WO2019144995A1 - Device and method for an energy-autonomous detection and transmission of vibration measurement data and system state information, and use thereof - Google Patents

Abstract

The invention relates to an energy-autonomous vibration measurement device (10) which is designed to detect vibration measurement data of a device (1), for example a container, in an energy-autonomous manner, comprising an energy store (17) for an autonomous energy supply; an energy receiving unit (15) which is designed to supply energy harvested from the surroundings to the energy store; and additionally a communication module (14) which is coupled to the energy store and which is designed for a wireless energy-autonomous transmission of the vibration measurement data on the basis of at least one communication protocol. The vibration measurement device (10) is designed for an energy-autonomous detection and transmission of vibration measurement data in the form of structure-borne sound measurement data detected on a solid body surface (2.1) of the device (1) to be measured, wherein the vibration measurement device has a computing unit (18) and is additionally designed for an energy-autonomous analysis of the detected structure-borne sound measurement data with respect to a fill state (z7) of liquid or solids (7) in an inner volume (6) delimited by the device. In this manner autonomy is ensured. A self-diagnosis can also be carried out. The invention additionally relates to corresponding methods and applications.

Description

 Device and method for self-sufficient detection and transmission of vibration measurement data and system state information and use

TECHNICAL AREA

 The present invention relates to a device and a method for self-sufficient detection of vibration measurement data on a device to be measured, for example, on a container, wherein by means of a communication module an energy self-sufficient wireless transmission of the vibration measurement data or system state information based on an evaluation of the vibration measurement data can be carried out, in particular in each case over comparatively long periods of several months or even years. In this way, system state information can be provided energy self-sufficient and wireless, in the sense of a remote diagnosis. Last but not least, the present invention also relates to a corresponding use. In particular, the invention relates to an apparatus and a method according to the preamble of the respective independent claim.

BACKGROUND OF THE INVENTION

 The most self-sufficient, fully automatic monitoring or diagnosis of any devices, in particular receptacles or machines or machine elements, is becoming increasingly important in the context of digitization, not only in industrial applications, but also in domestic applications (home use) or in public space. Particularly interesting fields of application for corresponding sensor systems include: fill level measurements in containers, e.g.

containers; Diagnosis of operating states of installations or rotating machines, in particular pumps; Fault diagnosis based on sound analysis.

It is no longer unusual today for the sensors to be specially designed for the

Monitoring autonomously over several months, whereby a transmission of measured values to a database system can take place even if large distances have to be bridged. If necessary, then a local radio Kommunikaüons infrastructure is no longer necessary. One of the practical advantages in an application for containers (empties or the like) consists e.g. The fact that the containers only need to be emptied when a critical level is reached, or as soon as possible. The logistical effort can be minimized. This is particularly interesting for large logistics service providers, who do not see a container inventory in the range of several million pieces to look after.

As a practical example of established sensor technology, the monitoring box usually provided for overseas containers in shipping can be cited. In addition position data can use it

For example, system states such as "container open" or the time of system changes are recorded and archived. The arrangement on the container takes place in particular in the region of the door in order to be able to detect an actuation of the door in a mechanical manner. To extend the duration of autonomous operation, for example, even in complete darkness, measures have already been taken to reduce the energy requirements of the sensor, or to allow self-sufficient desserts of energy from the environment, for example by means of solar modules. Such measures can be summarized, for example, under the keyword "Micro Energy Harvesting". A more or less autonomous mode of operation is nowadays already feasible in some cases, if a recharge can take place over a period of, for example, ten hours and a light irradiation of 20,000 lux (corresponding to the light irradiation on a covered summer day).

However, not only a design of the solar module and / or the respective energy storage device with a safety factor is expedient, but also measures with regard to energy-optimized control of the operating behavior. In particular, measures may be mentioned: controlling the energy balance and operating mode of the sensor based on a current state of the energy storage; and / or variably adjusting the transmission interval of the sensor, in particular as a function of the available energy; and / or operating mode as a function of the currently possible energy supply: in the event that no energy is produced (for example in the dark), an operating mode with a minimum energy requirement is selected.

Of course, the advantages mentioned above should be achievable in as many applications as possible, regardless of the type of sensor technology. In many cases, a specific designed or adapted sensor is required for a given application, especially since the way of acquiring measurement data has to be optimized or adapted in a specific way to the application, or because a narrow cost framework must be adhered to. Example: Optical detection of the fill level in containers, or evaluation of ultrasonic readings to determine the volume of the remaining cavity of a container filled with liquid. In fact, the collection and evaluation of level information in containers is a wide field; Numerous different measuring methods have already been established, including gravimetric and optical methods, but not all of them are particularly well suited for implementation in connection with sensors with as high a degree of autarchy as possible. The respective energy consumption can even become an exclusion criterion for one of these measurement techniques.

WO 2005/066592 A1 describes a device for evaluating ultrasonic waves that must be generated artificially in a container wall. For the detection of fluid levels, the

corresponding vibrations, for example generated in the frequency band 30 to 150 kHz, within the

Container wall forwarded and detected after a certain distance. Depending on the level results in a specific way of forwarding the vibrations in the container wall. The distance should be as far as possible at least approximately full, and the propagation direction should be in the vertical direction. The type of detection is determined by the sensors used (so-called "vibration-to-signal transducer" or "air transducer", for example, pulsed laser and

Magnetic coils called usable sensors). The detection is carried out in particular based on the amplitudes of the vibrations, wherein two sensors are attached to a lid of the container. WO 2012/158371 A2 describes a method for analyzing acoustic sound responses from a container, for determining the fill level in the container. In this case, a specific sound pattern is generated by means of a plurality of sensors in relative arrangement to one another. The evaluation can be carried out in particular in an optical manner.

WO 2017/137832 A1 describes camera sensors for detecting the fill level in containers, which, thanks to visual contact with the container interior, can visually create a 3D model thereof in comparatively high quality.

JP 2016-020883 A describes a system of self-powered sensors for monitoring and diagnosing the condition of a building or other large structure and in particular ensuring a sufficient power supply of all sensors. The energy supply is via a solar cell.

WO 2014/108206 A1 describes a self-sufficient sensor system with sensor, transmitter unit, self-sufficient energy source and control unit. The latter regulates the performance of measurements and the

Data transmission, in particular depending on the amount of energy provided. The current energy generated by the energy source is taken as the basis for the regulation. In a first step, measurements are stopped. Optionally, a decoupling can be done by the network.

If the degree of independence (self-sufficiency) of the sensors is to be increased further, in many cases special measures regarding the energy balance are required. Especially with the use of solar modules, one difficulty is to be able to use very low energy contents (e.g., heavily overcast sky, low solar radiation, unfavorable orientation of the solar module) to charge an energy storage device. In many situations, the amount of energy delivered by the solar module is insufficient to initiate a charge. A related measure is to first charge a capacitor by means of the solar module in order to provide a minimum charge pulse for charging the battery can. This measure is also realized to avoid self-discharge (so-called "trickle charging").

However, the hitherto available technology can not yet meet satisfactorily the requirements for self-sufficiency (in particular with regard to the desired duration) as well as the flexibility with regard to the possible applications. There is therefore a need for universal as possible in various applications usable sensors, which can ensure a reliable, reliable diagnosis on the one hand, on the other hand is highly autonomous, and requires little or no maintenance, possibly over many years. Last but not least, this would also allow an application in locations that are geographically / geometrically or geographically difficult to access. Last but not least, there is a certain cost if the sensor is to be used for example to equip any container or even any garbage bin.

SUMMARY OF THE INVENTION

 The object is to provide a device and a method with which self-sufficient measurements and diagnoses on devices, machines, installations or devices of any kind can be facilitated, based on a recording and evaluation of vibration data. It is also an object to configure the device and the method such that little maintenance is required on the device or on the device to be monitored, and that a high degree of self-sufficiency of the measuring technology can be ensured. Last but not least, it is an object to provide apparatus and methods for a wide range of applications, in particular also with regard to level measurement with a high degree of self-sufficiency, in particular on containers.

At least one of these objects is achieved by an energy self-sufficient vibration measuring device according to claim 1 and by a method according to the respective independent method claim. Advantageous developments of the invention are explained in the respective subclaims. The features of the exemplary embodiments described below can be combined with one another, unless this is explicitly denied.

An energy self-sufficient vibration measuring device is provided for energy self-sufficient acquisition of vibration measurement data on a device to be measured, in particular on a container, with at least one energy storage for self-sufficient energy supply of the vibration measuring device, in particular over a self-sufficient energy period of at least six months or optionally at least five years, and equipped with at least one energy absorption unit for feeding energy harvested from the environment into the energy store, and further equipped with at least one communication module coupled to the energy store for energy-autonomous wireless transmission of the

Vibration measurement data based on at least one communication protocol, in particular from the group of LP WAN (Low Power Wide Area Networkj protocols, in particular based on SigFox and / or NBIoT.

 According to the invention it is proposed that the vibration measuring device is set up for

Energy self-sufficient acquisition and transmission of the vibration measurement data in the form of

Body vibration measurement data (data regarding vibrations or vibrations of bodies, in particular structure-borne noise) is recorded on a solid surface of the device to be measured, wherein the

Vibration measuring device has a computing unit and is further adapted for energy self-sufficient evaluation of the detected body vibration measurement data with regard to at least one system state of the device to be measured, in particular with regard to a system state in an area bounded by the device interior volume, in particular with regard to a level of liquid or solids in Interior volume, especially designed for evaluation exclusively based on the

Body vibration measurement data. This provides a high degree of self-sufficiency in monitoring the corresponding facility. The detection of body vibrations can be carried out in particular as reactive detection in response to external effects / causes of the body vibrations.

By means of the vibration measuring device, a detection of vibrations can take place, for example during filling (impact impulses) and / or when opening a container (in particular also vibrations caused by opening / closing a flap of the container). This vibration or vibration measured value can be evaluated for determining the fill level (liquid and / or solids), in particular also by means of self-learning algorithms.

The diagnosis can optionally already based on an evaluation exclusively the

Vibrations / vibration emissions occur, which occur during manual operation of the container and / or when filling with fluids or solids. Active generation of certain vibration patterns or vibrations is not required. In other words, the vibration measuring device may remain passive in terms of vibration propagation. This reduces the complexity of the measuring arrangement and also allows a high degree of self-sufficiency. Since the measurement is based on externally generated vibration, e.g. caused by throwing in solids (e.g., bottles, glass, paper, mixed waste), the process can be carried out without its own active stimulation / vibration generation. The vibration measuring device is only active for detecting oscillations or vibrations and for transmitting data.

In particular, a measurement of strength, frequency and / or duration of the body vibrations or the vibrations can take place. Furthermore, the device may be configured to detect the movements of the substances when filling the container with the substances, in particular in a mounting position of the device on a lid of the container. Optionally, an optical and / or acoustic detection unit, in particular a camera device may be provided, in particular for the initial, one-time training of at least one self-learning algorithm. An optical and / or acoustic detection can be provided in an application-specific manner in addition to the detection of the vibration measurement data.

The evaluated data can then be transmitted based on a low-energy communication technology, in particular time-controlled and / or event-controlled. The used

Communication protocol may in particular be based on a LoRaWAN (Long Range WAN) protocol.

According to the invention, energy-intensive types of measurement data acquisition can be dispensed with, and also the transmission can take place in an energy-optimized manner. In particular, the accurate, but energy-intensive ultrasound technology does not have to be used. Independently of this, one of the already proven, accurate measurement technologies may be additional or e.g. for calibration purposes or when installing and

Commissioning of the vibration measuring device can be used. The vibration measuring device is preferably understood to mean a device which functions separately from any auxiliary means and which is set up both to record the measured data and to evaluate and transmit it. As self-sufficient energy is understood to mean a functioning without supply of energy from third parties or other devices. In this case, harvesting of energy from the environment can be carried out by the device itself, in particular by means of solar modules.

As a body vibration is a vibration, vibration or other movement of a solid to understand (state of matter = solid). Thus, body vibration does not involve vibration of fluids caused by acoustic sound. However, a body vibration may include a vibration caused by acoustic sound or vibration of a solid (structure-borne sound).

The body vibration measurement data are the data characterizing the body vibrations. Therefore, body vibration measurement data are also those data which are obtained and evaluated as measurement data from the vibrations of bodies which generally occur in the respective application and optionally also from the associated noise developments (sound emission), which can also cause a corresponding body vibration.

As the device to be measured is preferably any means (in particular open or closed container) for receiving substances or for the arrangement of e.g. Understand machine elements that defines an internal volume, which internal volume can also form a certain resonance volume.

By means of the communication module, a transmission of the body vibration data over the self-sufficient period, in particular at predefined times, and / or as a function of an energy content of the accumulator. The communication module may be configured to communicate based on a plurality of protocols, in particular including at least SigFox and NBIoT. The communication module can be set up to use at least one narrow-band wireless communication standard, in particular several LP WAN (Low Power Wide Area Network) standards. LP-WAN standards are characterized by low bandwidth and low power consumption. Sigfox is based on LoRaWAN (Long Range WAN) technology. NBIoT uses existing mobile technology, in particular LTE technology. The Sigfox technology is used in particular for the transmission of comparatively small amounts of data and has already been used for some time for e.g. Modules used the location of

Can specify shipping containers. It has now been shown that the Sigfox technology also in the

Connection with the detection and processing or transmission of relatively complex data / data sets can be used, in particular by means of the vibration measuring device, a preprocessing of Schwingungsrohdaten with respect to a preselection and optionally also

Data compression takes place. The body vibration measurement data may have been produced in an internal volume of the device to be measured, in particular during / through the insertion or filling of contents. The resulting vibrations propagate in the inner volume and are transmitted to the wall. By detecting (body) vibrations in the wall can be deduced the state in the internal volume. A corresponding correlation can be optimized in particular also with the aid of self-learning algorithms.

The vibration measuring device has at least one energy absorption unit (harvesting module) configured for feeding energy harvested from the environment into the energy storage device (accumulator). The harvesting module preferably has at least one module from the following group: Solar module (comprising at least one solar cell) arranged to feed energy harvested from natural and / or artificial light radiation; piezoelectric module.

The system state is preferably a state from the following group: operating state (eg full load operation, partial load operation, off, open, partially open, closed), noise behavior (normal expected standard noise, increased noise emission), level (in particular empty, partially filled, filled up to a predefinable threshold, more than 3/4 filled, full), power supply. The

System state can also be characterized by several types of these states: e.g.

Operating condition (e.g., open flap container), level, and / or noise behavior. For example, a sensor for detecting the position of the flap may be provided on the container, which sensor is in communication with the vibration measuring device or integrated therein.

The fill level can refer to a fill level in an inner volume bounded by the device to be measured, in particular to a fill level in a completely hollow cavity. The device may have any geometry. The device may consist of any material, for example with metallic wall or plastic wall. The contents may have any composition and be solid and / or liquid. In devices in which only fluids are taken up, a vibration can be detected, in particular, when an external excitation occurs, e.g. by opening or closing a lid or filler neck, or controlled by a controllable actuator (vibration generator).

The SigFox communication protocol is a communication protocol based on ultra-narrowband technology, also known as LPWAN (low-traffic network), which enables radio connectivity for the Internet of Things (IoT), in particular independently of existing networks.

It has now been found that an application for various types of facilities is possible, in particular for recycling containers, trough containers, settling and roll-off containers, overseas containers, either with or without cover, with or without fixed openings. Furthermore, it has been found that such a device can be realized comparatively inexpensively.

The arithmetic unit can be provided separately (in the manner of a downstream computer system, in particular decoupled from the acquisition of the measurement data), or be integrated into a sensor system for acquiring the measurement data.

The term "reactive grasping" became consciously here in contrast to the capture of actively artificial

(in particular according to predefined patterns) generated body vibrations selected. The self-powered device is arranged according to the invention to carry out the detection and evaluation independently of any artificially actively excited, induced vibrations or oscillations. An energy supply to the active, artificial generation of vibrations or sound is therefore not required according to the invention.

The device according to the invention or the method according to the invention can also have at least one acoustic vibration sensor, or it can be a detection and evaluation of acoustic

Include vibrations (sound). This additional data base may make the vibration evaluation even more accurate, or may extend the scope of the analysis.

In particular in connection with a calibration or for the plausibility check, comparative measurements can also be carried out, in particular ultrasound measurements or evaluations. For this purpose, preferably a short time interval is used at the very beginning of the commissioning. In particular, thanks to such comparison measurements, a neural network can be trained, in particular in the form of a one-time training of algorithms, initially in a data logger phase.

According to one exemplary embodiment, the vibration measuring device is set up for energy-autonomous reactive detection of the vibration measurement data with respect to vibration propagation passive

Vibration measurement device. The energy self-reactive detection can without active / active

Generation / generating vibrations take place. This provides a particularly high degree of self-sufficiency.

According to a specific embodiment, at least one of the aforementioned objects is achieved by an energy self-sufficient vibration measuring device configured for self-sufficient detection of energy

Vibration measurement data to a device in the form of a container, with an energy storage for self-sufficient energy supply of the vibration measuring device over a self-sufficient energy period of at least six months, and equipped with an energy absorption unit for feeding energy harvested from the environment into the energy storage, and further with a to the energy storage coupled

Communication module configured for energy self-sufficient wireless transmission of the vibration measurement data based on at least one communication protocol from the group of LP-WAN protocols, in particular based on SigFox and / or NBIoT; wherein the vibration measuring device is set up for self-sufficient detection and transmission of the vibration measurement data in the form of Body vibration measurement data recorded on a solid surface of the device to be measured, wherein the vibration measuring device is set up for energy self-reactive detection of the

Vibration measurement data with respect to vibration propagation passive vibration measuring device, wherein the vibration measuring device has a computing unit and is further adapted for energy self-sufficient evaluation of the detected body vibration measurement data with respect to a level of liquid or solids in an area bounded by the device interior, in particular designed for evaluation exclusively based on the body vibration measurement data. This embodiment is especially advantageous for level measurement.

According to one exemplary embodiment, the vibration measuring device has a mechanical interface designed as a body vibration coupling (designed for stationary mounting or for stationary coupling to the device or to a fastening point of the device provided for this purpose) and is configured to detect the body vibration measurement data in a non-optical manner (By solid state contact or by the transmitted due to solid contact vibrations), in particular exclusively in a non-optical manner via the body vibration coupling or corresponding, in connection with the body vibration coupling sensor, especially in a mounting position outside of the solid surface For example, on a container or container or

Maschinengehäusewandung. This also provides advantages in terms of application spectrum and mounting options.

As a body vibration coupling, a clutch is preferably arranged for forwarding

Understand body vibrations, so a coupling that allows attachment largely without damping or Fedemng. The body vibration coupling is adapted to be in solid state contact with the device to be measured. In this case, the vibration measuring device may have at least one connected to the body vibration coupling body vibration sensor, in particular in a rigid arrangement, optionally integrated into the body vibration coupling. This allows detection with minimal dissipation or minimized losses, with minimized attenuation. This can increase the accuracy or even expand the field of application, in particular also with regard to weak vibrations or with respect to devices / containers which are e.g. only be filled with materials of comparatively small mass (e.g., paper, cardboard).

According to one exemplary embodiment, the vibration measuring device is designed to detect body vibration measurement data by means of the body vibration coupling in a solid-body contacting arrangement on the outside of the device, outside of an interior volume defined by the device, in particular without a view of the interior volume, in particular on a wall of the device. This not least provides a high degree of flexibility with regard to the arrangement or with regard to the monitored

Facilities, eg also of machine housings. According to one embodiment, the body vibration coupling has a body vibration guide surface adapted for the material-fit, in particular adhesive Fixiemng on the device. This can optimize the interface. According to one embodiment, the body vibration coupling

Fastening means adapted for reversible positive and / or non-positive mounting on the device. This too can optimize the interface to the device.

According to one embodiment, the body vibration coupling comprises fastening means comprising at least one screw connection. This provides a robust connection and great freedom of fixation on the device.

 According to one embodiment, the body vibration coupling comprises fastening means comprising at least one rivet, in particular blind rivet (see Pop rivet). It has been found that a rivet can easily ensure a very stable, surface contacting attachment. This type of attachment also has the advantage that body vibrations are hardly or not noticeably dissipated.

 According to one embodiment, the body vibration coupling comprises fastening means comprising at least one irreversible or reversible adhesive bond. It has been shown that a bond is very easy to perform. A bond provides in particular also the advantage that the attachment point can be largely freely selected, and that no holes or the like are required on the device.

According to one exemplary embodiment, the body vibration coupling has an at least sectionally planar, planar body vibration guidance surface arranged for the areal absorption and transmission of body vibrations of the device, in particular geometrically corresponding to the device.

 According to one exemplary embodiment, the body vibration coupling has a body vibration guidance surface configured for surface contacting of the device. This allows each a suitable coupling. According to one embodiment, the body vibration guide surface is rigidly connected to at least one attachment means of the body vibration coupling. This can optimize the recording and transmission of the vibrations.

With regard to the type of attachment is worth mentioning that there are preferred variants depending on the type of device to be measured. It has been shown that a metrological measurement and evaluation can be largely independent of the type of attachment, in particular because the evaluation can be focused on differential readings or relative changes. Any influences of the manner of attachment, e.g. dampening effects on a bond can then be more or less ignored; arithmetically, such effects do not necessarily have to be taken into account if the evaluation can be focused on a temporal change of the measured values.

According to one exemplary embodiment, the vibration measuring device is set up for self-sufficient detection and evaluation of body vibration measurement data from vibrations or vibrations of the body Device, in particular of vibrations with respect to at least two spatial axes, preferably from

Vibrations with respect to all three spatial axes. This can also optimize the scope of the measurement.

According to one embodiment, the body vibration clutch is configured to detect the body vibration measurement data from vibrations with respect to at least two spatial axes, preferably vibrations with respect to all three spatial axes, non-optically via the body vibration clutch and at least one with the body vibration clutch rigidly connected

Body vibration sensor, in particular a body vibration sensor with sensitivity in all three spatial axes, in particular microelectromechanical (MEMS-based) body vibration sensor. This not least provides metrological advantages. The sensitivity with respect to all three spatial axes also has the advantage that metrological redundancy is not necessarily required. This also allows robustness and cost efficiency. The body vibration sensor may be e.g. be connected by means of rigid, non-damping connecting means or connectors with the body vibration coupling or integrated or embedded therein.

According to one embodiment, the vibration measuring device has at least one

Body vibration sensor, in particular an accelerometer, in particular in a relative arrangement for body vibration coupling or in a rigid relative arrangement to Körperschwingungsleitfläche, in particular coupled by means of a rigid connecting element (in particular with minimized damping, for example, a metallic connecting element).

 According to one embodiment, the vibration measuring device has at least one

Body vibration sensor, in particular an accelerometer set up to detect the

Body vibration measurement data with respect to at least two spatial axes, preferably with respect to all three spatial axes. The accelerometer need not necessarily be arranged in a specific relative position in the sensor or relative to the mounting position or coupling point or attachment point;

Optionally, a corresponding optimization can take place, depending on the application. Likewise, that needs

Accelerometer should not be embedded in a predefined way in the sensor. Also do not have to

necessary precautions are taken to avoid dampening. These advantages result in particular from the fact that the evaluation can be focused on a temporal change of the measured values, ie on an analysis of temporal changes and difference measured values. The time interval is not fixed, it can refer to a single filling process, or even to a period of several hours, days, weeks or months.

As an accelerometer or acceleration sensor can be provided in particular:

microelectromechanical (MEMS based) sensors; piezoelectric sensors; or a combination of them. It has been shown that MEMS-based sensors provide particular advantages, in particular with regard to energy requirements and a broad spectrum of detectable oscillations, not least also with regard to costs. According to one exemplary embodiment, the vibration measuring device has at least one body vibration sensor comprising a sound conversion unit, in particular a MEMS microphone. In other words, it is also possible to provide a sound conversion unit with regard to acoustic vibrations. This can optionally extend the scope of the analysis. In particular, it can

Plausibility checks are facilitated or noise is eliminated.

According to one embodiment, the energy absorption unit comprises at least one solar module and / or at least one piezoelectric module. As a result, the supply of energy may also be caused by ambient light or e.g. take place during relative movements.

 According to one embodiment, the vibration measuring device, in particular the computing unit is set up, the manner of the transmission, in particular times for the transmission, in

Specify dependence on the energy content of the energy storage and / or the energy flow in the energy storage. This can further increase the autarky degree. In particular, the energy supply can be ensured over a longer period of time. In this case, an input / output calculation can take place, in particular in the form of an energy balance.

According to one exemplary embodiment, the arithmetic unit is set up to define a transmission interval based on the energy provided by the energy absorption unit and / or based on a state of charge of the energy store. This enables a resource-saving handling of the available energy. The state of charge is an energetic state of the energy store, wherein the state of charge is defined based on a subdivision according to the following group: empty, state of charge at least sufficient for transmission, state of charge at least sufficient for detection and / or evaluation, state of charge at least sufficient for maintenance (connectable), full.

According to one exemplary embodiment, the vibration measuring device has a light sensor and is set up to quantify the amount of energy provided by the energy absorption unit or the energy flow into the energy store. This facilitates setting and optimizing the operating state of the vibration measuring device, also as a function of current environmental influences.

 According to one exemplary embodiment, the arithmetic unit is set up to adapt a transmission interval as soon as the voltage applied to the energy store changes, in particular by setting a change rate for the voltage over the distance to a predefined / predefinable target voltage

Transmission interval is given. This optimizes the use of available energy and operation as a function of available energy.

 According to one embodiment, the vibration measuring device is set up in a

to switch energy demand reduced (or energy minimized) deep sleep mode or at least suspend the transmission and / or detection when no energy is provided by means of the energy absorption unit. This allows energetic Optimiemngen. As deep sleep mode, for example, a standby state can be understood. According to one exemplary embodiment, the arithmetic unit is set up, based on a charge measurement, in particular by means of a Coulomb counter, to carry out an input / output calculation in the manner of an energy balance on the energy store. This also allows for energetic optimizations, thereby increasing the level of autarky.

The transmission interval (Advertisement Interval, AI) does not have to be firmly defined, but can iteratively be adapted to the energy (energy content) provided by means of the energy absorption unit or the energy store. In this regard, a light sensor can also be used, in particular to measure the energy that is produced in the energy absorption unit. By means of an ADC converter, the am

Energy storage voltage to be measured, from which the state of charge / energy content can be determined. The AI can be adjusted (shortened or extended) when the voltage changes. The distance to the target voltage can be used to specify a rate of change with which the AI is adjusted. In the event that no energy is produced (e.g., darkness), the vibration measurement device may be placed in a deep sleep mode, or at least the transmission may be suspended, in particular until a time when energy is re-injected into the energy storage.

According to one embodiment, the vibration measuring device is set up, the transmission in an energy demand optimized, as "non-connectable" defined state (active state without

Maintenance option) (or transmit a corresponding signal).

 According to one exemplary embodiment, the vibration measuring device is set up to switch into a "connectable" state for configuration (condition with possibility of maintenance), in particular as a function of a current energy content of the energy absorption unit, in particular out of a deep sleep mode. According to one exemplary embodiment, the vibration measuring device comprises a light sensor and is set to switch to a predefined / predefinable threshold value during irradiation in a "connectable" state, in particular for a predefined period of time, in particular as a function of a current energy flow from the energy absorption unit.

 According to one embodiment, the vibration measurement device is arranged to switch from a deep sleep mode to a connectable state in response to at least one external influence, wherein the external influence is defined / definable at least from the following group: non-contact activation through a magnetic field, NFC

(Nahfeldkommunikations) compound. This also enables an optimized energy budget.

The vibration measuring device transmits / transmits the corresponding signal (advertisement), in particular in a state defined as "non-connectable". If the vibration measuring device is to be configured, that is to say placed in the "connectable" state, in which state a higher energy requirement exists, the light sensor can be irradiated by means of an artificial energy source, eg by means of the flashlight of a smartphone. Only when a defined lighting limit is exceeded, the vibration measuring device is set in the "connectable" state and remains in this state, for example for a minute or as long as a device is connected to it. The state of the vibration measuring device is to be understood as a state which is adjustable and can be decisive for the adjustable operating behavior of the vibration measuring device

(in particular depending on the state of charge), wherein the state of the vibration measuring device is defined, for example based on a subdivision according to the following group:

Deep sleep mode, "non-connectable", "connectable". In "non-connectable" or "connectable" mode, the vibration measuring device can each be set up or be adjustable for at least one of the following steps: detection, evaluation, transmission. Depending on the selected state, an energy requirement state can be set, which energy requirement state can be a specification for the way of feeding energy and / or the manner of detecting, evaluating and / or transmitting steps, in each case adjustable by means of the arithmetic unit or by means of a corresponding computer program product or a corresponding control unit. For example, at least three for the level measurement

Energy demand states defined, and the (operating) state of the vibration measuring device is adjustable depending on the respective state of charge. This can avoid that the energy storage is unfavorably discharged for measurements / transmissions, which may not even be necessary. This in turn increases autarky.

ITEM1 At least one of the aforementioned tasks is also solved by an energy self-sufficient

Vibration measuring device set up for energy self-sufficient recording of vibration measurement data on a container, with an energy storage for self-sufficient energy supply of the vibration measuring device over a self-sufficient energy period of at least six months or even several years, and equipped with an energy absorption unit for feeding energy harvested from the environment into the energy storage, and further comprising a communication module coupled to the energy store for energy-autonomous wireless transmission of the vibration measurement data based on at least one communication protocol from the group of LP-WAN protocols; wherein the vibration measuring device is set up for self-sufficient detection and transmission of the vibration measurement data in the form of body vibration measurement data recorded on a solid surface of the device to be measured, wherein the vibration measurement device is adapted for self-sufficient reactive detection of

Vibration measurement data with respect to vibration propagation passive vibration measuring device, ie without active / active generation / generation of vibrations, wherein the vibration measuring device has a computing unit and is further configured for energy self-sufficient evaluation of the detected

Body vibration measurement data with regard to a level of liquid or solids in an area bounded by the device interior volume, in particular exclusively based on the

Body vibration measurement data, wherein the vibration measuring device at least one

Body vibration sensor, in particular an accelerometer and is adapted to detect the body vibration measurement data from vibrations of the container with respect to at least two spatial axes x, y, z, preferably from vibrations with respect to all three spatial axes, in a non-optical manner, wherein the vibration measuring device, in particular the arithmetic unit is preferably also set up, the manner of the transmission, in particular times for the transmission and / or a transmission interval, in Define dependence on the energy content of the energy storage and / or the energy flow in the energy storage. This provides many of the aforementioned benefits.

As mentioned above, at least one of the aforementioned objects is also achieved by a device, in particular a container, with at least one energy-self-sufficient, previously described vibration measuring device attached to it, wherein the vibration measuring device is arranged on the outside of a wall of the

Device is attached, in particular without visual contact in a wall bounded by the inner volume. This provides the aforementioned advantages. In particular, the facilities may independently request a service, e.g. an emptying or a diagnosis or repair. This not least reduces the

Maintenance. A most advantageous position on the outside of the device can be selected individually depending on the application.

As mentioned above, at least one of the aforementioned objects is also achieved by a method for energy self-sufficient operation of a vibration measuring device for energy self-sufficient provision of

System state information, in particular level information, with respect to at least one of several system states of a device to be measured, in particular a container, by energy self-sufficient detection of body vibration measurement data at the device, in particular by means of a previously described self-powered vibration measuring device, wherein a self-sufficient power supply is provided for the purpose of providing the system state information by using at least one

Energy intake unit of the vibration measuring device energy harvested from the environment and is fed into at least one coupled to the energy storage communication module of the vibration measurement device energy self-sufficient wireless transmission of body vibration measurement data based on at least one communication protocol, in particular from the group of LP-WAN Protocols, in particular based on SigFox and / or NBIoT; wherein an energy self-sufficient detection of the body vibration measurement data on a solid surface of the device to be measured is carried out, and further wherein an energy self-sufficient evaluation of the detected body vibration measurement data with respect to the at least one system state, in particular with regard to a system state in a bounded by the device

Internal volume, in particular with regard to a level of liquid or solids in the inner volume, the body vibration measurement data are transmitted energy self-sufficient wireless. This provides the aforementioned advantages. The detection can take place in a non-optical manner via a mechanical interface comprising a body vibration coupling, via which the vibrations can be forwarded as undamped as possible without dissipation. The evaluation takes place in particular taking into account a temporal

Development (difference formation), in particular also by means of at least one self-learning algorithm. The transmission takes place in particular based on SigFox and / or NBIoT.

It has been shown that the evaluation can be based on relative measured values and measured value changes or difference formation. The system of device and vibration measuring device can be regarded or defined as a vibration system, in which vibration system, the mechanical Intersection between the device and the vibration measuring device can be regarded as a constant, that is, as in terms of the propagation of vibrations or (body) sound not further noteworthy interface. The vibration measuring device can resonate with the device or detect (body) sound waves independently, so that the evaluation on the evaluation of temporal

Changes, relative values and difference formation can be focused. Absolute measurement data can be neglected or, compared to relative measurement data, at least subordinate to the evaluation.

According to one embodiment, the detection is reactive with respect to vibration propagation passive vibration measuring device without active generation of vibrations. This provides a particularly high degree of self-sufficiency.

According to one embodiment, the body vibration measurement data are detected in a non-optical manner, in particular exclusively in a non-optical manner, in particular by means of at least one

Body vibration sensor of the vibration measuring device. According to one embodiment, the body vibration measurement data are detected by means of the body vibration coupling in a body contacting arrangement on the outside of the device, outside of an interior volume bounded by the device, in particular without view into the interior volume. According to one embodiment, the

Body vibration measurement data mitels detected by at least one vibrationally conductive connection to the device coupled body vibration sensor. This provides each of the aforementioned advantages.

According to one embodiment, the self-sufficient detection is performed in a time interval of at least ls. This also allows the detection of a time course.

 According to one embodiment, the self-sufficient detection is performed in a time interval of a maximum of 10 seconds. According to one embodiment, the self-sufficient energy acquisition is carried out at individual time intervals of a few seconds in each case, in particular 1 to 10 s, over a period of at least 1 to 6 days, weeks or months. This enables a resource-saving mode of operation. In this case, a difference can also be facilitated by the fact that the individual time intervals are only a few seconds apart. For example, if a container is filled with empties (e.g., bottles) for a period of 30 seconds, the detection may be e.g. in three individual time intervals of 3s each in a comparatively small time interval of e.g. only 5s.

 According to one embodiment, the energy-autonomous detection is initiated in a situation-initiated manner by at least one body vibration sensor of the vibration measurement device, in response to

Depending on the situation occurring body vibrations, especially as a function of an exceeded minimum threshold for a vibration intensity. This ensures a resource-saving mode of operation and also prevents the detection of only little meaningful vibrations.

 According to one embodiment, the evaluation comprises a difference formation between the second

Body vibration measurement data and previous, earlier detected earlier

Body vibration measurement data. This provides good resilience of the readings even under adverse conditions. According to one embodiment, a decay behavior of the body vibrations is evaluated, in particular in a time interval of at least 2.5 s (seconds). This can extend the scope of the analysis. In this case, a reaction time of the body vibration sensor in the range of 2 ms can be expected, ie a time which is required for switching from simple monitoring (in particular standby mode) with respect to incident vibrations into an operating mode for acquiring / recording the vibration data. According to one embodiment, the energy-autonomous transmission takes place in each case after a time interval which is defined as a function of the current energy content of the energy store

and / or wherein the energy-autonomous transmission takes place only when the energy content of the energy store exceeds a predefinable minimum threshold value. This optimizes the energy budget.

Regardless of the period / time interval set for detection, permanent monitoring of the presence of vibration may be made, particularly by sampling or polling a body vibration sensor several times per second. If an oscillation is registered, in particular above a threshold value, the acquisition / recording of the oscillation is started, in particular for the duration of 2.5 s. The self-sufficient detection can take place continuously over several years.

According to one embodiment, the detection takes place by means of at least one body vibration sensor, in particular an accelerometer, arranged for detecting the body vibration measurement data with respect to at least two spatial axes, preferably with respect to all three spatial axes. According to one embodiment, the detection also takes place by means of a sound conversion unit, in particular by means of a MEMS microphone. This provides the aforementioned advantages.

According to one embodiment, the energy is fed into the energy store by means of a solar module and / or a piezoelectric module of the energy absorption unit. According to one

Embodiment, the manner of the transmission, in particular times for the transmission, depending on the energy content of the energy storage and / or the energy flow in the energy storage specified, in particular by means of a / the computing unit or control unit of

Vibration measurement device. This provides each of the aforementioned advantages.

According to one embodiment, the evaluation and the transmission take place as a function of a

Energy content of the energy storage by based on a charge measurement, in particular by means of Coulomb counter set up for data collection and data provision for or in the arithmetic unit, an input / output calculation in the manner of an energy balance on the energy storage.

 According to one embodiment, a transmission interval based on the by means of

Energy input unit provided energy and / or based on a state of charge of the

Energy storage defined. According to one embodiment, the amount of energy provided by the energy receiving unit is quantified by means of a light sensor of the vibration measuring device. According to one embodiment, the transmission interval is adapted as soon as the voltage applied to the energy store changes, in particular by setting a change rate over the distance to a predefined / predefinable target voltage. In one embodiment, the

Vibration measuring device in an energy demand reduced deep sleep mode or suspends the transmission and / or detection at least temporarily when no energy is provided by means of the energy absorption unit. According to one embodiment, based on a charge measurement, in particular by means of a Coulomb counter, an input / output calculation in the manner of an energy balance is performed on the energy store. This provides each of the aforementioned advantages.

These steps can each in particular by means of a computing unit or control unit of the

Vibration measuring device are made.

According to one embodiment, the transmission takes place in an energy-demand-optimized state of the vibration-measuring device that is defined as "non-connectable". According to one embodiment, the vibration measuring device is switched to configure in a "connectable" state, in particular as a function of a current energy content of the energy store, in particular out of a deep sleep mode. In accordance with one embodiment, the radiation measuring apparatus shifts into a "connectable" state (or is switched) during irradiation greater than a predefined / predefinable threshold value, in particular for a predefined period of time, in particular as a function of a current energy content of the energy store. According to one embodiment, in response to at least one external influence, the vibration measurement device switches from a deep sleep mode to a connectable state, wherein the external influence is defined in particular at least from the following group:

Non-contact activation through a magnetic field, NFC connection. This provides each of the aforementioned advantages. In this case, the vibration measuring device may switch from a deep sleep mode to a mode for detecting the vibrations in response to occurring vibrations. Permanent monitoring for incident vibrations allows activation in response to newly occurring vibrations

Vibrations. The monitoring is independent of the step of detection.

As mentioned, at least one of the aforementioned objects is also achieved by using at least one body vibration sensor, in particular an accelerometer in an energy self-sufficient one

Vibration measuring device, in particular an energy self-sufficient as described above

Vibration measuring device which is fastened by means of fastening means comprising at least one screw connection and / or at least one rivet, in particular blind rivet, and / or at least one irreversible or reversible adhesive connection in an arrangement on the outside of a device, in particular a container for detecting body vibration measurement data for evaluating a system state the device to be measured, wherein the vibration measuring device is used for energy self-sufficient reactive detection of the vibration measurement data with respect to vibration propagation passive vibration measuring device. This provides the aforementioned advantages. ITEM2 At least one of the aforementioned objects is also achieved by a method for energy self-sufficient operation of a vibration measuring device for energy self-sufficient provision of

System state information in the form of level information relating to a container, by energy self-sufficient detection of body vibration measurement data on the device, in particular by means of a previously described self-powered vibration measuring device, wherein a self-sufficient power supply for the purpose of providing the system state information is provided by means of a

Energy intake unit of the vibration measuring device harvested energy from the environment and is fed into an energy store of the vibration measuring device, wherein by means of a

Communication module of the vibration measuring device is a self-sufficient wireless transmission of the body vibration measurement data based on at least one communication protocol from the group of LP-WAN protocols takes place; wherein an energy self-sufficient detection of the body vibration measurement data on a solid surface of the device to be measured, wherein the detection is reactive with respect to vibration propagation passive vibration measuring device without active generation of vibrations, and further wherein an energy self-sufficient evaluation of the detected body vibration measurement data with respect to the level of liquid or solids takes place in an area bounded by the container interior volume, the body vibration measurement data are energy-autonomously transmitted wirelessly, the

Body vibration measurement data in a non-optical manner, in particular exclusively in a non-optical manner, by means of at least one body vibration sensor of the vibration measurement device adapted to detect the body vibration measurement data with respect to at least two spatial axes, preferably with respect to all three spatial axes, outside of the container are detected, wherein the self-powered Detecting in individual time intervals over a period of at least 1 to 6 days, weeks or months is carried out, wherein the evaluation of a difference between the second body vibration measurement data and

previous, previously recorded earlier body vibration measurement data includes. This provides many of the aforementioned benefits.

As mentioned above, at least one of the aforementioned objects is also achieved by a method for energy-autonomous provision of system state information, in particular level information, with respect to at least one of a plurality of system states of a device to be measured, in particular of a container, detected by energy self-sufficient evaluation of self-sufficient energy at the device

Body vibration measurement data, in particular by means of a previously described energy self-sufficient

Vibration measuring device, wherein an energy self-sufficient evaluation of the detected

Body vibration measurement data regarding at least one system state in an interior volume bounded by the device based solely on the body vibration measurement data, in particular with respect to a level of liquid or solids in the interior volume, wherein the evaluating a difference between the second body vibration measurement data and previous, previously recorded earlier body vibration measurement data wherein the body vibration measurement data are / were detected in particular by means of a previously described method. This provides the aforementioned advantages. In this case, a self-sufficient energy supply for the purpose of providing the system state information can be provided by harvested by at least one energy absorption unit energy from the environment and fed into at least one energy storage, said at least one of the

Energy storage coupled communication module an energy self-sufficient wireless transmission of

Body vibration measurement data (based on at least one communication protocol) takes place; wherein an energy self-sufficient detection of the body vibration measurement data in a non-optical manner via a mechanical interface with a body vibration coupling takes place, which contacts a solid surface of the device to be measured.

In this case, reference values can also be detected by means of established measuring methods, in particular for the purpose of depositing detected raw data together with the reference values. It can be a self-learning

Algorithm applied or established (machine-leaming).

The calculation performed by means of the arithmetic unit can be partly carried out on the sensor level, partly on a cloud level, ie be split in terms of data volume and / or

Computing tasks. This division on at least two levels is advantageous in order to also send comparatively large amounts of data in an efficient manner by means of narrowband communication methods.

According to one embodiment, the energy self-sufficient evaluation based on a difference formation to previous body vibration measurement data takes place in each case as a function or in dependence or at the time of a newly detected (or optionally actively initiated) vibration or vibration, in particular based on at least one self-learning algorithm, in particular with reference on at least one predefined, stored in a vibration database vibration pattern. According to one embodiment, a decay behavior of the body vibrations is evaluated. According to one embodiment, a distribution of the structure-borne sound measurement data and / or an exercise of the evaluation takes place on at least two levels, in particular comprising a cloud level and a sensor level. According to one embodiment, at least one comparison measurement takes place, in particular by means of ultrasound or based on ultrasound measurement values, in particular for the detection of reference values, in particular permanently or simultaneously, wherein a comparison with the evaluated body vibration measurement data takes place, in particular simultaneously. This provides each of the aforementioned advantages.

Not only can a difference be formed, but also a reference to predefined, stored or previously measured (vibration or sound) patterns can be made. In other words, the body vibrations can also be evaluated based on trained pattern recognition, in particular by means of self-learning algorithms.

Comparative measurements, in particular ultrasound measurements or evaluations are preferably carried out at most at the very beginning during a short time interval, ie not permanently, in particular in order

To generate reference values, in particular for calibration. In particular, thanks to the comparison measurement a neural network are trained, in particular in the form of a one-time training of algorithms (used / usable by the computing unit), in the beginning in a data logger phase, ie neither the final product (vibration measuring device) nor in its standard operating mode.

At least one of the aforementioned objects is also achieved by a computer program product configured to control a previously described method for self-powered operation of a

Vibration measuring device and / or set up for driving a previously described self-powered vibration measuring device, wherein the computer program product is set up to control the detection, the evaluation and / or the transmission of the body vibration measurement data depending on an energy content and / or energy flow. In addition to the aforementioned advantages, this also allows a very effective optimization of the energy balance.

At least one of the aforementioned objects is also achieved by a computer program product configured to evaluate body vibration measurement data acquired by a previously described method for providing system state information and / or by means of a previously described energy self-sufficient vibration measurement device, wherein the computer program product is set up, evaluating the acquired body vibration measurement data with respect to to perform at least one system state of the device to be measured by a time course of the

Body vibration measurement data between at least a first and a second measurement on the

System state is closed, in particular to the system state in an area bounded by the device interior volume, in particular with regard to a level of liquid or solids in the internal volume. This allows not only the aforementioned advantages but also the recording of a history, and thus the

Predicting an expected time when the internal volume will be completely filled. This can e.g. be advantageous when refueling tanks.

The computer program product may comprise both of the characteristics described above, that is to say be set up both for controlling the method described above and for controlling the device described above. In this case, the data and / or the evaluation are preferably split over at least two levels, in particular comprising a cloud level and a sensor level. As a result, relatively large amounts of data can be transmitted in an efficient manner, in particular also by means of narrowband communication protocols.

Accordingly, at least one of the aforementioned objects is also solved by a data carrier having such a computer program product stored thereon, or by a computer or a computer system or a virtual machine or at least one hardware element with it.

Accordingly, at least one of the aforementioned objects is also achieved by a computer program for providing the data described here or the method steps described here. As mentioned above, at least one of the aforementioned objects is also achieved by using an energy self-sufficient vibration measuring device, in particular an energy self-sufficient vibration measuring device, for energy self-sufficient detection of body vibration measurement data on a device to be measured in the form of a container, wherein the vibration measuring device comprises at least one energy absorption unit Energy stored by energy harvested from the environment self-sufficient energy and at least one communication module energy self-wireless transmits the vibration measurement data based on at least one communication protocol, in particular from the group of LP-WAN protocols, in particular based on SigFox and / or NBIoT, and the vibration measuring device detects the body vibration measurement data in a non-optical manner at a mounting position outside a solid surface of the container, wherein the sensing is reactive with respect to vibration propagation of the passive vibration measurement apparatus without actively generating vibrations, and wherein the vibration measurement apparatus evaluates and transmits the acquired body vibration measurement data with respect to at least one system state of the device to be measured, particularly with respect to a system state in an interior volume bounded by the device , in particular with regard to a level of liquid or solids in the internal volume. This results in the aforementioned advantages. In this case, for example, body vibration measurement data are recorded, which were caused by the throwing of contents into the container, ie reactive body vibration measurement data (no actively generated body vibration measurement data). Therefore, the vibration measuring apparatus enables reactive body vibration data to be reactively detected at the time when the body vibration is caused (reactive detection of body vibration caused by external effects).

As mentioned, at least one of the aforementioned objects is also achieved by using a computer program product and / or a computing unit for evaluating body vibration measurement data recorded on a device in the form of a container by means of an energy self-sufficient

Vibration measuring device, in particular an energy self-sufficient as described above

Vibration measuring device, by inferring from a time course of the body vibration measurement data between at least a first and a second measurement on the level in the container, wherein the detection of the body vibration measurement data is reactive in respect of vibration propagation passive

Vibration measuring device without active generation of vibrations takes place, in particular in a previously described method, in particular for evaluating a time course of the

 Body vibration measurement data between at least one first and one second measurement (difference formation) and / or for evaluating a decay behavior. This results in the aforementioned advantages.

BRIEF DESCRIPTION OF THE FIGURES

In the following drawing figures, the invention will be described in more detail, reference being made to reference characters, which are not explicitly described in a respective drawing figure, to the other drawing figures. Show it: Fig. 1A, 1B; 2A, 2B; 3A, 3B respectively in a schematic representation in a side view a

Vibration measuring device or its use, on a container with lid or on an open container or on a container without flap, each according to an embodiment;

 4 is a schematic representation of a process diagram relating to individual steps of a

Method according to one embodiment; and

 5 is a schematic representation of a time beam for illustrating an operation of a

Vibration measuring device or a method performed therewith, each according to a

Embodiment.

DETAILED DESCRIPTION OF THE FIGURES

 FIG. 1A shows a device 1 to be measured, for example a container, on which an energy self-sufficient vibration measuring device 10 is mounted. A wall 2 bounds the device and provides by means of a solid surface 2.1 a bearing or a mounting surface for the

Vibration measuring device 10. The wall 2 forms at least partially a lid 3. On the lid 3, a flap 4 is provided, which releases an opening 5 to the internal volume 6 of the device. The device 1 is filled with a filling 7 or with filling material (fluid and / or solids) at a filling level z7 (level). The device 1 rests on the ground and extends in three dimensions in the longitudinal direction x, width direction y and height direction z. The movement of the flap can optionally be detected, for example optically or by means of a swivel joint sensor or the like. Optionally, acoustic sensors may be provided.

Fig. 1B shows the vibration measuring device 10 in detail. A body vibration coupling 11 has a body vibration guide surface or contact surface 11.1 which can be brought into contact with the wall 2, 2.1 by attaching means 12 comprising mechanical fastening means 12a (for example screws) and / or adhesive fastening means 12b to the device 1 or wall 2 are coupled. The vibration measuring device 10 further comprises at least one vibration sensor, in particular

Accelerometer 13 and at least one energy storage or accumulator 17. A

Energy absorption unit 15, in particular comprising a solar module, can provide energy and charge the energy storage 17. Measurement data can be stored in a data memory 19 (main memory and / or permanent memory) or at least stored temporarily. By means of a communication module 14, a transmission of detected vibration measurement data can take place. By means of a computer program product 20, in particular, a specification with regard to the manner of the measurements to be carried out and / or the data transmission can take place. The vibration measuring device 10 may further include a

Charge measuring unit 15.1, in particular with Coulomb counter, and / or a light sensor 16 have. The individual modules or components of the vibration measuring device 10 are in connection with a computing unit and / or control unit 18.

FIG. 2A shows a variant in which the vibration measuring device 10 is arranged on a lateral wall 2 of an open device 1, for example on a recycling container, well container, Settling or roll-off container. Fig. 2B shows a contact surface 11.1, which is provided in combination with fastening means 12a, 12b. A variant with closed device 1 with one or more (insertion) opening 5 is shown in FIGS. 3A, 3B (without flap).

In Fig. 4, individual steps of a method according to the invention are explained in detail. In a first step S 1, a recording of vibration measurement data takes place. The step S 1 may also include activating the vibration measuring device 10, in particular from a deep sleep mode, in particular in response to newly occurring vibrations. In particular, the manner of detection can be regulated in a first control point RI, in particular with regard to a time or a time duration of the detection, in particular as a function of the energy content or energy flow. In a step S2, an evaluation of the vibration measurement data takes place. In a second control point R2, in particular the manner of the evaluation can be regulated, in particular with regard to a difference or a time course or a decay behavior. In a third step S3, archiving of the vibration measurement data takes place optionally. In a third control point R3, in particular the manner of storage can be regulated, in particular with regard to a selection of the data to be stored, for example in order to keep the data volume to be transmitted as low as possible. In a fourth step S4, a transmission of the vibration measurement data takes place, in particular as a function of the energy content of an energy store of the vibration measurement device. In a fourth control point R4, in particular the manner of the transmission can be regulated, in particular with regard to a point in time or a duration, in particular as a function of the energy content or energy flow. In this case, in a step S4.1, a setting of the type of transmission can take place, in particular with time specifications. In a step S5, a

Energy supply (charging) by means of at least one energy absorption unit (solar module). Step S5 may be independent of the further steps, or alternatively depending on e.g. in time dependence. A fifth control point R5 with regard to the mode of energy absorption and / or energy supply can be coupled to the further control points RI to R4.

FIG. 5 indicates a time profile (t) of one of the methods described here. At the time 0 in particular, a vibration or their detection / registration, for example, justified by a thrown into a container bottle, or by an open or slammed flap. At time 1, in particular, an activation of the vibration measuring device 10 takes place. At time 2, detection takes place in particular. At time 3, in particular, an evaluation takes place. At time 4, archiving and / or selection of subsets of the recorded data takes place in particular. At time 5, in particular, a transmission takes place, for example, only of a subset of the data to be transmitted. At time 6, in particular, a further transmission takes place, for example also only of a subset of the data to be transmitted, in particular as a function of an energy content of the energy store. The respective control RI to R5 can be carried out independently of the times 1, 2, 3 .... It can be a

Transmission interval (AI Advertisement Interval) are defined and maintained for a respective transmission time, which is independent of the individual times 1, 2, ..., for example over a time interval of a few minutes. FIG. 5 shows by way of example two transmission intervals of different lengths. The energy supply S5 is independent of the individual times 1, 2, 3 ...

Tag list

 1 device, in particular container

 2 wall

 2.1 Solid surface

 3 lids

 4 flap

 5 opening

 6 internal volume

 7 filling or filling material (fluid and / or solids)

 10 self-powered vibration measuring device

 11 Body vibration coupling with mechanical interface

 11.1 Body vibration control surface or contact surface

 12 fasteners

 12a mechanical fasteners

 12b adhesive fasteners

 13 vibration sensor, in particular body vibration sensor, in particular accelerometer

13.1 acoustic sensor or sound conversion unit (sound transducer), in particular MEMS microphone

14 communication module

 15 energy absorption unit, in particular solar module and / or piezoelectric module

 15.1 Charge measuring unit, in particular Coulomb counter

 16 light sensor

 17 energy storage or accumulator

 18 arithmetic unit and / or control unit

 19 data memory, in particular with vibration database

 20 computer program product

 AI transmission interval (Advertisement Interval)

 RI first regulation point, in particular with regard to the manner of detection

R2 second control point, in particular with regard to the manner of the evaluation

R3 third control point, in particular with regard to the way of Abspeememng

 R4 fourth control point, in particular with regard to the mode of transmission

 R5 fifth control point, in particular with regard to energy intake and / or feed

51 first step, in particular detection of vibration measurement data

 52 second step, in particular evaluation of the vibration measurement data

 53 third step, in particular storing or archiving the vibration measurement data

 54 fourth step, in particular transmission of the vibration measurement data

 54.1 Setting the mode of transmission

 55 Energy supply (charging) by means of energy absorption unit

x, y, z longitudinal direction, width direction and height direction

z7 level or filling level

Claims

claims 1. Energy self-sufficient vibration measuring device (10) arranged for energy self-sufficient detection of vibration measurement data on a device to be measured (1), in particular on a container, with an energy store (17) for self-sufficient energy supply of the vibration measuring device, in particular over a self-sufficient energy period of at least six months, and equipped with an energy absorption unit (15) for feeding energy harvested from the environment into the energy store, and further comprising a communication module (14) coupled to the energy store for energy self-sufficient wireless transmission of the vibration measurement data based on at least one communication protocol, in particular from the group of LP-WAN protocols, in particular based on SigFox and / or NBIoT; The vibration measuring device (10) is set up for self-sufficient detection and transmission of the vibration measurement data in the form of  Body vibration measurement data recorded on a solid surface (2.1) of the device to be measured (1), wherein the vibration measuring device has a computing unit (18) and is further adapted for energy self-sufficient evaluation of the detected body vibration measurement data with regard to at least one system state of the device to be measured (1), in particular with regard to a filling level (z7) of liquid or solids (7) in an internal volume (6) delimited by the device, in particular designed for evaluation exclusively on the basis of the body vibration measuring data. 2. Energy self-sufficient vibration measuring device (10) according to claim 1, wherein the Vibration measuring device (10) is set up for self-sufficient reactive detection of the Vibration measurement data with respect to vibration propagation of passive vibration measuring device. 3. energy self-sufficient vibration measuring device (10) arranged for energy self-sufficient detection of vibration measurement data on a device (1) in the form of a container, with an energy store (17) for self-sufficient energy supply of the vibration measuring device over a self-sufficient energy period of at least six months, and with an energy absorption unit (15 ) arranged to feed energy harvested from the environment into the energy store, and further comprising a communication module (14) coupled to the energy store for self-powered wireless transmission of the Vibration measurement data based on at least one communication protocol from the group of LP WAN protocols, in particular based on SigFox and / or NBIoT; The vibration measuring device (10) is set up for self-sufficient detection and transmission of the vibration measurement data in the form of  Body vibration measurement data recorded on a solid surface (2.1) of the device to be measured (1), wherein the vibration measuring device (10) is adapted for self-sufficient reactive detection of the vibration measurement data with respect to vibration propagation passive vibration measuring device, wherein the vibration measuring device has a computing unit (18) and is further adapted to Energy-self-sufficient evaluation of the detected body vibration measurement data with respect to a level (z7) of liquid or solids (7) in an inner volume (6) bounded by the device, in particular designed for evaluation exclusively based on the body vibration measurement data. 4. An energy self-sufficient vibration measuring device (10) according to one of the preceding claims, wherein the vibration measuring device as a body vibration coupling (11) formed mechanical interface and is adapted to detect the body vibration measurement data in a non-optical manner, in particular exclusively in a non-optical manner; and / or wherein the vibration measuring device (10) is arranged to detect body vibration measurement data by means of the body vibration coupling (11) in a festkörperkontaktierenden arrangement outside of the device, outside of an area bounded by the device interior volume (6), in particular without view into the internal volume, in particular on a wall (2) of the device. 5. Self-powered vibration measuring device (10) according to one of the preceding claims, wherein the body vibration coupling (11) comprises fastening means (12) comprising at least one screw connection and / or at least one rivet, in particular blind rivet; and / or wherein the body vibration coupling (11) comprises fastening means (12) comprising at least one irreversible or reversible adhesive bond; and / or wherein the body vibration coupling (11) has an at least partially planar, planar body vibration guidance surface (11.1) arranged for the areal absorption and transmission of Having body vibrations of the device, in particular geometrically corresponding to the device; and / or wherein the body vibration coupling has a body vibration guide surface (11.1) arranged for surface contacting of the device; and / or wherein one / the Körperschwingungsleitfläche (11.1) of the body vibration coupling (11) rigid with at least one fastening means (12) of the Body vibration coupling (11) is connected; and / or wherein the body vibration coupling (11) is arranged to detect the body vibration measurement data from vibrations of the device with respect to at least two spatial axes (x, y, z), preferably from vibrations with respect to all three spatial axes, in a non-optical manner via the body vibration coupling and at least one body vibration sensor (13) rigidly connected to the body vibration coupling, in particular a body vibration sensor with sensitivity in all three spatial axes, in particular a microelectromechanical body vibration sensor; and / or wherein the vibration measuring device has at least one body vibration sensor (13), in particular an accelerometer, in particular in a relative arrangement to / to body vibration coupling (11), in particular in a rigid relative arrangement to / to Körperschwingungsleitfläche (11.1), in particular coupled by means a rigid connecting element; and / or wherein the Vibration measuring device at least one body vibration sensor (13) comprising a Sound conversion unit (13.1), in particular MEMS microphone has. 6. energy self-sufficient vibration measuring device (10) according to any one of the preceding claims, wherein the energy absorption unit (15) comprises at least one solar module and / or at least one piezoelectric module; and / or wherein the vibration measuring device (10), in particular the arithmetic unit (18) is set up, the manner of the transmission, in particular times for the transmission, in Depend on the energy content of the energy store (17) and / or the energy flow in the energy storage; and / or wherein the arithmetic unit (18) is set up, a transmission interval (AI) based on the energy provided by the energy absorption unit (15) and / or based on a To define the state of charge of the energy store (17); and / or wherein the vibration measuring device (10) comprises a light sensor (16) and is arranged to quantify the amount of energy provided by the energy receiving unit (15); and / or wherein the arithmetic unit (18) is set up, the / Transmissionsintervall (AI) adapt as soon as the voltage applied to the energy storage (17) changes voltage, in particular by a Ändemngsrate is given by the distance to a predefinable target voltage; and / or wherein the vibration measuring device (10) is arranged to switch to an energy-demand-reduced deep sleep mode or to at least suspend the transmission and / or detection if no energy is provided by the energy absorption unit (15); and / or wherein the arithmetic unit (18) is set up, based on a charge measurement, in particular by means of Coulomb counter (15.1) to perform an input / output calculation in the manner of an energy balance on the energy store (17). 7. energy self-sufficient vibration measuring device (10) according to any one of the preceding claims, wherein the vibration measuring device (10) is adapted to make the transmission in an energy demand optimized, defined as "non-connectable" state; and / or wherein the vibration measuring device (10) is arranged to switch to configure the vibration measuring device in a "connectable" state, in particular depending on a current energy content of the energy absorption unit (15), in particular from a deep sleep mode; and / or wherein the vibration measuring device (10) comprises a light sensor (16) and is arranged to switch a predefinable threshold value into a "connectable" state during irradiation, in particular for a predefined period of time, in particular as a function of a current energy flow from the energy absorption unit (15); and / or wherein the vibration measuring device (10) is arranged to switch from a deep sleep mode into a "connectable" state in response to at least one external influence, the external influence being definable, in particular, from the following group: non-contact activation by a magnetic Field, NFC connection. 8. Energy autonomous vibration measuring device (10) arranged for energy self-sufficient detection of Vibration measurement data on a container, with an energy storage device (17) for self-sufficient energy supply of the vibration measuring device over a self-sufficient energy period of at least six months, and with a power receiving unit (15) adapted to feed energy harvested from the environment in the energy storage, and further with a the energy storage coupled communication module (14) arranged for energy self-sufficient wireless transmission of the vibration measurement data based on at least one communication protocol from the group of LP-WAN protocols; The vibration measuring device (10) is set up for self-sufficient detection and transmission of the vibration measurement data in the form of  Body vibration measurement data recorded on a solid surface (2.1) of the device to be measured (1), wherein the vibration measuring device (10) is adapted for self-sufficient reactive detection of the vibration measurement data with respect to vibration propagation passive vibration measuring device, wherein the vibration measuring device has a computing unit (18) and is further adapted to energy-self-sufficient evaluation of the acquired body vibration measurement data with regard to a level (z7) of liquid or solids (7) in an inner volume (6) delimited by the device, in particular based solely on the body vibration measurement data, wherein the vibration measurement device comprises at least one body vibration sensor (13) and is adapted to detect the Body vibration measurement data from vibrations of the container with respect to at least two spatial axes (x, y, z) in a non-optical manner. 9. Device (1), in particular container, with at least one energy self-sufficient vibration measuring device (10) attached thereto according to one of the preceding claims, wherein the Vibration measuring device (10) is attached to the outside of a wall (2) of the device, in particular without visual contact in a wall bounded by the inner volume (6). 10. A method for energy self-sufficient operation of a vibration measuring device for energy self-sufficient provision of system state information, in particular level information, with respect to at least one of several system states of a device to be measured (1), in particular a container, by energy self-sufficient detection of body vibration measurement data to the device (1), in particular by means of a Self-powered vibration measuring device (10) according to any one of the preceding claims, wherein a self-sufficient power supply for the purpose of providing the system state information is provided by harvested by an energy absorption unit (15) of the vibration measuring device energy from the environment and fed into an energy store (17) of the vibration measuring device wherein by means of a communication module (14) of the vibration measuring device, an energy self-sufficient wireless transmission of the body vibration measurement data based on who at least one communication protocol, in particular from the group of LP-WAN protocols, in particular based on SigFox and / or NBIoT; characterized by energy self-sufficient detection of the body vibration measurement data on a solid surface (2.1) of the device to be measured (1), and further by energy self-sufficient evaluation of the acquired body vibration measurement data with respect to the at least one system state, in particular a system state or a level (z7) of liquid or solids (7 ) in an interior volume (6) bounded by the device, the body vibration measurement data being transmitted in a self-sufficient, wireless manner. 11. The method according to the preceding method claim, wherein the detection takes place reactive with respect to vibration propagation passive vibration measuring device. 12. The method according to any one of the preceding method claims, wherein the  Body vibration measurement data are detected in a non-optical manner, in particular exclusively in a non-optical manner, in particular by means of at least one body vibration sensor (13) of Vibration measuring device (10); and / or wherein the body vibration measurement data by means of Body vibration coupling in a festkörperkontaktierenden arrangement outside of the device, outside of an area bounded by the device inner volume (6), in particular without view ins Internal volume are recorded; and / or wherein the body vibration measurement data by means of at least one in vibration-conducting connection to the device coupled body vibration sensor (13) are detected. 13. The method according to any one of the preceding method claims, wherein the energy-autonomous detection is carried out in individual time intervals of a few seconds, in particular 1 to 10 s, over a period of at least 1 to 6 days, weeks or months; and / or wherein the energy autonomous detection initiated, depending on the situation, by at least one body vibration sensor (13) of the Vibration measuring device (10) is performed in response to situational occurring Body vibrations, in particular as a function of an exceeded minimum threshold for a vibration intensity; and / or wherein the evaluating a difference between the second Body vibration measurement data and previous, earlier detected earlier Includes body vibration measurement data; and / or wherein a decay behavior of the body vibrations is evaluated, in particular in a time interval of at least 2.5s; and / or wherein the energy-autonomous transmission takes place in each case after a time interval which is defined as a function of the current energy content of the energy store (17); and / or wherein the energy self-sufficient transmission takes place only when the energy content of the energy store (17) exceeds a predefinable minimum threshold. 14. The method according to any one of the preceding method claims, wherein the detection by means of at least one body vibration sensor (13), in particular an accelerometer is arranged for detecting the body vibration measurement data with respect to at least two spatial axes, preferably with respect to all three spatial axes; and / or wherein the detection also takes place by means of a sound conversion unit (13.1), in particular a MEMS microphone. 15. The method according to any one of the preceding method claims, wherein the feeding of energy into the energy store (17) by means of a solar module and / or a piezoelectric module of Energy absorption unit (15) takes place; and / or wherein the mode of the transmission, in particular times for the transmission, are predetermined as a function of the energy content of the energy store (17) and / or the energy flow in the energy store, in particular by means of a computing unit (18) or control unit of the vibration measuring device (10 ); and / or wherein the evaluation and the transmission in dependence of an energy content of the energy storage device (17) is carried out by based on a Charge measurement takes place an input / output calculation in the manner of an energy balance on the energy store (17); and / or wherein a transmission interval (AI) is defined based on the energy provided by the energy receiving unit (15) and / or based on a state of charge of the energy store (17); and / or wherein the amount of energy provided by the energy receiving unit is quantified by means of a light sensor (16) of the vibration measuring device; and / or wherein one Transmission interval (AI) is adjusted as soon as the voltage applied to the energy storage (17) voltage changes, in particular by setting a rate of change over the distance to a predefinable target voltage; and / or wherein the vibration measuring device (10) switches to an energy-demand-reduced deep sleep mode or at least temporarily suspends the transmission and / or detection when no energy is provided by means of the energy absorption unit (15); and / or being based on a Charge measurement, in particular by means of Coulomb counter, a Eingangsgangsgangsrechnung in the manner of an energy balance on the energy storage (17) is performed; and / or wherein the transmission takes place in an energy demand-optimized, as "non-connectable" defined state of the vibration measuring device (10); and / or wherein the vibration measuring device is switched to configure in a "connectable" state, in particular depending on a current energy content of the energy store (17), in particular from a deep sleep mode; and / or wherein the vibration measuring device switches on irradiation greater than a predefinable threshold value into a "connectable" state, in particular for a predefined period of time, in particular as a function of a current energy content of the Energy storage (17); and / or wherein the vibration measuring device (10) switches from a deep sleep mode to a "connectable" state in response to at least one external influence, wherein the external influence is defined in particular at least from the following group: non-contact activation by a magnetic field, NFC Connection. 16. Use of at least one body vibration sensor (13), in particular accelerometer in an energy self-sufficient vibration measuring device, in particular an energy self-sufficient  Vibration measuring device (10) according to one of the preceding claims, fastened by means of fastening means (12) comprising at least one screw connection and / or at least one rivet and / or at least one irreversible or reversible adhesive connection in an arrangement on the outside of a device (1), in particular a container is, for acquiring body vibration measurement data for evaluating a System state of the device to be measured, wherein the vibration measuring device (10) is used for self-sufficient reactive detection of the vibration measurement data with respect to vibration propagation passive vibration measuring device. 17. A method for energy self-sufficient operation of a vibration measuring device for energy self-sufficient provision of system state information in the form of level information with respect to a container by energy self-sufficient detection of body vibration measurement data on the device (1), in particular by means of an energy self-sufficient vibration measuring device (10) according to one of the preceding claims, wherein a self-sufficient Energy supply for the purpose of providing the System state information is provided by means of a power receiving unit (15) of the Vibration measuring device energy harvested from the environment and is fed into an energy store (17) of the vibration measuring device, wherein by means of a communication module (14) of the Vibration measurement device is an energy self-sufficient wireless transmission of the body vibration measurement data based on at least one communication protocol from the Gmppe LP-WAN protocols; characterized by self-sufficient detection of the body vibration measurement data on a solid surface (2.1) of the device (1) to be measured, the detection being reactive with respect to vibration propagation of the passive vibration measurement device, and by self-sufficient evaluation of the acquired body vibration measurement data with respect to the level (z7) of liquid or solids (7) in an inner volume (6) delimited by the container, the body vibration measurement data being transmitted in an energy-autonomously wireless manner, the body vibration measurement data being transmitted in a non-optical manner, in particular exclusively non-optically, by means of at least one body vibration sensor (13). the vibration measuring device (10) is set up to detect the body vibration measurement data relative to at least two spatial axes outside the container, wherein the self-sufficient detection is performed at individual time intervals over a period of at least 1 to 6 days, weeks or months, wherein the evaluating a difference formation between second body vibration measurement data and previous, previously recorded earlier body vibration measurement data. 18. A method for energy self-sufficient provision of system state information, in particular level information, with respect to at least one of several system states of a device to be measured (1), in particular a container, by energy self-sufficient evaluation of self-sufficient energy at the device detected body vibration measurement data, in particular by means of a self-sufficient energy Vibration measuring device (10) according to one of the preceding claims; energy-self-sufficient evaluation of the acquired body vibration measurement data with regard to at least one system state, in particular a fill level (z7) of liquid, or e Solids (7), in an interior volume (6) bounded by the device, based solely on the body vibration measurement data, the evaluation forming a difference between the second Body vibration measurement data and previous, earlier detected earlier  Body vibration measurement data comprises, wherein the body vibration measurement data are detected in particular by means of a method according to one of the preceding method claims / were. 19. Method according to the preceding method claim, wherein the self-sufficient evaluation based on a difference formation to previous body vibration measurement data takes place in each case as a function or as a function of or at the time of a newly detected oscillation, in particular also using at least one self-learning algorithm, in particular with reference to at least one predefined one vibration pattern stored in a vibration database; and / or wherein a Decay behavior of body vibrations is evaluated; and / or wherein a breakdown of Structure-borne noise measurement data and / or exercise of the evaluation on at least two levels takes place, in particular comprising a cloud level and a sensor level; and / or wherein at least one Comparative measurement is carried out, in particular based on ultrasonic measurements, in particular for the detection of reference values, in particular permanently and / or simultaneously, and wherein a comparison with the evaluated body vibration measurement data takes place, in particular simultaneously. 20. Computer program product (20) configured to control a method for self-powered operation of a vibration measuring device according to one of the preceding method claims and / or set up for driving a self-powered vibration measuring device (10) according to one of the preceding device claims, wherein the computer program product (20) is arranged to detect to control the evaluation and / or the transmission of the body vibration measurement data as a function of an energy content and / or energy flow. 21. Computer program product (20) configured to evaluate body vibration measurement data acquired by means of a method for providing system state information according to one of the preceding Method claims and / or by means of an energy self-sufficient vibration measuring device (10) according to one of the preceding device claims, wherein the computer program product (20) is adapted to perform the evaluation of the detected body vibration measurement data with respect to at least one system state of the device to be measured (1) by a temporal Course of the Body vibration measurement data between at least a first and a second measurement on the System state is closed, in particular to the system state in one of the device (1) bounded inner volume (6), in particular with regard to a level (z7) of liquid or Solids (7) in the internal volume. 22. Use of an energy self-sufficient vibration measuring device, in particular an energy self-sufficient vibration measuring device (10) according to one of the preceding device claims, for energy self-sufficient detection of body vibration measurement data to be measured device (1) in the form of a Containers, wherein the vibration measuring device of at least one by a Energy recording unit (15) supplied with energy from the environment harvested energy storage (17) self-sufficient with energy and at least one communication module (14) energy self-wireless transmits the vibration measurement data based on at least one communication protocol, in particular from the group of LP-WAN protocols, in particular based on SigFox and / or NBIoT, and wherein the vibration measuring device in a mounting position on the outside of a solid surface (2.1) of the container detects the body vibration measurement data in a non-optical manner, wherein the detection is reactive with respect to vibration propagation passive vibration measuring device, and wherein the Vibration measuring device evaluates the transmitted body vibration measurement data with regard to at least one system state of the device to be measured (1) and transmits, in particular one System state or a level of liquid or solids (7) in an area bounded by the device inner volume (6). 23. Use of a computer program product and / or a computing unit for evaluating body vibration measurement data recorded on a device in the form of a container, by means of a energy self-sufficient vibration measuring device, in particular an energy self-sufficient Vibration measuring device according to one of the preceding device claims, by inferring from a time profile of the body vibration measurement data between at least a first and a second measurement on the level in the container, wherein the detection of Body vibration measurement data reactive with respect to vibration propagation passive Vibration measuring device takes place, in particular in a method according to one of the preceding method claims, in particular for evaluating a time profile of the body vibration measurement data between at least one first and a second measurement and / or for evaluating a decay behavior.