• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Method and measuring arrangement for determining the local displacement of an object (1) along a displacement axis (V), wherein it is proposed that the light generated by laser light sources (10) of a measuring unit (5) be transmitted through an optical waveguide (3) to a relative to the object (3). 1), which transmits the transmitted light in the form of at least two laser light beams each having different wavelengths Ai (i = 1, 2,... N with N ~ 2) with at least two along the displacement axis (V ) side by side and overlapping projection surfaces Pi (i = 1, 2, ... N with N ~ 2) projected onto the object (1), and that of a on the object (1) within the projection surfaces Pi fixed retroreflector (2) reflected laser light of the at least two laser light beams in the measuring head (4) is detected, wherein the local displacement on the basis of the distribution of the reflected light intensity over the at least two wavelengths Ai ermit elt becomes.
    公开号:AT520302A4
    申请号:T50789/2017
    申请日:2017-09-19
    公开日:2019-03-15
    发明作者:
    申请人:Ing Guenther Neunteufel;Herbert Doeller;
    IPC主号:
    专利说明:

    The invention relates to a method for determining the local displacement of an object along a displacement axis, according to the preamble of claim 1, and a measuring arrangement for determining the local displacement of an object along a displacement axis, according to the preamble of claim 8.
    The measurement of the local displacement of an object along a displacement axis is essential, for example, in building construction and civil engineering, as well as in the monitoring of infrastructure equipment, in order to be able to detect an incipient impairment of the function of the object, for example a component, at an early stage.
    The local displacement along a displacement axis is an important indicator of an incipient deformation. If the object is, for example, a railroad track, a local displacement in the vertical direction causes a ramp to form between two adjacent rails, which can lead to the derailment of a train. But also for the monitoring of unstable geological zones, for example, the measurement of the local displacement of objects can be essential, for example in order to be able to detect the slipping of larger earth and rock masses as early as possible. For the measurement of the local displacement of an object along a displacement axis, conventionally, for example, optical measuring methods are available in which a laser beam is projected onto the object preferably provided with a reflector, and with a spatially resolving detector, for example a CCD sensor Vertical offset of the reflected light is measured. However, such methods are inaccurate because of a
    Vertical offset of the reflected light is not necessarily due to a local displacement in the vertical direction, but, for example, to a rotation of the reflector provided with the object. In addition, locally resolving detectors such as CCD sensors are sensitive to electrical interference and require permanent power supply. However, the measurements sometimes have to be carried out in the presence of electrical and / or magnetic interference fields, which can influence the measurement when using sensitive electronic components. Significant interference fields are present, for example, in the vicinity of railway systems, which make it difficult to measure the railroad tracks using optoelectronic methods. In addition, the relocation of own power lines to a measuring location is often neither possible nor acceptable in terms of cost.
    It is therefore the object of the invention to provide an apparatus and a method enabling a more accurate measurement of the local displacement of objects. The method and the device provided for this purpose should also allow an implementation in which can be dispensed with electrical components and a power supply for this, if this is necessary in a specific application.
    These objects are achieved by a method according to claim 1 and a measuring arrangement according to claim 8. Claim 1 relates to a method for determining the local displacement of an object along a displacement axis, is proposed in the invention that the light generated by laser light sources of a measuring unit via an optical waveguide to a relative to the object immovably mounted measuring head is passed, the transmitted light in the form of at least two laser light beams each having different wavelengths with at least two along the shift axis adjacent and overlapping projection surfaces projected onto the object, and which is detected by a retroreflector attached to the object within the projection surfaces reflected laser light of the at least two laser light beams in the measuring head, wherein the local displacement is determined on the basis of the distribution of the reflected light intensity over the at least two wavelengths.
    The measuring head is arranged at the location of the measurement in the vicinity of the object to be measured and immobile relative to the object. It projects the laser light generated by the measuring unit and transmitted via an optical waveguide in the form of at least two laser light beams each having different wavelengths onto at least two projection surfaces adjacent to one another and overlapping one another along the displacement axis. Within these projection areas, a retroreflector is attached to the object. A retroreflector is a reflective material that reflects most of the incident radiation, largely independent of the orientation of the reflector, back toward the radiation source. The light intensity of the reflected laser light thus significantly depends on the lying within the projection of the respective light beam partial surface of the retroreflector. The measurement is initially set approximately so that the retroreflector lies in the overlap region of the two projection surfaces. The ratio of the reflected to the incident light intensity of each wavelength will thus be about the same size for both light beams of different wavelengths. However, due to a local displacement of the object along the axis of displacement, the retroreflector attached to the object may be displaced to increasingly lie outside of the overlap area, or may even leave the overlap area altogether and become entirely within the projection area of either light beam. In this case, the distribution of light intensity will change over the two wavelengths, until ultimately no light is reflected by the retroreflector of any of the two laser beams at all, and a maximum of the other light beam. The distribution of the reflected light intensity over the at least two wavelengths is thus proportional to the local displacement of the object along the displacement axis and can be used to calculate the local displacement since each wavelength correlates with a local projection area. A maximum of the reflected light intensity for a particular wavelength thus correlates with the positioning of the retroreflector within the corresponding projection surface, and a lack of detection of reflected light of a particular one
    Wavelength with positioning of the retroreflector outside the corresponding projection surface. In other words, a shift of the maximum of the reflected light intensity from one wavelength to another Wellenläge immediately close to a corresponding local displacement of the retroreflector.
    An advantage of the method according to the invention is that it can also be carried out in a manner in which only electroless optical components are used at the location of the measurement, as will be explained in more detail below. In this case, current-carrying components are located exclusively in the measuring unit, which has one
    Fiber optic cable is connected to the measuring head. The
    However, the measuring unit can be located far away from the measuring head, for example in a safe place, where there is a permanent power supply via the public power grid. For example, the laser light reflected by the retroreflector can be coupled into an optical waveguide and transmitted to the measuring unit, the local displacement being determined in a spectrometer of the measuring unit based on the distribution of the reflected light intensity over the at least two wavelengths.
    The measurement can therefore also be carried out automatically, since it is low maintenance and easy to operate and in particular can be performed in the measuring head without regularly exchanged power storage. By specifying tolerance values of the local displacement of the object and an automated comparison of the measured values with the tolerance values, an automated generation of a warning signal can also be provided as soon as the tolerance values are exceeded. The measuring method can therefore be carried out largely autonomously and without human monitoring. This also allows its use over a longer period of time at a variety of measuring points, such as along a
    Rail network.
    If a power supply can be provided at the location of the measurement and the use of electronic components no
    Problem represents, the method according to the invention can of course also be applied. In this case, it is possible, for example, to spectrally separate the light reflected by the retroreflector in the measuring head and to supply each wavelength to a photodiode whose light intensity proportional, analog signal via an A / D converter converted into a digital signal and as a digital signal via the optical fiber of the measuring unit is transmitted. In addition, it is also possible to provide the power supply required for any electronic components that may be required via the optical fiber ("power over fiber"), so that an external power supply at the location of the measurement can be dispensed with.
    The number of light beams of different wavelengths used can of course vary. One possible embodiment of the measuring method according to the invention provides, for example, that the transmitted light is projected onto the object in the form of five laser light beams each having different wavelengths with five projection surfaces adjacent to one another along the displacement axis, wherein adjacent projection surfaces each overlap. Increasing this number can improve the accuracy of the measurement and extend the spatial displacement for the local displacement.
    The light beams of different wavelengths required for the measurement can either be made available via respective separate lasers which are arranged in the measuring unit, that is to say when five different wavelengths are used, for example, by five lasers or else by a broadband laser. In particular, it is proposed that the at least two wavelengths of the laser light beams projected onto the object are wavelengths of a CWDM (Coarse Wavelength Division Multiplex) method. In a multiplexing method, light signals of different wavelengths are commonly used to transmit data over the same optical fiber. The CWDM method represents a variant of a
    Multiplexing method in which 18 standard wavelengths with a channel spacing of 20 nm between 1271 nm and 1611 nm are used for the transmission of signals. In communications technology, these narrowband wavelength ranges are used as transmission channels for modulation. In the context of the present invention, however, the light signals of different wavelengths are used as measuring signals and are part of the measuring method. In particular, the light signals of different wavelengths are not modulated, but used to determine a luminous intensity ratio between the reflected and the emitted light. Preferably, the light generated by the laser light sources of the measuring unit is continuous laser light, although pulsed light may also be used.
    In particular, it is proposed that the at least two wavelengths projected onto the object
    Laser light beams in the O-band and / or in the C-band and / or in the L-band of the optical waveguide are. In the case of optical waveguides, wavelength ranges are formed by scattering and absorption, in which the attenuation of the transmitted light signal is lower than in other wavelength ranges. These wavelength ranges are also referred to as optical transmission windows and preferably used for the transmission of data. The optical windows are in wavelength ranges around 850 nm, 1,310 nm and 1,550 nm. The 0 band comprises approximately a wavelength range of 1260-1360 nm, the C band a wavelength range of 1530-1565 nm and the L band a wavelength range of 1570 A possible choice of five wavelengths for the light beams projected onto the object and the retroreflector would be about 1,530 nm, 1,550 nm, 1,570 nm, 1,590 nm, and 1,610 nm.
    Claim 8 refers to a measuring arrangement for determining the local displacement of an object along a displacement axis, for which it is proposed that a measuring head connected to a measuring unit via an optical waveguide is provided which includes a measuring head demultiplexer
    Generation of at least two light beams each having different wavelengths from the laser light generated by the laser light sources of the measuring unit and transmitted via the optical waveguide laser light comprises, as well as a radiating and receiving unit for the projection of at least two
    Light beams of different wavelengths with along the axis of displacement adjacent and overlapping projection on the object, and provided on the object within the projection retroreflector is provided, wherein an evaluation unit for determining a local shift on the basis of the distribution of the reflected light intensity over the at least two wavelengths provided is.
    Preferably, the evaluation unit comprises a in the
    Measuring unit arranged spectrometer, as well as arranged in the measuring head multiplexer for coupling the reflected by the retroreflector and recorded by means of the emitting and receiving unit of the measuring head laser light of different wavelengths in the optical waveguide. Alternatively, it is also possible for the evaluation unit to comprise a spectrometer arranged in the measuring head and a detector for determining the light intensity for each wavelength of the laser light reflected by the retroreflector, and an interface arranged in the measuring head for coupling a digital signal into the optical waveguide, which contains information about the light source detected light intensity for each wavelength of the reflected light from the retroreflector laser light, and for transmitting the digital signal to the measuring unit. The detector may be, for example, photodiodes which evaluate the light of different wavelengths separated by the spectrometer, the thus generated analog signals being converted into a digital signal which is subsequently coupled into the optical waveguide.
    The provision of light of different wavelengths can take place, for example, by means of different laser light sources, for example by means of LEDs or laser diodes, which each generate light of different wavelengths, which are subsequently fed through a multiplexer of the measuring unit into the
    Fiber optic is coupled. A possible choice would be, for example, special CWDM laser diodes, in particular VCSEL (Vertical Cavity Surface Emitting Laser) lasers, which were developed for data transmission but have proved suitable for the application according to the invention. They are available for wavelengths within the 850nm, 1,310nm, and 1,550nm optical transmission windows, and have low beam divergence and easy fiber launch compared to LEDs. Alternatively, a broadband laser providing the appropriate wavelengths could be used, in which case a multiplexer in the measuring unit may be dispensed with.
    This light could in principle be transmitted via different glass fibers to the location of the measurement to the measuring head, where it is used for the method according to the invention. The respective reflected light could be coupled into other fibers and transmitted to the measuring unit, where it is evaluated spectrometrically. This procedure would be conceivable in principle with sufficiently available glass fiber number. But sometimes it has to be an existing one
    Fiberglass architecture must be taken into account so that consideration must be given to a limitation of the number of available glass fibers, especially when multiple light beams of different wavelengths must be transmitted. In this case, a multiplexing method is preferably used in which the light signals of different wavelengths are first multiplexed in the measuring unit by means of a multiplexer onto an optical waveguide and transmitted via the same optical waveguide, and after transmission in the measuring head by means of a demultiplexer by passive optical filters and separated on the projected to be monitored and the retroreflector. The reflected light of different wavelengths is detected by the measuring head and either transmitted by means of a multiplexer via a second optical waveguide to the measuring unit, or already evaluated in the measuring head. In the former case, the received light in the measuring unit is subjected to a spectrometric analysis, and in the second case in the measuring head. It should be noted that the multiplexing and the de-multiplexing apparatus is usually carried out in the same device unit.
    However, as mentioned earlier, light signals of different wavelengths are not used to transmit data using modulation, as is common in CWDM techniques, but directly as measurement signals using emission and reflection and comparison of the respective intensities.
    The invention will be further described with reference to
    Embodiments explained in more detail using the accompanying drawings. It show here the
    1 is a schematic representation for explaining an embodiment of a measuring arrangement according to the invention,
    Fig. 2 is a schematic representation for explaining the method according to the invention, in particular the generation of light of different wavelengths using a
    Wavelength division multiplexing and its use as
    Measurement signal
    3a shows a representation of the projection surfaces in an embodiment of the method according to the invention using five different wavelengths,
    3b is a schematic diagram of the measurement signal measured in the spectroscope for the measurement configuration of Fig. 3a,
    4a shows the measurement configuration of FIG. 3a with the measurement object shifted, FIG.
    4b is a schematic diagram of the measurement signal measured in the spectroscope for the measurement configuration of FIG. 4a, and FIGS
    5 shows an example of a measurement result using the method according to the invention using a measuring arrangement according to the invention.
    Reference is first made to FIG. 1, which shows a schematic representation for explaining a possible embodiment of a corresponding measuring arrangement, and FIG. 2, which shows a schematic representation for explaining the method according to the invention. On the right side of Fig. 1, an object 1 is shown schematically, the local displacement along a shift axis V, which is indicated in phantom in FIGS. 1 and 2, monitored and optionally determined. The object 1 can be a local displacement in two opposite directions along the
    Displacement axis V subject, as indicated in FIGS. 1 and 2 with reference to the double arrow. A retroreflector 2 is fastened to the object 1 for this purpose, which carries out the same displacement in the case of a local displacement of the object 1 along the displacement axis V. The object 1 is, for example, a railroad track.
    The local displacement of the object 1 is determined on the basis of the positioning of a retroreflector 2 within the mutually overlapping projection regions of laser light beams of different wavelength λχ (i = 1, 2,... N with N> 2), as will be explained in more detail. In FIGS. 1 to 5, about five different wavelengths λι, λ2, λ3, λ4, λ5 are used for the measurement.
    The provision of the light of different wavelengths λι, λ2, λ3, λ4, λ5 takes place in laser light sources 10a, 10b, 10c, 10d and 10e of the measuring unit 5, for instance by means of LEDs or laser diodes, which respectively generate light of corresponding wavelengths. One possible choice would be, for example, special CWDM laser diodes, in particular VCSEL lasers, available for wavelengths located within the optical transmission windows of optical waveguides 3 at 850 nm, 1,310 nm and 1,550 nm. The five wavelengths λι, λ2, λ3, λ4, λ5 of the projected on the object 1 laser light beams are about wavelengths of a CWDM method, a possible choice would be about 1,530 nm, 1,550 nm, 1,570 nm, 1,590 nm and 1,610nm , These wavelengths are in the C-band and in the L-band of the optical waveguide 3. The laser light with these wavelengths λi, λ2, λ3, λ4, λ5 can be used as a measurement signal for distances up to 10 km subsequently, where each as a continuous Signal can be used, or as a pulsed signal whose mean frequency in the Fourier spectrum of the respective wavelength λι, λ2, λ3, λ4, λ5 corresponds.
    Laser light with these wavelengths λι, λ2, λ3, λ4, Äs is subsequently transmitted to the measuring head 4 by means of a multiplexing process via a first optical waveguide 3a, where it is detected by means of a demultiplexer in laser light beams having these five wavelengths λ1, λ2, λ3, λ4, λ5 is disconnected. For the transmission process from the measuring unit 5 to the measuring head 4, the interaction of a measuring unit multiplexer 6 and a measuring head demultiplexer 7 is required. The measuring unit multiplexer 6 couples the laser light of the five wavelengths λ1, λ2, λ3, λ4, λ5 into the same optical waveguide 3a, and the measuring head demultiplexer 7 separates them again. The measurement signals provided in this way to the measuring head 4 in the form of five laser light beams of different wavelengths λx, λ2, λ3, λ4, λ5 are produced by means of a radiation and reception unit 8 of the measuring head 4 with adjacent and overlapping ones along the displacement axis V.
    Projection surfaces Pi, P2, P3, P4, P5 projected onto the object 1, wherein the emitting and receiving unit 8 in particular comprises a collimator 9. The projection image resulting on the object 1 is shown schematically in FIGS. 3a and 4a.
    Within the projection surfaces Pi, P2, P3, P4, P5, the retroreflector 2 is arranged (see FIGS. 3a and 4a). The laser light incident on the object 1 is substantially only measurably reflected by the measuring head 4 when it hits the retroreflector 2, which largely reflects the incident radiation back to the measuring head 4, where it is received by the emitting and receiving unit 8. The reflected light is subsequently using a
    Measuring head multiplexer located in the same
    Device unit as the measuring head demultiplexer 7 is coupled into a second optical waveguide 3b and transmitted to the measuring unit 5, where it is evaluated in a spectrometer 11. If at the place of measurement a
    Power supply can be provided and the use of electronic components is not a problem, it is also possible, for example spectrally separate the light reflected by the retroreflector 2 in the measuring head 4 and each wavelength λχ, λ2, λ3, λ4, λ5 each supplied to a photodiode whose Light intensity proportional, analog signals are converted via an A / D converter into digital signals and transmitted as a digital signal via the optical waveguide 3b of the measuring unit 5. In this case, the spectrometer 11 is in the measuring head 4 and a measuring head multiplexer can be omitted.
    The reflected laser light can be emitted with the
    Laser light can be compared in its luminous intensity, the ratio being within the relevant
    Projection surface Ρχ, P2, P3, P4, P5 can close surface portion of the retroreflector 2, as will be explained with reference to FIGS. 3 and 4. The measurement is first set approximately according to FIG. 3 a such that the retroreflector 2 lies in the overlapping area of the two projection surfaces Ρχ and P 2, as well as the projection surfaces P 2 and P 3. The ratio of the reflected to the incident light intensity will thus be greatest for the wavelength λ2, since the entire surface of the retroreflector 2 is within the projection area P2.
    The ratio of the reflected to the incident light intensity for the two light beams of the wavelengths λχ and λ3, however, will be approximately the same, since comparable partial areas of the retroreflector 2 within the
    Projection surfaces Ρχ and P3 are. On the other hand, hardly or no reflected laser light will be measurable for the wavelengths λ4 and λ5, since the retroreflector 2 lies entirely outside the projection surfaces P4 and P5, so that the ratio of the reflected to the incident light intensity for these two light beams will be approximately zero. This distribution of the reflected light intensities over the respective wavelengths is indicated in FIG. 3b.
    Due to a local displacement of the object 1 along the axis of displacement V, however, the retroreflector 2 attached to the object 1 can be displaced so that it increasingly comes to rest outside the overlapping area of the two projection surfaces Ρχ and P2, or even completely leaves its overlapping area and entirely the projection surface P3 comes to rest, as shown in Fig. 4a. In this case, the distribution of light intensity across the five wavelengths λχ, λ2, λ3, λ4, λ5 will change until ultimately no longer any light is reflected by the laser beam of wavelength λχ, of the laser beam of wavelength λ2 compared to FIG. 3b clearly reduced light intensity, and the laser beam of wavelength λ3 a maximum. On the other hand, hardly any or no reflected laser light will be measurable for the wavelengths λ4 and λ5. The corresponding distribution of the reflected light intensities over the respective wavelengths is indicated in FIG. 4b.
    The distribution of the reflected light intensity over the five wavelengths λχ, λ2, λ3, λ4, λ5 is thus proportional to the local displacement of the object 1 along the displacement axis V and can be used to calculate the local displacement, since each wavelength λχ, λ2, λ3, λ4, λ5 correlated with a local projection area. A maximum of the reflected light intensity for a particular wavelength λχ, λ2, λ3, λ4, λ5 thus correlates with the positioning of the retroreflector 2 within the corresponding projection area Ρχ, P2, P3, P4, P5, and a lack of detection of reflected light of a specific wavelength λχ, λ2, λ3, λ4, λ5 with a positioning of the retroreflector 2 outside the corresponding
    Projection area Ρχ, P2, P3, P4, P5. In other words, a shift of the maximum of the reflected light intensity from one wavelength λχ, λ2, λ3, λ4, λ5 to another
    Wellenläge λι, λ2, λ3, λ4, λ5 close immediately to a corresponding local displacement of the retroreflector 2.
    FIG. 5 shows a corresponding measurement curve. It turns out that the trace shifts from the initial + 0.7mm at the time "00: 00h" to -1.4mm at the time "16:00", ie at 2.1mm. The two marked areas "trainl" and "train2" indicate the passage of a train, whereby the associated temporary lowering of the railroad track was exactly measurable. This temporary
    Measuring artifacts can be eliminated, for example, by software from an automatically performed monitoring, so that a warning signal is generated only when a tolerance range for the local displacement is permanently exceeded.
    The invention thus enables the autonomous measurement of the local displacement of an object 1 along a
    Displacement axis V, which can also be used without local power supply at the location of the measurement. In addition, the measurement is possible without the presence of operating or maintenance personnel at the place of measurement, and thus facilitates permanent monitoring over longer periods of time.
    权利要求:
    Claims (10)
    [1]
    1. A method for determining the local displacement of an object (1) along a displacement axis (V), characterized in that the laser light sources (10) of a measuring unit (5) generated light via an optical waveguide (3) to a relative to the object (1 ) immobile bearing measuring head (4) is passed, the transmitted light in the form of at least two laser light beams each having different wavelengths (i = l, 2, ... N with N> 2) with at least two along the displacement axis (V) side by side lying and overlapping projection surfaces Pi (i = l, 2, ... N with N> 2) projected onto the object (1), and the laser light reflected by a retroreflector (2) fixed to the object (1) within the projection surfaces Pi the at least two laser light beams in the measuring head (4) are detected, wherein the local displacement is determined on the basis of the distribution of the reflected light intensity over the at least two wavelengths λi.
    [2]
    2. The method according to claim 1, characterized in that the retroreflector (2) reflected laser light in an optical waveguide (3) is coupled and transmitted to the measuring unit (5), wherein in a spectrometer (11) of the measuring unit (5), the local displacement is determined on the basis of the distribution of the reflected light intensity over the at least two wavelengths λi.
    [3]
    3. The method according to claim 1, characterized in that the retroreflector (2) reflected light in the measuring head (4) separated spectrally and the light intensity of each wavelength λι of the retroreflector (2) reflected laser light is detected, wherein a digital signal, the Information about the determined light intensity for each wavelength λi of the retroreflector (2) reflected laser light contains, via the optical waveguide (3) of the measuring unit (5) is transmitted.
    [4]
    4. The method according to any one of claims 1 to 3, characterized in that the transmitted light in the form of five laser light beams each having different wavelengths λί (i = l, 2, ... 5) with five along the axis of displacement (V) adjacent Projection surfaces Pi (i = l, 2, ... 5) is projected onto the object (1), wherein adjacent projection surfaces Pi each overlap.
    [5]
    5. The method according to any one of claims 1 to 4, characterized in that it is the wavelengths of a CWDM (Coarse Wavelength Division Multiplex) method at the at least two wavelengths λχ of the object (1) projected laser light beams, using a multiplex method be transmitted via the optical waveguide (3).
    [6]
    6. The method according to any one of claims 1 to 5, characterized in that the at least two wavelengths λχ of the object (1) projected laser light beams in the O-band and / or in the C-band and / or in the L-band of the optical waveguide ( 3) lie.
    [7]
    7. The method according to any one of claims 1 to 6, characterized in that it is the object (1) is a railroad track.
    [8]
    8. Measuring arrangement for determining the local displacement of an object (1) along a displacement axis (V), characterized in that a with a measuring unit (5) via an optical waveguide (3) connected to the measuring head (4) is provided which a measuring head demultiplexer (7) for generating at least two light beams each having different wavelengths λχ (i = l, 2,... N with N> 2) from the laser light sources (10) of the measuring unit (5) and via the optical waveguide (3) transmitted laser light comprises, as well as a emitting and receiving unit (8) for projecting the at least two light beams of different wavelengths λί along the displacement axis (V) adjacent and overlapping projection surfaces P ± (i = l, 2, ... N with N > 2) on the object (1), and on the object (1) within the projection surfaces Ρχ fixed retroreflector (2) is provided, wherein an evaluation unit for determining a it is local displacement based on the distribution of the reflected light intensity over the at least two wavelengths λ ± is provided.
    [9]
    9. Measuring arrangement according to claim 8, characterized in that the evaluation unit comprises a in the measuring unit (5) arranged spectrometer (11) and arranged in the measuring head (4) measuring head multiplexer for coupling of the retroreflector (2) reflected and using the Emitting and receiving unit (8) of the measuring head (4) recorded laser light of different wavelengths λ ± in the optical waveguide (3).
    [10]
    10. Measuring arrangement according to claim 8, characterized in that the evaluation unit comprises a measuring head (4) arranged spectrometer (11) and a detector for determining the light intensity for each wavelength λι of the retroreflector (2) reflected laser light comprises, as well as in the measuring head ( 4) arranged interface for coupling a digital signal in the optical waveguide (3) containing information about the detected light intensity for each wavelength λ ± of the retroreflector (2) reflected laser light, and for transmitting the digital signal to the measuring unit (5).
    类似技术:
    公开号 | 公开日 | 专利标题
    EP3069952B1|2017-05-03|Axle counting method and axle counting device
    DE3044183C2|1989-11-09|
    DE4129438C2|1993-06-17|
    DE19940280C2|2001-11-15|Gas sensor with an open optical measuring section
    DE69831405T2|2006-02-23|DISTRIBUTED SENSOR SYSTEM
    EP3685117B1|2021-11-17|Method for determining the spatial displacement of an object
    DE602005004787T2|2009-03-05|An optical transmitter-receiver module for monitoring an optical fiber and method for providing the monitoring data of the optical fiber
    EP1796295B1|2010-07-21|Method for detection and location of faults on an optical transmission path and optical transmission system
    DE19754910A1|1999-07-01|Wavelength detection on fiber Bragg grating sensors
    DE102009047990A1|2011-04-07|Apparatus and method for spatially resolved temperature measurement
    EP0174496A2|1986-03-19|Procedure for measuring the radiation wavelength and the wavelength-corrected radiation power of monochromatical light-sources and arrangement for carrying out this procedure
    EP2513873A1|2012-10-24|Sensor for checking value documents
    DE69823609T2|2004-09-16|Monitoring the optical signal power with a signature bit pattern in WDM systems
    DE102013002304B3|2014-03-20|Optical sensor system for motor vehicle for detecting road condition, has controller, whose control is effected such that signal component of transmitted signal controls error in receiver output signal
    DE202018104258U1|2019-10-25|Safety Light Curtain
    DE102016202662A1|2017-09-07|Device for fiber-based temperature detection
    EP0224943A2|1987-06-10|Method to measure selectively, according to wavelength, the diminution in radiation intensity in an optical transmission system
    DE4133131C2|1996-07-04|Arrangement for determining chemical and / or physical quantities influencing the light intensity
    DE19816359A1|1999-10-07|Optical structural change detector for surface of moving part, especially adhesive layer
    EP1025417A1|2000-08-09|Method and device for measuring the optical properties of transparent and/or diffusive objects
    DE102017122774A1|2019-04-04|Method and system for monitoring track systems
    EP2227671B1|2013-07-10|Arrangement and method for determination of a position and/or orientation of two objects relative to one another
    EP2189813A1|2010-05-26|Sensor device with a distance sensor
    DE102019200733A1|2020-07-23|Method and device for determining at least one spatial position and orientation of at least one tracked measuring device
    DE102016124654A1|2018-06-21|Method and apparatus for identifying a fiber in a bundle of optical fibers and related use
    同族专利:
    公开号 | 公开日
    AT520302B1|2019-03-15|
    EP3685117B1|2021-11-17|
    EP3685117B8|2021-12-22|
    WO2019057481A1|2019-03-28|
    EP3685117A1|2020-07-29|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JP2006266973A|2005-03-25|2006-10-05|Kds Corp|Displacement amount measuring method|
    JP2011069699A|2009-09-25|2011-04-07|Railway Technical Res Inst|Rail detection method and rail displacement measurement apparatus in rail displacement measurement|
    EP2333493A2|2009-12-14|2011-06-15|Dr. Johannes Heidenhain GmbH|Position measuring device|
    CH663466A5|1983-09-12|1987-12-15|Battelle Memorial Institute|METHOD AND DEVICE FOR DETERMINING THE POSITION OF AN OBJECT IN RELATION TO A REFERENCE.|
    GB8923994D0|1989-10-25|1989-12-13|Smiths Industries Plc|Optical transducers|
    US7916278B2|2004-04-06|2011-03-29|Bae Systems Information And Electronic Systems Integration Inc.|Polyspectral rangefinder for close-in target ranging and identification of incoming threats|CN112146566A|2019-11-19|2020-12-29|中国南方电网有限责任公司超高压输电公司贵阳局|High-voltage converter transformer sleeve state monitoring device based on multi-source information fusion|
    CN112484647A|2020-11-18|2021-03-12|北京华卓精科科技股份有限公司|Interferometer displacement measurement system and method|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50789/2017A|AT520302B1|2017-09-19|2017-09-19|Method for determining the local displacement of an object|ATA50789/2017A| AT520302B1|2017-09-19|2017-09-19|Method for determining the local displacement of an object|
    PCT/EP2018/073719| WO2019057481A1|2017-09-19|2018-09-04|Method for determining the spatial displacement of an object|
    EP18765609.5A| EP3685117B8|2017-09-19|2018-09-04|Method for determining the spatial displacement of an object|
    [返回顶部]