual components arise, for example, with the use of an inkjet printing method or a microcontact stamp printing method. Since several printing methods are available, the individual components can be printed both with a uniform method and with different methods.

For attachment of the individual components on the carrier element 102 but also other options are available. The components can be glued, for example, to the support member 102 or welded. In addition, it is possible to print one or more components and stick or weld the other components.

Fig. 1 b schematically shows the example of a display 106 with a displayed text 107, which images a state of the sensor module 101. The representation of a text 107 (ALARM) in the display 106 allows a direct assignment of the display 106 to a state of the sensor module 101 and thus leads to a correspondingly better understanding of the display 106.

For the representation of the text 107, the display 106 comprises a plurality of electrochromic elements with electrochromic substances. After applying a voltage, the text 107 is then about the color change of the electrochromic substances of the individual electrochromic elements visible. In this case, this text 107 can comprise both several words and only one word or one abbreviation.

Furthermore, it is possible to arrange other electrochromic elements between the individual electrochromic elements of the text 107, which show a different color after the application of a voltage than the electrochromic elements of the text 107 and thus form a background color for the text 107.

In Fig. 1 c schematically shows the example of a display 106 with an adjacent to the display 106, associated text 107 (ALARM) shown, which is permanently visible. The text 107 indicates a state of the sensor module 101 and becomes valid whenever the electrochromic substances of the electrochromic elements of the associated display 106 have changed color by the application of a voltage.

As in Fig. 2a By way of example, a plurality of displays 106, 106 ', 106 "can also be arranged on the sensor module 101. Each of these displays 106, 106', 106" indicates a different state of the sensor module 101. Displayable states of the sensor module 101 include, for example, information on whether a recording of measured values by the sensor 103 has begun and when this recording has ended. Another status display represents, for example, the result of the setpoint monitoring.

However, it is also possible to assign the displays 106, 106 ', 106 "to a different sensor 103 if several sensors are arranged on the sensor module 101. This then makes it possible to display the results of the setpoint monitoring for different measured variables.

In Fig. 2b schematically the example of a sensor module 101 with multiple displays 106, 106 ', 106 "with a respective text 107, 107', 107" shown, which can be formed from several words or from a word or an abbreviation. The text 107 -'ALARM ', the text 107'-'START'and the text 107 "-'STOPP' are shown.

The monitoring process for the nominal value monitoring of a measured variable is started via a starting device (not shown) integrated in the sensor module 101. This starting device generates an electrical start pulse in the electronics 104, which is forwarded via the existing electrical connections both to the sensor 103 and to the display 106 '. As a result of this start pulse, the sensor 103 starts recording measurement data which it sends back to the electronics 104 via the electrical connections.

The electrical start pulse of the electronics 104 conducted to the display 106 'causes an electrochemically induced spectroscopic change in the electrochromic substance of the electrochromic element of the display 106'. The originally, for example, transparent display 106 'then displays a color, such as black or green. Thus, it is immediately visible on the sensor module 101 at the display 106 ', which is identified, for example, by the text 107' - 'START', that the monitoring process has been started.

In electronics, the measurement data recorded by the sensor 103 are processed and evaluated. The electronics 104 compares the recorded measured data with a stored in the electronics 104 setpoint for the measured variable to be monitored. Each stored setpoint is identified either as an upper or lower limit. An upper limit of the measured data should not be exceeded and a lower limit should not be exceeded.

The overshoot or undershoot of a setpoint leads in the electronics 104 to generate an alarm pulse. This alarm pulse is relayed by the electronics 104 via electrical connections to the display 106 and there also causes an electrochemically induced, spectroscopic change of the electrochromic substance of the electrochromic element of the display 106. The originally, for example, transparent display 106 then shows a color, for example black or red. This makes it possible to read directly on the sensor module 101 at the display 106 labeled, for example, with the text 107 'ALARM', that the stored one Setpoint was exceeded or undershot during the monitoring process.

If a plurality of setpoint values, for example an upper and a lower limit value, are stored in the electronics 104, the recorded measured data are compared with each of these setpoint values and the alarm pulse is generated if at least one of the setpoint values has been exceeded or undershot.

The termination of the monitoring process via an integrated into the sensor module 101, also not shown stop device. This stop generates an electrical break-off pulse in the electronics 104 which is relayed via the existing electrical connections both to the sensor 103 and to the display 106. As a result of this break-off pulse, the sensor 103 terminates the acquisition of measurement data.

In the display 106 ", the electrical break-off pulse of the electronics 104 also causes an electrochemically-induced spectroscopic change in the electrochromic substances of the electrochromic element of the display 106". The originally, for example, transparent display 106 "thereupon displays a color, for example black or yellow, so that the monitoring process is terminated directly on the display 106", for example with the text 107 "- 'STOP', on the sensor module 101.

The sensor module 101 is flexible and versatile, in particular due to its small dimensions caused by the production. In addition, the sensor module 101 is tamper-proof because the printed components are not easily replaceable and the energy source used has only a defined life. The low production costs recommend it, for example, for use as a disposable product that can be disposed of after a single use. This is especially true when the sensor module 101 is combined with an RFID transponder, which is used for a shipment identification and tracking during transport and over which the recorded measurement data can be read.

LIST OF REFERENCE NUMBERS

101

sensor module

102

support element

103

sensor

104

electronics

105

battery

106, 106 ', 106 "

display

107, 107 '. 107 '

text

Claims (15)

Sensor module (101) for monitoring at least one predetermined desired value of a measured variable, comprising at least one sensor (103) for detecting the measured variable and at least one display (106, 106 ', 106 ") for displaying states of the sensor module, wherein the sensor (103 ) and the at least one display (106, 106 ', 106 ") are in connection with an electronic unit (104) and the measured variable measured by the sensor (103) can be transmitted to the electronics (104),
characterized,
in that the sensor module (101) comprises a sheet-like, printable carrier element (102) which receives the at least one sensor (103), the electronics (104) and the at least one display (106, 106 ', 106 "), the electronics ( 104) is formed as organic electronics and the display (106, 106 ', 106 ") is printed on the carrier element (102), is irreversibly changeable and has at least one electrochromic element, and that the display (106, 106', 106" ) is configured so that an electrical pulse of the electronics (104) causes an electrochemically induced spectroscopic change of the at least one electrochromic element of the display (106, 106 ', 106 "), which is irreversible and visually indicates a state of the sensor module (101) , Sensor module (101) according to claim 1,
characterized,
that the display (106, 106 ', 106 ") having a plurality of electrochromic elements, and is designed so that different electrochemically induced, spectroscopic changes can be effected by a pulse of the electronics (104) at the plurality of electrochromic elements, whereby a text (107 ) can be generated on the display (106, 106 ', 106 ") representing a state of the sensor module (101). Sensor module (101) according to one of claims 1 and 2,
characterized,
that the display (106, 106 ', 106 "), one or more electrochromic elements and is configured so that by a pulse of the electronics (104) the same electrochemically induced, spectroscopic change in the one or more electrochromic elements can be effected, whereby a color change of the entire display (106, 106 ', 106 ") can be generated is. Sensor module (101) according to claim 3,
characterized,
that in addition to the at least one display (106, 106 ', 106 ") a text (107, 107', 107") is printed, which visually reproduces the state of the sensor module (101). Sensor module (101) according to claim 4,
characterized,
in that a plurality of displays (106, 106 ', 106 ") are mounted on the carrier element (101), and next to each display (106, 106', 106") is printed a text (107, 107 ', 107 ") which contains the State of the sensor module (101), the texts (107, 107 ', 107 ") are different. Sensor module (101) according to one of claims 1 to 5,
characterized,
that the electronics (104) and / or the sensor (103) on the carrier element (102) are printed. Sensor module (101) according to claim 6,
characterized,
in that the electronics (104) and / or the sensor (103) are printed on the carrier element (102) by screen printing. Sensor module (101) according to one of claims 1 to 7,
characterized,
that an energy source (105) is part of the electronics (104). Sensor module (101) according to one of claims 1 to 8,
characterized,
that the sensor (103) is formed as a temperature sensor. Sensor module (101) according to one of claims 1 to 9,
characterized,
that the sensor module (101) comprises a memory in communication with the electronics (104) and an RFID transponder, wherein contactlessly read out from the memory on the RFID transponder. Method for monitoring at least one predetermined desired value of a measured variable with a sensor module (101) according to one of Claims 1 to 10,
characterized,
in that the electronics (104) transmit an electrical pulse to the at least one display (106, 106 ', 106 ") for displaying a state of the sensor module (101), said electrical pulse being an electrochemically induced spectroscopic change of the at least one electrochromic element of the respective one Display (106, 106 ', 106 ") which is irreversible and indicates a state of the sensor module (101). Method according to claim 11,
characterized,
that the electronics (104) of the sensor module (101) comprises means for detecting the overshoot and / or undershooting of a target value of the measured variable and means for generating an electrical alarm pulse in case of overshoot and / or undershooting of this setpoint, the electronics (104) a thus generated alarm pulse to the at least one display (106, 106 ', 106 ") transmitted, which causes the electrochemically induced spectroscopic change of the at least one electrochromic element of the at least one display (106, 106', 106"). Method according to one of claims 11 and 12,
characterized,
in that the electronics (104) of the sensor module (101) have means for starting the measuring operation of the at least one sensor (103) and for generating an electrical starting pulse, the electronics (104) sending an electrical starting pulse thus generated to the at least one display (106, 106 ', 106 "), which effects the electrochemically induced spectroscopic change of the at least one electrochromic element of the at least one display (106, 106', 106"). Method according to one of claims 11 to 13,
characterized,
in that the electronics (104) of the sensor module (101) have means for canceling the measuring operation of the at least one sensor (103) and generating an electrical break-off pulse, the electronics (104) sending an electrical break-off pulse thus generated to the at least one display (106, 106 ', 106 "), which effects the electrochemically induced spectroscopic change of the at least one electrochromic element of the at least one display (106, 106', 106"). Method according to one of claims 11 to 14,
characterized,
in that the sensor module (101) is designed in accordance with claim 5 and an alarm pulse, a start pulse and a termination pulse are respectively transmitted from the electronics (104) to different displays (106, 106 ', 106 ") of the sensor module (101).

Images