Ultrasonic Anemometer And Method For Determination Of At Least One Component Of A Wind Velocity Vector Or The Velocity Of Sound In The Atmosphere

Abstract

Described is an ultrasonic anemometer (7) as well as a method for determination of at least one component of a wind velocity vector and/or a velocity of sound with at least one sound transducer at least temporarily working as a transmitter (1, 2, 3, 4, 5, 6, 15, 16) with a sound emission surface for emitting sound waves and at least one sound transducer at least temporarily working as a receiver (1, 2, 3, 4, 5, 6, 15, 16) with a sound detection surface for at least partially receiving the emitted sound waves, and with an evaluation unit, which, based on a recorded transit time, which the sound waves require on a measuring section located between the sound emission surface of the at least one transmitter and the sound detection surface of the at least one receiver to cover the distance of this measuring section, determines at least one component of a wind velocity vector and/or the velocity of sound.

The technical solution described is characterized by at least one measuring section between a first sound emission surface of a first transmitter and a first sound detection surface of a first receiver being arranged approximately vertical to the earth's surface and the first sound emission surface and/or the first sound detection surface being inclined compared to the horizontal.

Claims

1-13. (canceled)

14. An ultrasonic anemometer (7) for determination of at least one component of a wind velocity vector and/or a velocity of sound, comprising: at least one sound transducer at least temporarily working as at least one transmitter (1, 2, 3, 4, 5, 6, 15, 16) with a sound emission surface for emitting sound waves; at least one sound transducer at least temporarily working as at least one receiver (1, 2, 3, 4, 5, 6, 15, 16) with a sound detection surface for at least partially receiving emitted sound waves; an evaluation unit to determine at least one component of a wind velocity vector and/or a velocity of sound based on a recorded transit time that the sound waves require on a measuring section located between the sound emission surface of the at least one transmitter and the sound detection surface of the at least one receiver to cover the distance of the measuring section, wherein at least one first measuring section between a first sound emission surface of a first transmitter and a first sound detection surface of a first receiver is arranged approximately vertical to the earth's surface, in particular with an inclination angle between 0 and 5, and wherein the first sound emission surface and/or the first sound detection surface are inclined compared to the horizontal.

15. The ultrasonic anemometer according to claim 14, wherein the at least one first measuring section is arranged with an inclination angle between 0 and 5 relative to the earth's surface.

16. The ultrasonic anemometer according to claim 14, wherein the sound emission surface and/or the sound detection surface has a membrane.

17. The ultrasonic anemometer according to claim 14, wherein the at least one transmitter and/or the at least one receiver is at least temporarily heatable.

18. The ultrasonic anemometer according to claim 14, wherein between the first transmitter with the first sound emission surface and at least one second receiver with a second sound emission surface, a second measuring section, inclined compared to the vertical, is formed and wherein the evaluation unit, based on a recorded transit time, which the sound waves require to cover the distance of the second measuring section, determines the at least one component of the wind velocity vector and/or the velocity of sound.

19. The ultrasonic anemometer according to claim 14, wherein the evaluation unit is configured, such that, depending on a wind direction, a measuring section from a group of at least two measuring sections is used for the determination of the at least one component of the wind velocity vector and/or the velocity of sound.

20. The ultrasonic anemometer according to claim 14, wherein the evaluation unit is configured such that at least a vertical component of the wind velocity vector is determined.

21. The ultrasonic anemometer according to claim 14, wherein the evaluation unit is configured such that an average value of the at least one component of the wind velocity vector is determined.

22. The ultrasonic anemometer according to claim 14, wherein the evaluation unit is configured such that three components of the wind velocity vector are respectively determined.

23. A method for determination of at least one component of a wind velocity vector and/or a velocity of sound, comprising: emitting sound waves with at least one sound transducer at least temporarily working as a transmitter (1, 2, 3, 4, 5, 6, 15, 16) with a sound emission surface; receiving emitted sound waves with at least one sound transducer at least temporarily working as a receiver (1, 2, 3, 4, 5, 6, 15, 16) with a sound detection surface; determining, with an evaluation unit, the at least one component of the wind velocity vector and/or the velocity of sound based on a recorded transit time, which the sound waves require on a measuring section located between the sound emission surface of the at least one transmitter and the sound detection surface of the at least one receiver to cover the distance of this measuring section, wherein at least one first measuring section between a first sound emission surface of a first transmitter and a first sound detection surface of a first receiver is arranged approximately vertical to the earth's surface, and wherein the first sound emission surface and/or the first sound detection surface are inclined compared to the horizontal.

24. The method according to claim 23, wherein a vertical component of the wind vector is determined.

25. The method according to claim 23, wherein an average value of the at least one component of the wind vector is determined.

26. The method according to claim 23, wherein, depending on a wind direction, at least one measuring section is selected from a group of at least two measuring sections, in order to take the at least one selected measuring section as the basis for determination of the at least one component of the wind velocity vector and/or the velocity of sound.

27. The use of an ultrasonic anemometer according to claim 14 for determination of vertical eddy covariance flows of air admixtures and/or energy.

Description

[0035] In the following, the invention is set forth in further detail without restriction of the general inventive concept by means of special embodiments with reference to the figures. In that:

[0036] FIG. 1: shows an ultrasonic wind measuring device, in which the lower sound transducer of the vertical measuring section is simultaneously used for measuring two inclined wind components;

[0037] FIG. 2: shows an ultrasonic wind measuring device, in which six sound transducers are used, which spread out three vertical measuring sections;

[0038] FIG. 3: shows an ultrasonic wind measuring device with a retaining frame formed by three vertical struts, in which six sound transducers are used, between which the measuring sections extend, and

[0039] FIG. 4: shows an ultrasonic wind measuring device with a central strut, in which eight sound transducers are used, between which the measuring sections extend.

[0040] FIG. 1 shows an ultrasonic wind measuring device 7, in which the lower sound transducer 2 of the vertical measuring section is simultaneously used for measuring two inclined wind components. The sound transducers 1 and 2 spread out the vertical measuring section 1-2, and with the sound transducers 1 and 3 or 1 and 4, resp., the inclined measuring sections 1-3 and 1-4 are realized. The actual section angles and section lengths can deviate from this example.

[0041] According to a particularly advantageous structural further development of the embodiment according to FIG. 1, it is conceivable to additionally offset the sound transducer 2 upward and the sound transducers 3 and 4 downward. With this offset, possible shadowing by the sound transducer 2 on the sections 1-3 as well as 1-4 is avoided or at least reduced, also with inclined inflow directions.

[0042] The transit times of the sound waves recorded on the measuring sections are transmitted to an evaluation unit, in which, on the basis of the recorded transit times, three wind components are determined, wherein, due to the special arrangement of the measuring sections, in particular the vertical wind component can be determined with particular accuracy.

[0043] Furthermore, FIG. 2 shows a further special embodiment of an ultrasonic wind measuring device 7 designed according to the invention. In this case, six sound transducers 1, 2, 3, 4, 5, 6 are used, using which three vertical measuring sections (1-2, 3-4, 5-6) are spread out. Using the same transducers, six inclined measuring sections are simultaneously realized (1-4, 1-6, 3-2, 3-6, 5-2, 5-4). Without higher effort compared to a conventional sound transducer arrangement for the three-dimensional wind vector, here, redundant measuring sections can be realized. Thus, depending on the respective inflow direction, a selection of those measuring sections can be made, with which, due to their position with the given inflow, the lowest shadowing effects are to be expected. Alternatively, or in addition, using multiple determinations, consensus values for the wind components can be determined, which enable higher reliability and accuracy than individual measurements on individual measuring sections. Advantageous compared to the design of the variant in FIG. 1 is the symmetrical setup of the upper and lower arrangement of the sound transducers.

[0044] In principle, the dashed connections in FIG. 2 could also be used. They are, however, of subordinate significance, since they have the undesired horizontal orientation and furthermore deviate too far from the respective beam axes, whereby the strength of the useful signal, and thus the accuracy of the measurements, is reduced.

[0045] For evaluation of the recorded transit times, a suitable evaluation unit is again provided, which determines the components of the wind vector from the recorded transit times. The output of information about the determined wind vector can be undertaken via a monitor or a display, resp., or any other suitable display unit.

[0046] FIG. 3 shows an ultrasonic wind measuring device 7 with a retaining frame formed by three bent vertical struts 14, in which six sound transducers 1-6 are used, which spread out three measuring sections. In this context, FIG. 3a) shows a side view and FIG. 3b) a top view of an ultrasonic wind measuring device 7 designed according to the invention.

[0047] Essential in the depicted ultrasonic wind measuring device 7 is, that in the central area, a retaining foot 8 is provided for fastening on a roof or at a masthead with a central strut 9 vertically extending upward. At the end of this central strut 9, three side arms 13 attached to a lower socket 11 are provided. Neighboring side arms 13, at the end of which one ultrasonic transducer 1-3 is respectively fastened, respectively enclose an angle of 120 in a horizontal plane. The side arms 13 are preferably inclined compared to the horizontal by an angle between 15 and 20, so that hereby the ultrasonic transducers 1-6 arranged at the end of the side arms 13 and fixedly connected to the arms 13 are also inclined by this angle compared to the horizontal.

[0048] Beside the side arms 13 for the ultrasonic transducers 1-6, three U- or C-shaped, resp., vertical struts 14 are attached at the lower socket 11 at the upper end of the central strut 9, which from here extend to an upper socket 12 of the ultrasonic wind measuring device 7. In the area of the lower socket 11, the bent vertical struts 14 are respectively attached below the side arms 13, at which the ultrasonic transducers 1-3 are arranged.

[0049] At the upper socket 12 of the ultrasonic wind measuring device 7, the bent vertical struts 14 are respectively arranged above the side arms 13 for the ultrasonic transducers 4-6 and rotated by an angle of 60 in the horizontal compared to the side arms 13 with the ultrasonic transducers 4-6.

[0050] With the special embodiment of the invention depicted in FIG. 3, in which at least one vertical measuring section between two ultrasonic transducers 1-6 is realized with a sound emission surface inclined compared to the horizontal, an ultrasonic wind measuring device 7 is provided, which, in a preferred manner, can be mounted at exposed locations for wind measurement, as e.g. at mastheads. Simultaneously, the bent vertical struts 14 are designed such that, on the one hand, sufficient stiffness and stability of the anemometer are ensured and simultaneously an almost interference-free inflow of wind to the individual ultrasonic transducers 1-6 is achieved.

[0051] In the embodiment shown in FIG. 3, two ultrasonic transducers 1-6 with inclined sound emission or sound reception surfaces, resp., are respectively arranged vertically on top of each other. Here, in a preferred manner, ultrasonic transducers 1-6 are used, which can emit sound waves in different directions and receive sound waves from different directions, wherein the sound transducers 1-6 preferentially have a hemispherical emission characteristic or reception characteristic, resp.

[0052] For measurement of the velocity and direction of the inflowing wind, the wind measuring device 7 depicted in FIG. 3 can be used to measure and evaluate the transit times of the sound waves between two ultrasonic transducers 1-6 vertically arranged on top of each other as well as respectively between one of the lower sound transducers 1-3 and the upper sound transducers 4-6. Here, three measuring sections can be spread out from each sound transducer 1-6, wherein at least one of these measuring sections extends in a vertical direction. Here, in principle, it is irrelevant for the realization of the invention, whether the individual sound transducers 1-6 transmit successively or simultaneously and whether fixed transmitters and receivers are provided among the ultrasonic transducers 1-6 or the individual ultrasonic transducers 1-6 respectively act alternatingly as transmitters and as receivers.

[0053] For evaluation of the recorded transit times, a suitable evaluation unit is again provided, which determines the components of the wind vector from the recorded transit times. The output of information about the determined wind vector can be undertaken via a monitor or a display, resp., or any other suitable display unit.

[0054] In FIG. 4, a further embodiment of an ultrasonic wind measuring device 7 is depicted, which uses the invention. Here, FIG. 4a) shows a side view and FIG. 4b) a top view of an ultrasonic wind measuring device 7 designed according to the invention.

[0055] The ultrasonic transducers 1-6, 15, 16 are, as already set forth in connection with FIG. 3, attached to side arms 13, which are arranged inclined compared to the horizontal. According to the embodiment shown in FIG. 4, however, eight ultrasonic transducers 1-6, 15, 16 are provided, of which respectively four are arranged in one horizontal plane. Neighboring ultrasonic transducers 1-6, 15, 16 respectively enclose an angle of 90 in a horizontal plane and are fastened to sockets 11, 12 of the ultrasonic wind measuring device 7 via side arms 13. Respectively four ultrasonic transducers 1-3, 15 are fastened to a lower socket 11 and four to an upper socket 12.

[0056] A retaining foot 8 is again provided, to which a central retaining strut 9 is fastened, which extends in a vertical direction up to a lower socket 11 for fastening the side arms 13 with the ultrasonic transducers 1-3, 15. According to this embodiment, the lower and upper sockets 11, 12 for fastening of the side arms 13 with the ultrasonic transducers 1-6, 15, 16, however, are not connected with one another via bent vertical struts 14 extending in the outside area, but via a centrally arranged central strut 10. In this case, too, the ultrasonic transducers 1-6, 15, 16 are arranged such that an almost undisturbed inflow of the wind is ensured and the ultrasonic wind measuring device 7, in a preferred manner, can be mounted on mastheads.

[0057] For the measurement of velocity and direction of the inflowing wind, with the wind measuring device 7 depicted in FIG. 4, the transit times of the sound waves between two ultrasonic transducers 1-6, 15, 16 vertically arranged on top of each other as well as respectively between one of the lower sound transducers 1-3, 15 and the upper sound transducers 4-6, 16 can again be measured and evaluated. Here, four measuring sections can be spread out from each sound transducer 1-6, 15, 16, wherein one of these measuring sections extends in a vertical direction. Here, in principle, it is irrelevant for the realization of the invention, whether the individual sound transducers 1-6, 15, 16 transmit successively or simultaneously and whether fixed transmitters and receivers are provided among the ultrasonic transducers 1-6, 15, 16 or the individual ultrasonic transducers 1-6, 15, 16 respectively act alternatingly as transmitters and as receivers.

[0058] For evaluation of the recorded transit times, a suitable evaluation unit is provided in this embodiment, too, which determines the components of the wind vector from the recorded transit times. The output of information about the determined wind vector can be undertaken via a monitor or a display, resp., or any other suitable display unit.

LIST OF REFERENCE SIGNS

[0059] 1 Sound transducer [0060] 2 Sound transducer [0061] 3 Sound transducer [0062] 4 Sound transducer [0063] 5 Sound transducer [0064] 6 Sound transducer [0065] 7 Ultrasonic wind measuring device [0066] 8 Retaining foot [0067] 9 Central strut, bottom [0068] 10 Central strut, center [0069] 11 Lower socket [0070] 12 Upper socket [0071] 13 Side arm [0072] 14 Bent vertical struts [0073] 15 Sound transducer [0074] 16 Sound transducer