DE4142938C2 - Device for measuring turbidity and solid concentrations in liquids - Google Patents

Description

The invention relates to a device according to the Preamble of claim 1.

Such a device is through DE-OS 23 63 432 be knows. The beam lies with this stray light opacimeter lengang in one plane and the windows stand up vertically this level. The beam coming from the respective light transmitter len bundle is in the opening area of the Barrier (aperture) partially reflected and gets to least proportionately to the respective below the relevant light transmitter located light receiver. There are also additional through a second diaphragm arranged transversely to the first diaphragm caused reflections. These reflected light rays affect the measurement results flow and therefore lead to inaccurate measurements keiten. In addition, such a stray light opacimeter is emp sensitive to pollution, so that transmitter and receiver in must be cleaned mechanically at relatively short intervals.

Through the US-PS 3,510,666 a turbidity meter with a adjustable light source known, also in one plane works and windows standing perpendicular to this plane points and contains a barrier. In the case on the transmitter side existing impurities, e.g. B. algae, sprinkle them Beam of light on the housing inner wall, and from this ge reaches light on the stray light receiver and deceives a cloudy exercise in the medium. Furthermore, deposits on the Direct light receivers cause backscattering on the barrier (aperture) is reflected and on the litter light receiver arrives. The pollution sensitive Such a turbidity meter makes practically daily mechanical cleaning is required, which is done automatically by can go.

The invention has for its object a device Generic type to improve that stray light byways safely prevented and thus influencing the Measurement results by reflect due to scattered light xions can be avoided.

This object is according to the invention Features of claim 1 solved.

The advantage of these measures is that they are not intended scattered light is emitted into the free medium without to strike other parts of the probe. By ver The use of spreading discs ensures that the spatial Distribution of light even when the windows are dirty lasts. This is for the ratio measurement of Be interpretation.  

Further training and practical developments of the Erfin are characterized in the subclaims.

The invention will he in the following with reference to the drawing purifies. It shows

Fig. 1 is a perspective view of the head probes,

Fig. 2 is a view of the probe head of FIG. 1 from above,

Fig. 3 is a view along section AA of Fig. 2,

Fig. 4 is a view along section B-B through FIG. 2,

Fig. 5 is a view of a probe head accordingly FIG. 1, but having a split partition wall,

Fig. 6 shows a cross section through a probe head with both sides zugängiger trichterförmi ger recess,

Fig. 7 is a view of the probe head of FIG. 6 from above,

Fig. 8 is a partial circuit of the evaluation unit.

In Fig. 1, 10 with a funnel-shaped Ausneh tion 14 designated probe head. The funnel-shaped recess 14 is divided into two chambers 12, 13 by a continuous partition wall 11 . The chamber 12 is assigned a light transmitter 15 and a light receiver 17 , as is the chamber 13, a light transmitter 16 and a light receiver 18th The light transmitters 15 and 16 are accommodated in receiving bores or the like recesses in the boundary wall 10 'of the probe head 10 , as are the light receivers 17 and 18 . The light transmitter 15 is, based on the vertical central axis of the trich ter-shaped recess 14 and covered by the partition 11, covers the light receiver 18 diametrically opposite, as does the light transmitter 16 of the light receiver 17 (see FIG. 4). Each light transmitter 15 , 16 and each light receiver 17 , 18 is a diffuser 19 , 20 , 21 , 22 , for example in the form of a milk glass plate, spatially arranged.

In the first phase, the light transmitter 15 emits light, and the light receiver 17 corresponding to it receives, as shown in FIG. 4, direct light as reference light. From FIGS. 1 and 3 it can be seen that all surfaces, which are illuminated by the light transmitter 15 are dimmed by the partition wall 11. Accordingly, the light receiver 18 receives only scattered light. In the second phase, the light transmitter 16 comes into operation, and the light receivers 17 and 18 interchange their task. That is, the light receiver 18 receives direct reference light, the light receiver 17, however, only scattered light. Different sensitivities of the light receivers 17 and 18 are thus eliminated.

The lenses 19 to 22 cause a direction-independent reduction in intensity even with uneven soiling of the light transmitter and / or the Lichtemp catcher. Soiling has just as little impact as aging. In contrast, relatively large errors can occur when using clear windows or windows.

The end face of the partition 11 forming a central wall is provided with at least one groove-shaped recess 23 or a notch in order to prevent light from passing over the edges in the case of a slimy coating (waste water measurement).

The partition 11 can be arranged around its longitudinal axis 24 rotatably or swivel bar and manually or motorized who the z. B. for a self-test to shade off individual areas or wipe off coarse dirt.

In the formation of a probe head according to Fig. 5, the dividing wall 11 'is partially broken and the funnel-shaped recess from 14 accessible from both sides, so that a flow passage 28 is provided and the probe 10 is channel transversely used.

FIGS. 6 and 7 show an embodiment of the probe head 10 in which trich terförmigen in the center of-reach both sides of recess 14 acting as a diaphragm center rod 25 with diametrically opposed, extending in the axial direction of the central rod 25 grooves 26, 26 ', 27 , 27 'is arranged.

The lenses 19 , 20 , 21 , 22 are preferably used in countersunk holes 29 , 30 , 31 and 32 and attached, for example, by gluing. The countersinks 29 to 32 prevent irradiation of the areas around the light emitters, as does indirect light reception via the areas around the light receivers. In some cases, this means that a central rod is sufficient as an aperture.

The preferably arranged in a uniform spatial distribution on the circumference of the funnel-shaped recess 14 , light transmitters 15 , 16 and light receivers 17 , 18 are switched on alternately, the light transmitters formed, for example, as transmitter diodes being clocked at a suitable frequency, for example at 1 KHz . The optical axes of the light transmitter and the light receiver are directed towards the opening of the funnel-shaped recess 14 and preferably form a normal to the associated surface line of the recess 14 .

As can be seen from FIG. 8, the signal generated in one of the light receivers 17 , 18 and polled in the transmission clock is logarithmized by means of a logarithmic amplifier 33 . The ratio of the forward scattered light to the logarithmic, undistorted reference light (reference signal) is formed in the following differential amplifier 34 (log A - log B = log A / B). A voltage / frequency converter 35 is connected to the output of the differential amplifier 34 , followed by an RC element (high-pass filter) 36 . During the blueprints, an automatic zeroing takes place by means of an amplifier 37 which is bridged on the input and output sides by a capacitor 38 . This capacitor stores the zeroing status during the measuring period (compensation of extraneous and daylight as well as the blocking currents of the components).

The signal logarithm enables a simple ratio formation in the differential amplifier 34 and ensures a very large working range. The voltage / frequency conversion of the log A / B enables interference-free signal transmission and a large useful area.

A discriminator 39 is connected to the two inputs of the differential amplifier 34 via a resistor in order to report a fault when the signal is too low.

The partition 11 11 ( FIG. 1), which advantageously consists of elastic material or contains an edge boundary of such a material, enables not only a cleaning function but also a check of the function of the light transmitter and the light receiver. For this purpose, the partition 11 only needs to be pivoted ver into the corresponding test position.

The voltage source for the evaluation device is designated 40 .

Claims (15)

1. Device for measuring turbidity and solid concentrations in liquids with the aid of a probe, in the head of which two spatially spaced light transmitters are accommodated, each of which is assigned a light receiver, the light transmitters being operated alternately and a barrier being arranged on the probe head in such a way, that light in the direct beam path from the operating light transmitter only reaches the respectively assigned light receiver and only stray light strikes the not assigned light receiver, and the signals generated in the light receivers are fed to an evaluation unit, characterized in that the end face the probe head ( 10 ) is provided with a funnel-shaped recess ( 14 ), the boundary wall ( 10 ') of which opens into the recess ( 14 ) with holes for receiving the light transmitter ( 15 , 16 ) and the light receiver ( 17 , 18 ) whose optical A axes are directed towards the opening of the recess ( 14 ), and that the light transmitters ( 15 , 16 ) and the light receivers ( 17 , 18 ) are each spatially arranged with a diffuser ( 19 , 20 , 21 , 22 ). 2. Device according to claim 1, characterized in that the barrier as a the funnel-shaped recess ( 14 ) in two chambers ( 12 , 13 ) dividing partition ( 11 ) is formed and in each chamber ( 12 , 13 ) a light transmitter ( 15th , 16 ) and this directly opposite a Lichtemp catcher ( 17 , 18 ) is arranged. 3. Device according to claim 1 or 2, characterized in that the barrier or partition ( 11 ) is designed as a center wall rotatable or pivotable about the vertical central axis of the funnel-shaped recess. 4. Device according to claim 3, characterized in that the middle wall can be actuated by a motor. 5. Device according to claim 1, characterized in that the funnel-shaped recess ( 14 ) on opposite sides for the liquid to be measured freely accessible and the barrier is designed as a partially perforated partition ( 11 '). 6. Device according to claim 1, characterized in that the barrier is embodied by a central rod ( 25 ). 7. Device according to one of the preceding claims, characterized in that the light transmitter ( 15 , 16 ) and the light receiver ( 17 , 18 ) in a symmetrical distribution in the wall of the funnel-shaped recess ( 14 ) are housed un. 8. Device according to one of the preceding claims, characterized in that the barrier ( 11 , 11 ', 25 ) is provided on its end face with at least one groove-shaped recess ( 23 ). 9. Device according to claim 6, characterized in that the shading central rod ( 25 ) with diametrically opposite, extending in the axial direction of the central rod longitudinal grooves ( 26 , 26 ', 27 , 27 ') is provided. 10. Device according to one of the preceding claims, characterized in that the spreading disks ( 19 , 20 , 21 , 22 ) are inserted into counterbores in the inner wall of the funnel-shaped recess ( 14 ). 11. Device according to one of the preceding claims, characterized in that the optical axes of the light transmitter ( 15 , 16 ) and the light receiver ( 17 , 18 ) form at least approximately a normal to the associated surface line of the funnel-shaped recess ( 14 ). 12. Device according to one of the preceding claims, characterized in that the signals generated in the light receivers ( 17 , 18 ) for ratio formation via a logarithmic amplifier ( 33 ) are fed to a differential amplifier ( 34 ), with the logarithmic input at its reference Reference signal from the light receiver acted upon in the direct beam path is present. 13. The device according to claim 12, characterized in that a voltage / frequency converter ( 35 ) is connected to the output of the differential amplifier ( 34 ). 14. The device according to claim 12 or 13, characterized in that a discriminator ( 39 ) is connected to the inputs of the differential amplifier ( 34 ) via a resistor for fault reporting when the signal is too low. 15. Device according to one of claims 12 to 14, characterized in that the output of the logarithmic amplifier ( 33 ) is zeroed in the blueprints.