NL1003961C2 - Transducer to measure opacity of fluid - Google Patents

Abstract

The fluid to be tested passes into (P1) a cylindrical tube (2) through a radial import port (3). In the tube it swirls around a fluorescent light source (5) which runs the length of the tube. The fluid leaves (P2) the tube via another radial port (4). Light from the source passes through the fluid to an electronic sensor (6), via a radial transparent rod (7). During a test, the rod is moved (P3) between two radial positions (8, 10). Measurements are taken at both positions and related to take account of the distance moved (A).

Description

Short designation: Method and device for determining transmission of a fluid, as well as a sensor suitable for such a device.

The invention relates to a method for determining transmission of a fluid, in which light from a light source is absorbed through the fluid by means of a light-sensitive sensor arranged opposite the light source and the light quantity observed by the sensor is used for determining of the transmission of the fluid.

The invention also relates to a device for determining transmission of a fluid, which device is provided with a light source and a light-sensitive sensor arranged opposite the light source.

The invention further relates to a sensor suitable for such a device.

In such a method and device known per se, a light source and a sensor are arranged opposite one another, the fluid being located between the light source and the sensor. To determine the transmission of the fluid, light from a light source is measured with the aid of a light-sensitive sensor and, based on the expected amount of light emitted, the distance between the light source and the sensor and the amount of light measured by the sensor, the transmission of the fluid present between the light source and the sensor.

However, if the light intensity of the light source decreases due to aging or the light source and / or sensor becomes contaminated by the liquid, the calculated transmission will no longer correspond to the actual transmission of the fluid.

The object of the invention is to provide a method in which the transmission of the fluid can nevertheless be correctly determined.

This object is achieved in the method according to the invention in that, for determining the transmission at at least two different distances between a light source and a sensor, a quantity of light transmitted by the fluid is measured, and then the transmission based on the two light quantities observed of the fluid traversed by the light is calculated.

* 00J95 1 2

In this way, the calculated transmission depends only on the light transmittance of the fluid. The amount of light emitted by the light source and / or contamination of the sensor no longer has any influence on determining the transmission of the fluid traversed by the light.

An embodiment of the method according to the invention is characterized in that the photosensitive sensor and the light source are displaceable relative to each other from a first predetermined mutual distance to a second predetermined, other mutual distance and vice versa, whereby at both mutual distances the light from the light source is measured by means of the sensor, after which the transmission of the fluid over the difference distance between the first and second distance is then calculated on the basis of the measured light quantities.

In this manner, the light emitted by the light source can be measured by means of a single sensor and a single light source at two or more mutual distances.

Another object of the invention is to provide a device in which the above-mentioned drawbacks of the known devices are avoided.

This object is achieved in the device according to the invention in that the light source and the sensor are displaceable relative to each other from a first predetermined mutual distance to a second, other predetermined mutual distance and vice versa.

With the aid of such a device light can be measured at two different distances in the fluid from the light source in a simple manner with the aid of the sensor for determining the transmission of the fluid over the difference distance between the first and second distance. .

The invention will be further elucidated with reference to the drawings, in which: fig. 1 shows a cross-section of the device according to the invention, fig. 2A and 2B show a sensor of the device shown in fig. 1 in different positions, Fig. 3 shows a first cross section of a sensor of the device shown in Fig. 1, Fig. 4 shows a second cross section of a sensor of the device shown in Fig. 1, Fig. 5 shows a control diagram of the device shown in Fig. 1 device shown.

In the figures, corresponding parts are provided with the same reference numerals.

Fig. 1 shows a device 1 according to the invention, which is provided with an elongated tube 2 which has a fluid supply opening 3 on one side and a fluid discharge opening 10 4 on another side. The fluid supply opening 3 and the fluid discharge opening 4 are connected to fluid supply and discharge pipes, respectively, by means known per se. An elongated light source 5 is arranged in the tube 2, which comprises, for example, a UV lamp. Between the fluid supply opening 3 and the fluid discharge opening 4, the tube 2 is provided with a sensor 6 with the aid of which the light from the light source 5 can be measured. Before further explaining the sensor 6 in the device 1, the function of the device 1 and determining the transmission of a fluid will first be explained in more detail.

The device 1 is used for disinfecting a fluid, wherein fluid is led through the fluid supply opening 3 into the tube 2 in a direction indicated by arrow P1 and is discharged from the tube 2 in the direction indicated by arrow P2 through the fluid discharge opening 4. Bacteria present in the fluid are at least partially killed by the UV light emitted by the light source 5. The reduction in the number of bacteria depends, inter alia, on the time during which the fluid is exposed to the UV light and the intensity of the UV light. The time during which the fluid is exposed to the UV light depends, inter alia, on the length of the light source in the tube 2 and the flow velocity through the tube 2. The intensity of the UV light at a specific place in the tube depends on the UV power of the light source 5, the distance from the light source 5 and the transmission of the fluid between the light source and the determined location in the tube 2.

The light source can be considered as a line source because the distance to the light source is many times smaller than the lamp length L. The light intensity Ix # at a certain location (x, φ) in the tube 2 due to radiation is then dependent on the distance R between the determined location (x, φ) and the light source and the transmission of the fluid, 1 0 0 * M 1 4 where T10 is a basic transmission of the fluid over a distance of 10 mm and at a light source emitting parallel light beams . The relationship is established by the formula below.

T _ m i Ιχ '♦ "2 π RL 10 5 where P is the total UV power emitted by the UV lamp.

The transmission of a fluid over a length L is defined as the quotient of the intensity I after the passage of the fluid and the intensity I0 for the passage of the fluid, or T - - = e '€ * £ * 0 10 where € the absorption coefficient of the fluid is at a given wavelength λ of the light.

In order to obtain insight into the reduction of the number of bacteria in the fluid, it is therefore important, inter alia, to determine the transmission of the fluid present in the tube. For determining the transmission, device 1 is provided with the sensor 6, which will be explained in more detail with reference to Figures 2A, 2B, 3 and 4. The sensor 6 comprises a translucent pin 7 displaceable in directions indicated by double arrow P3, which extends radially on the light source 5. In order to determine the transmission of the fluid present in the tube 2, the intensity is determined by the sensor 6 at least two different mutual distances in the fluid. First, the light intensity is measured at a dotted line 8, at a first distance from the light source 5, with an end 9 of the pin 7 extending to the dotted line 8 and 25, then the pin 7 is turned into an arrow P3 direction indicated until one end 9 of the pin 7 is in a position indicated by a dotted line 10, located at a second distance from the light source 5. The first position 8 and the second position 10 are at a different distance A from each other. The transmission of the fluid between the first position 8 and the second position 10 can then be determined by dividing the light intensity I2 measured at the second position 10 by the light intensity I2 measured at the first position 8. The transmission determined in this way is independent of the power P emitted by the 1003961 light source 5. This can easily be demonstrated in the following manner.

The transmission between positions 10 and 8 can be represented as follows; where I, the measured intensity at the first position 5 is 8 and I2 the measured intensity at the second position 10 1s.

P

rr _ 7, "^ 2 _ 7, Γ« "I, - k ...... ~ p --¾" * ιΊζ] Tl ° 2 * J ^ L 10 where k is a constant depending on the geometry of the device.

This shows that the transmission is independent of the lamp power P.

In the same way, it can be shown that the transmission is independent of contamination of the end 9 of the quartz stick 7. If only a fraction y of the incident light is transmitted due to contamination by the quartz stick 7, the two measured intensities are 1m compared to the unpolluted situation

Ini = JiY and * m = J2Y The following applies to the transmission:

j. _ ^ m _ J2Y m ^ 2 lm -TiY

It follows that the transmission is independent of the degree of contamination on the pin 7.

If desired, it is also possible to measure the light intensity at three or more different distances from the light source 5, whereby it can be determined whether the transmission of the fluid is constant over the entire diameter of the tube.

Fig. 2A and 2B show the sensor 6 of the device shown in FIG. 1. The sensor 6 is provided with a light measuring unit 11 which comprises a light-sensitive element such as a photodiode which is located at the level of the reference numeral 12. The photosensitive element 12 is not shown in detail in Figures 2A and 2B, but may comprise any photosensitive element known per se. The sensor 6 further comprises a motor 13 which is coupled via a transmission shown in FIGS. 3 and 4 to the pin 7 and by means of which the pin 7 can be moved in directions indicated by arrow P3. The sensor 6 is further provided with a coupling piece 14 with the aid of which the sensor 6 can be coupled to the tube 2 in a leak-proof manner. The coupling piece 14 is known per se and will therefore not be further elucidated. Fig. 3 shows a cross section 10 of the sensor 6 according to the invention. The light-guiding pin 7, which is made of, for example, quartz, is located coaxially in a sleeve 14 which extends from the light measuring unit 11 into the tube 2. A sleeve-shaped member 15 is fitted around the pin 7 and is provided with a sealing element 16, by means of which fluid can be prevented from penetrating from the tube 2 into the light measuring unit 11. The sleeve-shaped member 15 is provided with a rack 17 extending in directions indicated by arrow P3. The sleeve 14 is provided with a square recess 18, the function of which will be explained in more detail with reference to Fig. 4.

FIG. 4 shows a second cross section of the sensor 6 according to the invention, showing a pinion 19 cooperating with the rack 17. The pinion 19 is connected via a shaft coupling 20 to an output shaft 21 of a transmission (not shown) which is connected to an output shaft 22 of the motor 13, indicated with a center line. By driving the motor 13 on the output shaft 22, the shaft 21 is rotated about the axis 23, whereby the pinion 19 extending through the recess 18 is driven and the rack 17 engaging the pinion is moved in a direction indicated by arrow P3.

FIG. 5 shows a control diagram of the device shown in FIG. 1, showing a control unit 24 coupled to the sensor. The control unit 24 comprises a controller 25 using which the motor 13 is controlled at a time stored in the controller 25 to positions also stored in the controller, whereby a first or second distance between sensor and light source is set. Light quantities measured by the sensor 6 are converted into a specific current (milli amperes) in the light measuring unit 11 and passed on to a memory unit 26. In the memory unit 26, the measured light intensity 1003961 7 is coupled to information from the controller 25 concerning the position of the measurement taken. The information concerning the intensities I2, Ij at the second and first positions, respectively, originating from the memory unit 26 is then supplied to a divider 27 which divides the measured intensity from each other, from which the transmission of the fluid over the difference distance between the first and second position is determined by multiplication by a correction factor, which depends on the shape of the light source, the position of the sensor relative to the light source and further geometric factors.

10 It is also possible to move the light source instead of the sensor. Furthermore, it is possible to measure the light intensity of the light emitted by the light source with the aid of two sensors which are arranged at the first and second distance from the light source. However, this has the drawback that the light coming from the light source goes to the sensors via different optical paths and that signal processing at the sensors cannot be realized by one and the same electronics.

1003961

Claims (10)

A method for determining transmission of a fluid, wherein light from a light source is absorbed through the fluid by means of a light-sensitive sensor 5 arranged opposite the light source and the light quantity observed by the sensor is used to determine the transmission of the fluid, characterized in that, for determining the transmission at at least two different distances between a light source and a sensor, an amount of light transmitted by the fluid is measured, and then, based on the two amounts of light observed, the transmission of the the light traversed fluid is calculated. 2. Method according to claim 1, characterized in that the photosensitive sensor and the light source are displaceable relative to each other from a first predetermined mutual distance to a second predetermined, other mutual distance and vice versa, wherein at both mutual distances the light from the light source is measured with the aid of the sensor, after which the transmission of the fluid over the difference distance between the first and second distance is then calculated on the basis of the measured light quantities. Method according to claim 1, characterized in that a light-sensitive sensor is provided at any distance by means of which the light from the light source is measured. 4. Device for determining transmission of a fluid, which device comprises a light source and a light-sensitive sensor disposed opposite the light source, characterized in that the light source and the sensor are movable relative to each other from a first predetermined spacing to a second, other predetermined spacing and vice versa. 5. Device according to claim 4, characterized in that the device is provided with a control unit for determining transmission of the fluid over a difference distance between the first and second distance on the basis of the light quantities measurable with the aid of the sensor the first and second spacing. 6. Device as claimed in claims 4-5, characterized in that the sensor comprises a light-guiding pin and a photosensitive element situated opposite one end of the light-guiding pin, wherein the pin is movable relative to the light-sensitive element. 1003961 1% Device according to claim 6, characterized in that the photosensitive element comprises a photodiode. 8. Device as claimed in any of the claims 4-7, characterized in that the light source comprises a UV lamp. 9. Device as claimed in any of the claims 4-8, characterized in that the device is provided with a fluid flow tube, in which the light source is arranged, wherein the reciprocally displaceable light-guiding pin is connected to a drive mechanism arranged outside the tube . Sensor suitable for a device according to any one of the preceding claims. 1003961