Fluid Measurement Device

Abstract

First to N-th (N is an integer of three or more) sensor elements each including a light source unit and a light reception unit are arranged around a tube that allows a fluid containing scatterers to flow at equiangular intervals, and coherent light which is emitted from the light source unit of any one sensor element of the first to N-th sensor elements and is transmitted through the fluid flowing through the tube is received by the light reception unit of another predetermined sensor element of the first to N-th sensor elements. At this time, when a distance between the light source unit and the light reception unit of any one sensor element is d and an outer radius of the tube is r, a distance between any one sensor element and another predetermined sensor element is set to πd/2 or more and √3r or less.

Claims

1.-7. (canceled)

8. A fluid measurement device, comprising: first to N-th sensor elements arranged around a tube configured to allow a fluid containing scatterers to flow, wherein N is an integer of three or more, and wherein each of the first to N-th sensor elements includes a light source configured to irradiate the fluid with coherent light and a light receiver configured to receive and photoelectrically convert the coherent light; a signal processor configured to amplify and filter signals which are received and photoelectrically converted by the light receivers of the first to N-th sensor elements; and a calculator configured to convert the signals processed by the signal processor into digital signals, and calculate a flow velocity or a flow rate of the fluid based on the digital signals; wherein the coherent light which is emitted from the light source of a first sensor element of the first to N-th sensor elements and is transmitted through the fluid flowing through the tube is received by the light receiver of a second predetermined sensor element of the first to N-th sensor elements; and wherein, when a distance between the light source and the light receiver of the first sensor element is d and an outer radius of the tube is r, a distance between the first sensor element and the second predetermined sensor element is set to πd/2 or more and √3r or less.

9. The fluid measurement device according to claim 8, wherein the first to N-th sensor elements are arranged around the tube at equiangular intervals.

10. The fluid measurement device according to claim 8, wherein the second predetermined sensor element is a sensor element adjacent to the first sensor element.

11. The fluid measurement device according to claim 8, wherein: N is an integer of 6 or more; and the second predetermined sensor element is a sensor element adjacent to the first sensor element with a third sensor element adjacent to the first sensor element interposed between the second predetermined sensor element and the first sensor element.

12. The fluid measurement device according to claim 8, wherein the calculator is configured to calculate the flow velocity or the flow rate of the fluid based on a scattered light, which is a light scattered by the scatterers, the light configured to be emitted from the light source of the first sensor element and received by the light receiver of the first sensor element in addition to a light which is emitted from the light source of the first sensor element, transmitted through the fluid allowed to flow through the tube, and received by the light receiver of the second predetermined sensor element.

13. The fluid measurement device according to claim 8, wherein the calculator is configured to calculate the flow velocity or the flow rate of the fluid based on an average value of the signals received by the light receivers of the first to N-th sensor elements.

14. The fluid measurement device according to claim 8, wherein the calculator is configured to calculate concentration information of the fluid based on signals of transmitted light detected by the light receivers of the first to N-th sensor elements, and correct at least one value of the calculated flow velocity or the flow rate of the fluid based on the concentration information.

15. A method of measuring a fluid, the method comprising: arranging first to N-th sensor elements around a tube that allows a fluid containing scatterers to flow, wherein N is an integer of three or more, and wherein each of the first to N-th sensor elements includes a light source to irradiate the fluid with coherent light and a light receiver to receive and photoelectrically convert the coherent light; amplifying and filtering signals which are received and photoelectrically converted by the light receivers of the first to N-th sensor elements; and converting the signals processed into digital signals and calculating a flow velocity or a flow rate of the fluid based on the digital signals; wherein the coherent light which is emitted from the light source of a first sensor element of the first to N-th sensor elements and is transmitted through the fluid flowing through the tube is received by the light receiver of a second predetermined sensor element of the first to N-th sensor elements; and wherein, when a distance between the light source and the light receiver of the first sensor element is d and an outer radius of the tube is r, a distance between the first sensor element and the second predetermined sensor element is set to πd/2 or more and √3r or less.

16. The method according to claim 15, wherein arranging the first to N-th sensor elements around the tube comprises arranging the first to N-th sensor elements around the tube at equiangular intervals.

17. The method according to claim 15, wherein the second predetermined sensor element is a sensor element adjacent to the first sensor element.

18. The method according to claim 15, wherein: N is an integer of 6 or more; and the second predetermined sensor element is a sensor element adjacent to the first sensor element with a third sensor element adjacent to the first sensor element interposed between the second predetermined sensor element and the first sensor element.

19. The method according to claim 15, wherein calculating the flow velocity or the flow rate of the fluid based on the digital signals comprises calculating the flow velocity or the flow rate of the fluid based on a scattered light, which is a light scattered by the scatterers, the light being emitted from the light source of the first sensor element and received by the light receiver of the first sensor element in addition to a light which is emitted from the light source of the first sensor element, transmitted through the fluid allowed to flow through the tube, and received by the light receiver of the second predetermined sensor element.

20. The method according to claim 15, wherein calculating the flow velocity or the flow rate of the fluid based on the digital signals comprises calculating the flow velocity or the flow rate of the fluid based on an average value of the signals received by the light receivers of the first to N-th sensor elements.

21. The method according to claim 15, further comprising: calculating concentration information of the fluid based on signals of transmitted light detected by the light receivers of the first to N-th sensor elements; and correcting at least one value of the calculated flow velocity or the flow rate of the fluid based on the concentration information.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] FIG. 1 is a cross-sectional view illustrating an element arrangement in a fluid measurement device according to a first embodiment of the present disclosure.

[0024] FIG. 2A is a diagram illustrating an arrangement of a light source unit and a light reception unit in a sensor element.

[0025] FIG. 2B is a diagram illustrating the arrangement of the light source unit and the light reception unit in the sensor element.

[0026] FIG. 3A illustrates another example in which sensor elements are arranged around a tube at equiangular intervals.

[0027] FIG. 3B illustrates still another example in which the sensor elements are arranged around the tube at equiangular intervals.

[0028] FIG. 3C illustrates still another example in which the sensor elements are arranged around the tube at equiangular intervals.

[0029] FIG. 4A illustrates an example in which light rays from light source units of a plurality of sensor elements are received by a light reception unit of one sensor element.

[0030] FIG. 4B illustrates an example in which the light rays from light source units of the plurality of sensor elements are received by the light reception unit of one sensor element.

[0031] FIG. 4C illustrates an example in which the light rays from light source units of the plurality of sensor elements are received by the light reception unit of one sensor element.

[0032] FIG. 4D illustrates an example in which the light rays from light source units of the plurality of sensor elements are received by the light reception unit of one sensor element.

[0033] FIG. 5 is a cross-sectional view illustrating an element arrangement in a fluid measurement device according to a second embodiment of the present disclosure.

[0034] FIG. 6 is a diagram illustrating an example in which back-scattered light is received by using a light reception unit in the identical sensor element.

[0035] FIG. 7 is a diagram illustrating a configuration of a fluid measurement device of the related art.

[0036] FIG. 8A is a diagram illustrating an arrangement of light source units and light reception units in the fluid measurement device of the related art.

[0037] FIG. 8B illustrates the arrangement of the light source units and the light reception units in the fluid measurement device of the related art.

[0038] FIG. 9 is a functional block diagram of a signal processing unit and a calculation unit.

[0039] FIG. 10A is a diagram illustrating a velocity distribution in a straight tube (laminar flow state).

[0040] FIG. 10B illustrates a velocity distribution in a bent tube (non-laminar flow state).

[0041] FIG. 11 is a diagram illustrating a distance d between a light source unit and a light reception unit in an integrated sensor.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

[0042] Hereinafter, embodiments of the present disclosure will be described in detail. First, an outline of the present disclosure will be described before the embodiments are described.

Outline of Disclosure

[0043] As described above, the reason why it is extremely difficult to calculate the average flow velocity and the average flow rate of the fluid from the moving velocity when the tube is made from the elastic body or the like and the tube may be bent is because velocity information of the scatterers to be detected is obtained from a local region.

[0044] Thus, in a situation in which the velocity distribution is not uniform such that the velocity distribution is changing depending on the position of the tube, a position at which a sensor is to be arranged or a bent state changes, and thus, values to be detected fluctuate. One method for solving this problem is to average these values by enlarging a region in which the velocity information of the scatterers to be detected is obtained. Thus, it is necessary to separate the light source unit and the light reception unit from each other such that scattered light generated from a wide range can be received.

[0045] However, an intensity of the scattered light is weak, and the light is scattered during repeated multiple scattering by separating the light source unit and the light reception unit from each other. Thus, there is a possibility that a light intensity becomes weak enough to be difficult to be detected. The scattered light is attenuated by absorption in a medium in which the light is absorbed.

[0046] From the viewpoints of solving such attenuation, it is necessary to detect the scattered light in a direction of a stronger scattering. That is, as in the related art, when the distance between the light source unit and the light reception unit is close, the light from the light source unit scattered backward of the scatterers (hereinafter, referred to as “back-scattered light”)) is necessarily received. However, in the fluid measurement device according to the present embodiment, this problem is solved by receiving the light from the light source unit scattered forward of the scatterers (hereinafter, referred to as “forward-scattered light”) instead. The “forward-scattered light” advances along an optical path through which the fluid is transmitted (passes), and thus, the forward-scattered light is included in “transmitted light” to be described below.

[0047] In blood to be often measured by the flowmeter, a size of a red blood cell (particle size) which is the scatterer is approximately identical to a wavelength used for measurement, and the scattering in this case is referred to as “Mie scattering”. In this type of scattering, an intensity of the forward-scattered light is about 10 times stronger than an intensity of the back-scattered light, and an attenuation amount of the light caused by separating the light source unit and the light reception unit from each other can be compensated for.

[0048] Accordingly, the light source unit and the light reception unit may have a “transmitted light detection arrangement” in which transmitted light from a light source (light transmitted through the fluid flowing through the tube (including forward-scattered light)) is received, and thus, the forward-scattered light can be selectively detected. This arrangement has an effect that information related to a concentration of the scatterers can also be obtained from the attenuation amount of the transmitted light caused by absorption and scattering by the scatterers to detect the transmitted light.

[0049] The light source unit and the light reception unit can be arranged as independent elements. However, data at various positions can be acquired by arranging a plurality of sensor elements (hereinafter, also referred to as “integrated sensor elements”) in which the light source unit and the light reception unit are provided in proximity to one board around the tube. Accordingly, the number of data itself increases, and thus, there is an advantage that measurement accuracy is improved.

[0050] Meanwhile, when the light source unit and the light reception unit have the “transmitted light detection arrangement”, the distance between the light source unit and the light reception unit is an important factor. As the optical path becomes long, the scattered light generated from a wider range becomes easy to be received. Thus, an averaging effect of the velocity distribution may be increased. However, while the intensity of the forward-scattered light is strong, as the optical path, that is, a transmission distance becomes long, diffusion attenuation and absorption attenuation caused by multiple scattering become easy to be caused even in the forward-scattered light. As a result, the intensity of the received signal decreases.

[0051] As verification for verifying the effect of the intensity of the received signal and averaging, when four sensors each including, for example, the light source unit and the light reception unit are installed around the tube at equiangular intervals (every 900), a fluid having a dilute concentration is measured in an arrangement of the light source unit and the light reception unit in which a diameter of the tube is connected (hereinafter, this arrangement is referred to as a “complete transmission arrangement”). At this time, it is experimentally confirmed for the first time that an influence of the bending of the tube is less by receiving the transmitted light (adjacent sensor arrangement) in the sensors positioned adjacent to each other, measuring the fluid, and averaging four sensor signals compared to a case where four sensor signals are averaged.

[0052] With such verification, to effectively reduce the influence of the bending of the tube, it is confirmed that the distance between the light source unit and the light reception unit in the measurement needs to be shorter than the complete transmission arrangement and an optimal number of sensor elements is three or more when the plurality of integrated sensor elements is used. It can be seen that an optimal distance between the light source unit and the light reception unit in the measurement is preferably equal to or less than a distance Lth between the sensor elements adjacent to each other when three integrated sensor elements are arranged at equiangular intervals. In this case, the distance Lth between the sensor elements adjacent to each other is √3r when an outer radius of the tube (a radius of an outer diameter) is r.

[0053] Embodiments of the present disclosure exhibit an effect compared to the method of the related art in which the back-scattered light is received by using the light source unit and the light reception unit of the integrated sensor when an optical path length in the measurement becomes long and the averaging effect of the velocity distribution increases. When it is assumed that the distance between the light source unit and the light reception unit in the integrated sensor is set to d (see FIG. 11), an average optical path length in the related art that receives the back-scattered light may be estimated as a length πd/2 of an arc. Thus, it is also confirmed from the verification that the optimal distance between the light source unit and the light reception unit in the measurement is πd/2 or more. Thus, although there is some variation caused by an arrangement relationship of the light source unit and the light reception unit within the sensor element by setting the distance between the sensor elements to πd/2 or more, the optical path length with which the present disclosure exhibits the effect is achieved regardless of the details of the arrangement relationship between the light source unit and the light reception unit. Accordingly, when the plurality of integrated sensor elements is used, the distance between the sensor element that irradiates the fluid with the coherent light and the sensor element that receives the coherent light is preferably πd/2 or more and √3r or less.

[0054] When the number of sensor elements to be arranged increases, the light is considered to be received by not only the adjacent sensor element but also by the adjacent sensor element of the adjacent sensor element (first adjacent element), that is, the sensor element (second adjacent element) adjacent with the adjacent sensor element interposed between these sensor elements adjacent to each other. However, in this case, it is needless to say that the distance between the light source unit and the light reception unit in the measurement is preferably equal to or less than the distance Lth between the sensor elements adjacent to each other described above. In this case, the number of optimal sensor elements is six or more.

[0055] When the integrated sensor elements are used, the back-scattered light can be received by using the light reception unit in the identical element, and thus, the flow velocity and the flow rate may be calculated by additionally using the received signal of the back-scattered light.

[0056] Processing such as standardization of the amount of light is easy to be performed in the measurement. Thus, the number of light source units received by each light reception unit is preferably one (each light reception unit does not receive light rays from two light source units), but light rays from a plurality of light source units may be simultaneously received when the measurement accuracy is not adversely influenced.

First Embodiment

[0057] Hereinafter, a fluid measurement device according to a first embodiment of the present disclosure will be described with reference to the drawings. FIG. 1 is a cross-sectional view of an element arrangement in a fluid measurement device 101 according to the first embodiment. In this figure, components identical to the components described with reference to FIG. 7 are assigned the same reference signs, and descriptions will be omitted.

[0058] In the present embodiment, for example, vinyl chloride having an inner diameter 2r of 5.6 mm is used as a tube 1, and three integrated sensor elements SE in which a light source unit 2 and a light reception unit 3 are provided in proximity to one board are arranged around the tube 1 at equiangular intervals (intervals of 120°). In this case, distances between the light source units 2 and the light reception units 3 of the sensor elements SE adjacent to each other are equal between the three sensor elements SE.

[0059] In the present embodiment, the light source unit 2 and the light reception unit 3 in each of the sensor elements SE (SE.sub.1 to SE.sub.3) are arranged in proximity to a direction intersecting a tube axis J of the tube 1 at a predetermined angle θ as viewed from a circumferential surface side of the tube 1 as illustrated in FIGS. 2A and 2B. FIG. 2A is a diagram viewed from the circumferential surface side of the tube 1, and FIG. 2B is a cross-sectional view taken along a line IIb-IIb of FIG. 2A. Although the angle θ is set to 90° in this example, the angle is not limited to 90°, and is preferably an angle within a range of 70° to 110° (90°±20°).

[0060] In the present embodiment, the sensor elements SE.sub.1 to SE.sub.3 are arranged such that light which is emitted from the light source unit 2 of the sensor element SE.sub.1 and is transmitted through a fluid flowing through the tube 1 is received by the light reception unit 3 of the sensor element SE.sub.2. Further, the sensor elements are arranged such that light which is emitted from the light source unit 2 of the sensor element SE.sub.2 and is transmitted through the fluid flowing through the tube 1 is received by the light reception unit 3 of the sensor element SE.sub.3. Furthermore, the sensor elements are arranged such that light which is emitted from the light source unit 2 of the sensor element SE.sub.3 and is transmitted through the fluid flowing through the tube 1 is received by the light reception unit 3 of the sensor element SE.sub.1.

[0061] A surface-emitting laser element (LD) in a near infrared region is mounted, as a light source, on the light source unit 2. In this case, a stable laser element with little output variation is preferably used as the light source, but an output of the laser element may be monitored and corrected. Further, a photodiode (PD) is provided, as the light reception unit 3, adjacent to the light source unit 2 at an interval of approximately 1 to 2 mm, and the light source unit 2 and the light reception unit 3 constitute the integrated sensor element SE.

[0062] The sensor element SE is mounted on a printed circuit board that includes a signal processing unit 4. The sensor element SE mounted to the printed circuit board is referred to as a sensor head. A functional block diagram of the signal processing unit 4 is similar to the functional block diagram of FIG. 9. A calculation unit 7 is provided at a subsequent stage of the signal processing units 4.sub.1 to 4.sub.3 provided for the sensor elements SE.sub.1 to SE.sub.3. The calculation unit 7 includes a data acquisition unit 71 such as an analog-to-digital conversion circuit (ADC circuit), and a calculation processing unit 72 that performs a fast Fourier transform (FFT) or the like by using a calculator or the like.

[0063] A component arrangement of the signal processing units 4.sub.1 to 4.sub.3 may be appropriately omitted and changed depending on a measurement situation like a case where a filter in each of the signal processing units 4.sub.1 to 4.sub.3 is moved to the calculation unit 7. For example, the signal processing units 4.sub.1 to 4.sub.3 may be provided as one signal processing unit at a previous stage of the calculation unit 7.

[0064] In the fluid measurement device 101, the light emitted from the light source unit 2 of any one of the sensor elements SE is received by the light reception unit 3 of the adjacent sensor element SE. For example, the light source unit 2 of the sensor element SE.sub.1 irradiates the fluid flowing through the tube 1 which serves as a flow path with light-source light having coherency (coherent light). The scatterers S that scatter the light-source light are contained in the fluid. Vinyl chloride is transparent, and has transmittance to light-source light wavelengths. When the light-source light is scattered by the scatterers S, a part of the light-source light is received by the light reception unit 3 of the sensor element SE.sub.2. When a concentration of the scatterers S is low, the majority of the scattering is single scattering. However, as the concentration increases, the light-source light reaches the light reception unit 3 of the sensor element SE.sub.2 by performing scattering multiple times. Transmitted light that is not scattered and reflected and scattered light from a stationary tube wall are also received as well.

[0065] The light received by the light reception unit 3 of the sensor element SE.sub.2 is converted into an electrical signal. However, a beat signal is generated between light of which a frequency is changed due to Doppler shift and light of which a frequency is not changed (is changed very little), and is detected as an alternating current component. The electrical signal output by the light reception unit 3 of the sensor element SE.sub.2 is typically weak. An output current is the order of about μA. Thus, the output current is amplified by using an amplification circuit such as a transimpedance amplifier arranged on the signal processing unit 4.sub.2, and is then converted into a voltage signal having a level of, for example, approximately 1V which is easy to handle. Subsequently, the amplified signal is split, and only high-frequency (alternating current) components are extracted by causing one signal to pass through a high-pass filter. An appropriate value of approximately 1 to 100 Hz can be selected as a cutoff frequency of the high-pass filter.

[0066] After the signal which does not pass through the filter is converted into a digital signal by the ADC circuit in the data acquisition unit 71 in the subsequent calculation unit 7, high-frequency components are averaged by performing time average and are extracted as a direct current component, and is used for signal standardization or the like. This direct current component changes depending on a transmittance of a liquid, that is, the concentration of the scatterers S in the liquid, and thus, the change in the direct current component excluding the variation in the output of the laser element gives concentration information of the scatterers S. Accordingly, a calibration table is created by measuring a correspondence between a concentration of a target to be measured, a direct current component, and a flow velocity correlation feature value to be described below in the tube to be used in advance, and thus, the concentration of the scatterers S can be corrected for the flow velocity correlation feature value by using the direct current component obtained by subtracting the output variation of the laser element.

[0067] The high-frequency component typically has a value smaller than the direct current component by about single digit or double digits, and thus, the high-frequency component unnecessary for signal processing is removed by the low-pass filter after the high-frequency component is further amplified to a value appropriate for signal processing by a secondary amplifier, and is sent to the calculation unit 7. A cutoff frequency of the low-pass filter varies depending on the flow velocity of the scatterers S, but may be, for example, 20 MHz.

[0068] In the calculation unit 7, the high-frequency component from the signal processing unit 4.sub.2 is converted into a digital signal by the ADC circuit in the data acquisition unit 71. The high-frequency component converted to the digital signal is sent to the calculation processing unit 72. The calculation processing unit 72 obtains a power spectrum by performing Fourier transform on the high-frequency component by FFT and calculating a power of the high-frequency component. When the power spectrum is obtained, the sum of products of a power P and a frequency f is calculated over a predetermined frequency range by Equation (1) represented below, and is used as a flow velocity correlation feature value ν.

Equation (1)

N=Σ(P(fi)×f)  (1)

[0069] As described above, it has been described that the light from the light source unit 2 of the sensor element SE, is received by the light reception unit 3 of the adjacent sensor element SE.sub.2 through the fluid flowing through the tube 1. However, even when the light from the light source unit 2 of the sensor element SE.sub.2 is received by the light reception unit 3 of the adjacent sensor element SE.sub.3 through the fluid flowing through the tube 1 and when the light from the light source unit 2 of the sensor element SE.sub.3 is received by the light reception unit 3 of the adjacent sensor element SE.sub.1 through the fluid flowing through the tube 1, the flow velocity correlation feature values ν are obtained as well.

[0070] The calculation processing unit 72 achieves fluid measurement by adding a calculation of multiplying three flow velocity correlation feature values ν by a calibration coefficient, calculating, for example, a value of the average flow rate from the three flow velocity correlation feature values ν to which this calculation is applied, and sending the calculated value of the average flow rate to a result display unit 6. A correction calculation of correcting frequency characteristics of the amplification and filter circuits can be appropriately performed in calculating the flow velocity correlation feature values ν. The ADC and the calculation processing are appropriately designed, and thus, the correction calculation or the like corresponding to an intensity of incident light and a degree of reflection using the direct current component or the like can be performed.

[0071] In the present embodiment, the integrated sensor elements SE are arranged around the tube 1 at equiangular intervals, and the light emitted from the light source unit 2 of any one sensor element SE is received by the light reception unit 3 of the adjacent sensor element SE through fluid flowing through the tube 1. Specifically, the scattered light is received by using the light reception unit 3 of the adjacent sensor element SE. Accordingly, the scattered light can be received from a fluid region of a range wider than in the related art, and the velocity distribution can be averaged over a wider region. The received signals of the plurality of sensor elements SE are averaged, and thus, the fluid measurement can be performed.

[0072] As a result, in the present embodiment, the influence of the change in the velocity distribution caused by the bending of the tube 1 can be reduced by 12% or more than in the related art. At this time, a transmitted light detection arrangement capable of selectively receiving forward-scattered light having a strong scattering intensity is used, and thus, an optical path becomes larger than in the related art. Accordingly, the influence of attenuation of the scattered light is canceled, and thus, a scattering signal having a magnitude approximately identical to a magnitude in the related art can be received.

[0073] In this embodiment, the three sensor elements SE (three sensors) are arranged around the tube 1 at equiangular intervals. As illustrated in FIG. 3A, four sensors may be arranged. As illustrated in FIG. 3B, five sensors may be arranged. As illustrated in FIG. 3C, six sensors may be arranged. In this case, the influence of the change in the velocity distribution caused by the bending of the tube 1 can be reduced by using four sensors by 14% or more, by using five sensors by 15% or more, and by using six sensors by 16% or more than in the related art.

[0074] In this embodiment, the light from the light source unit 2 of the sensor element SE.sub.1 is received by the light reception unit 3 of the sensor element SE.sub.2. The light from the light source unit 2 of the sensor element SE.sub.2 is received by the light reception unit 3 of the sensor element SE.sub.3. The light from the light source unit 2 of the sensor element SE.sub.3 is received by the light reception unit 3 of the sensor element SE.sub.1. Meanwhile, as illustrated in FIG. 4A, the light rays from the light source units 2 of the sensor elements SE.sub.1 and SE.sub.3 may be received by the light reception unit 3 of the sensor element SE.sub.2. The light rays from the light source units 2 of the sensor elements SE.sub.1 and SE.sub.2 may be received by the light reception unit 3 of the sensor elements SE.sub.3. The light rays from the light source units 2 of the sensor elements SE.sub.2 and SE.sub.3 may be received by the light reception unit 3 of the sensor element SE.sub.1. The same applies to cases where four sensors, five sensors, and six sensors illustrated in FIGS. 3A, 3B, and 3C are used (see FIGS. 4B, 4C, and 4D).

Second Embodiment

[0075] FIG. 5 illustrates a cross-sectional view of an element arrangement of a fluid measurement device according to a second embodiment of the present disclosure.

[0076] In the second embodiment, six integrated sensor elements SE (SE.sub.1 to SE.sub.6) are arranged around a tube 1 at equiangular intervals (intervals of 60°).

[0077] In the second embodiment, the scattered light is received by not the adjacent sensor element (first adjacent element) SE but the sensor element adjacent to the adjacent sensor element SE, that is, the sensor element (second adjacent element) SE adjacent with the sensor element SE interposed between these sensor elements.

[0078] In the second embodiment, as illustrated in FIG. 6, the flow rate or the flow velocity is calculated by receiving the back-scattered light by using the light reception unit 3 in the identical sensor element SE and averaging the received signals together with a received signal of the back-scattered light.

[0079] In this manner, the influence of the change in the velocity distribution caused by the bending of the tube 1 can be reduced by 18% or more than in the related art.

[0080] It has been described in the second embodiment that the scattered light is received by using the second adjacent element and the received signal of the back-scattered light is also used to calculate the flow rate or the flow velocity. Alternatively, the scattered light may be received by using the first adjacent element, and a signal of this scattered light may also be used to calculate the flow rate or the flow velocity. In this case, the influence of the change in the velocity distribution caused by the bending of the tube 1 can be reduced by 20% or more than in the related art.

Third Embodiment

[0081] A fluid measurement device according to a third embodiment of the present disclosure has an arrangement and measurement configuration similar to the arrangement and measurement configuration of the second embodiment, but focuses on the fact that the direct current component corresponding to the transmitted light increases or decreases depending on the concentration of the scatterers S having light absorption characteristics as described above.

[0082] Specifically, after the calibration table is created by measuring the correspondence between the concentration of the target to be measured, the direct current component, and the flow velocity correlation feature value in the tube to be used in advance, the calculation unit 7 corrects the flow velocity correlation feature value caused by the change in the concentration of the scatterers S by comparing the direct current component obtained by subtracting the output variation of the laser element with the calibration table. Accordingly, the flow velocity correlation feature value, for example, the average flow rate of the fluid in the tube that does not depend on the concentration of the scatterers S can be measured.

[0083] In this manner, in the third embodiment, the influence of the change in the velocity distribution caused by the bending of the tube 1 can be reduced by 18% or more than in the related art as in the second embodiment. The variation in the value of the flow rate dependent on the concentration of the scatterers S can be reduced by 15% or more. Accordingly, the variation in the value of the flow rate can be reduced by a total of 22% or more as the effect of reducing the variation in the value of the flow rate.

EXPANSION OF THE EMBODIMENTS

[0084] The present disclosure has been described above with reference to the embodiments, but the present disclosure is not limited to the above-described embodiments. Various changes that can be understood by a person skilled in the art within the scope of the present disclosure can be made to the configuration and details of the present disclosure.

REFERENCE SIGNS LIST

[0085] 1 . . . Tube, 2 . . . Light source unit, 3 . . . Light reception unit, 4 (4.sub.1 to 4.sub.3) . . . Signal processing unit, 41 . . . Amplifier, 42 . . . Filter, 6 . . . Result display unit, 7 . . . Calculation unit, 71 . . . Data acquisition unit, 72 . . . Calculation processing unit, SE (SE.sub.1 to SE.sub.6) . . . Sensor element, S . . . Scatterer, 101 . . . Fluid measurement device