DE19544851A1 - Floating mini-laboratory for fluids analysis - Google Patents

Abstract

An apparatus for testing fluid samples comprises: (i) analytical devices within a sample chamber (5); (ii) a filling and emptying device intaking and ejecting fluids; (iii) a measurement buoy housing (2) immersed in the fluid; a chamber opening (7) providing a passage to the exterior of the buoy; (iv) a control and evaluation unit (4) removable from the buoy and connected by lines (3); and (v) a gas interchange unit connected to the sample chamber (5), to introduce and extract gas, inducing and ejecting the sample as necessary.

Description

The invention relates to a device for examination of liquid samples, with a sample chamber in which at least one examination device is arranged, with a control and evaluation device, and with one Filling and emptying device, each with one Liquid sample from a quantity of liquid Sample chamber supplied and removed from this.

A typical application of such Examination devices is the wastewater analysis Here it is necessary to take a liquid sample to be taken from the wastewater and in the sample chamber examine, often with a reagent in the sample chamber added and a reaction of the liquid sample is carried out and measured for measurements within the sample chamber are usually gas or ion-selective sensors, pH sensors, photo-optical Sensors and other sensors used. One at the The resulting gaseous reaction product can be supplied to a measuring unit provided for this purpose, for example a CO₂ detector.

The liquid sample must be used to fill the sample chamber from the amount of liquid available, for example from the wastewater, via a supply line  and a pump in the sample chamber arranged in the device be promoted. This is done in the opposite direction Empty the sample chamber too Liquid lines.

Especially when examining wastewater samples it is inevitable that those for filling and emptying necessary liquid lines in the sample chamber pollute. There is a risk that this Add lines if there is no regular flushing takes place, which involves a relatively large effort is.

The object of the invention is therefore a device of train the genus mentioned so that the Filling and emptying the sample chamber in particular can be done easily, without the risk of a There is clogging of liquid lines and a considerable flushing effort is required.

This object is achieved in that the Sample chamber in one in the amount of liquid submersible buoy is arranged and over a Chamber opening in connection with the outside of the measuring buoy stands that at least one examination facility in the Measuring buoy is arranged that the control and Evaluation device arranged away from the measuring buoy and connected to it via lines, and that the Filling and emptying device a gas exchange device with which a displacing the liquid sample Gas is introduced into and removed from the sample chamber becomes.

By moving the sample chamber from an outside the liquid arranged measuring device in a The amount of liquid immersed in the buoy is eliminated Need for pollution-prone  Liquid lines. The within the to be examined Liquid arranged sample chamber can on direct Paths are filled and emptied without this any liquid lines would be required. Via lines that the measuring buoy with the removed for this connect the arranged control and evaluation device, - in addition to electrical measurement signals and possibly electrical control pulses or electrical Drive energy - possibly reagents and / or gases transported. The transport of these substances is in the Compared to transporting liquid samples entirely easily and does not lead to the risk of contamination or constipation.

Since at least the section containing the sample chamber the measuring buoy is immersed in the liquid to be examined, it is sufficient to fill the sample chamber, which in the To remove gas contained in the sample chamber, d. H. in the simplest case, the sample chamber to the atmosphere to open. The hydrostatic pressure of the buoy surrounding liquid presses the liquid sample into the Sample chamber. To empty the sample chamber, use the gas exchange device gas, for example air, under Pressure applied to the liquid sample from the Push out the sample chamber. The intensity of the Gas supply can be chosen so that there is a turbulent swirling of the liquid sample in the Sample chamber comes, which makes it very easy effective rinsing and cleaning of the sample chamber and the Chamber opening takes place. This causes constipation Chamber opening largely excluded.

Preferably there is at least one in the measuring buoy Reagent dosing device opening into the sample chamber arranged with one outside the measuring buoy arranged reagent source via a hose line connected is. This also allows in the sample chamber  such examinations are carried out - which like this this is often the case, especially when it comes to waste water analysis is - a chemical reaction of the liquid sample with require one or more reagents. For the Transport lines for liquid or gaseous There is no risk of constipation in reagents; you can therefore also over relatively large distances between the measuring buoy and a supply unit will.

Preferably, the gas exchange device has one in the Measuring buoy arranged and connected to the sample chamber Gas pump on with an outside of the buoy arranged gas source connected via a hose line can be. Such a hose line is subject also no risk of constipation and can therefore can be easily laid over a greater distance.

According to a preferred embodiment of the invention provided that the chamber opening of the sample chamber in a the settling chamber below it opens into the measuring buoy, which has a bottom opening. Especially with the Examination of the aqueous fraction of activated sludge Wastewater treatment plant it is necessary to check the solids content before Detach investigation. That of the sample chamber upstream sedimentation chamber serves the To take a liquid sample during a filling break, so that the activated sludge content in the lower area of the Settling chamber settles or concentrates before on this way pre-cleaned liquid sample into the Sample chamber is let in.

About this timing of the filling of the sample chamber to control is preferably in the range of Settling chamber connecting to the sample chamber Chamber opening a level sensor arranged with the Control for the gas exchange device is connected.  

The level sensor determines when the Sedimentation chamber is filled. In this state the Filling process interrupted so that the sludge content can settle in the settling chamber. After this The filling process becomes a predetermined period of time continued.

For the investigation of activated sludge, in which constantly Gas bubbles rise, it has proven to be useful at a distance below the bottom opening of the settling chamber in the vertical projection on all sides over the Arrange bumpers extending beyond the bottom opening. This deflector prevents gas bubbles in the Sedimentation chamber and enter the sample chamber.

According to another advantageous embodiment of the Invention is provided that the sample chamber with a Gas supply line for a reaction gas is connected that the Chamber opening can be closed by a valve and that a gas discharge line closable by a valve the sample chamber to one away from the measuring buoy arranged evaluation device leads. That’s it possible, the recorded in the sample chamber Liquid sample after closing the chamber opening subject to a reaction with the reaction gas and this reaction gas then from the buoy to the remotely located to guide perform the required analysis there.

The following are exemplary embodiments of the invention explained in more detail, which are shown in the drawing. It shows:

Fig. 1 in a vertical section of a device for determining the NH₄ content of waste water,

Fig. 2 shows a section along the line II-II in Fig. 1,

Fig. 3 + 4 in a representation corresponding to Fig. 1 and an apparatus for the determination of nitrate and phosphate content of a waste water sample 2

Fig. 5 + 6 in views corresponding to FIGS. 1 and 2, a device for the determination of the nitrogen content of waste water and

Fig. 7 + 8 in representations corresponding to Figs. 1 and 2, an apparatus for determining the TOC content of waste water.

The device shown in FIGS. 1 and 2 for determining the NH₄ content of water has a measuring buoy 2 which can be immersed in the wastewater 1 to be examined and which is connected via lines 3 , which are only indicated schematically, to a control and evaluation device 4 arranged away therefrom . In the measuring buoy 2 there is a sample chamber 5 which receives the wastewater sample to be examined. An agitator 6 projects into the sample chamber 5 . The sample chamber 5 has a chamber opening 7 at the bottom through which the sample chamber 5 can be filled and emptied. Below the chamber opening 7 , a settling chamber 8 is arranged in the measuring buoy 2 , the volume of which is larger than that of the sample chamber 5 . The settling chamber 8 has a bottom opening 9 , below which a deflector body 10 is arranged at a distance. In the vertical projection, the deflector body 10 projects on all sides beyond the bottom opening 9 and has the effect that the gas bubbles rising during an activated sludge examination cannot enter the settling chamber 8 through the bottom opening 9 . A fill level sensor 11 is arranged in the area of the chamber opening 7 connecting the settling chamber 8 to the sample chamber 5 .

In the embodiment shown in FIGS. 1 and 2, an NH₃ probe 12 projects into the sample chamber 5 and is connected to the control and evaluation device 4 via a line 13 . A hose line 14 leads from a reagent source (not shown) arranged outside the measuring buoy 2 to a solenoid valve 15 , which forms a reagent metering device for supplying a reagent into the sample chamber 5 . In a corresponding manner, a hose line 17, which can be closed with a solenoid valve 16, serves to supply acid to the sample chamber 5 .

A pH probe 18 also protruding into the sample chamber 5 serves to determine the pH in the liquid sample. An air line, in which a solenoid valve 19 is arranged, also opens into the sample chamber 5 .

To examine a wastewater sample, the sample chamber 5 and the settling chamber 8 are emptied by supplying air or gas by opening the solenoid valve 19 . After opening a solenoid valve 20 , which is also connected to the sample chamber 5 , the air contained in the sample chamber 5 and the settling chamber 8 escapes via a hose line 17 , and the settling chamber 8 is filled until the level sensor 11 responds. After a settling pause in which the sludge contained in the liquid sample and possibly other settable substances have settled down in the settling chamber 8 , the sample chamber 5 is filled by re-opening the solenoid valve 16 under the effect of the hydrostatic pressure of the surrounding wastewater.

Then, by opening the solenoid valve 15, lye is let into the sample chamber 5 until a pH of about 11 has been established on the probe 18 . At a pH of 11, the entire NH₄ is present as NH₃ after sufficient mixing and is measured with the NH₃ probe 12 and evaluated by a computer in the control and evaluation device 4 . A new measuring cycle can then be carried out in the manner described.

To calibrate the device, a standard line 21 can be connected to the sample chamber 5 via a solenoid valve 20 in order to supply a standard liquid, so that an automatic calibration can be carried out.

Similarly, a (not shown) NO₃ measuring device can be carried out. Instead of the described NH₃ probe 12 , a NO₃ probe is then provided. In addition, an additional conductivity probe is attached in the sample chamber 5 .

In all of the following exemplary embodiments, the same parts are designated with the same reference symbols as in FIGS. 1 and 2.

FIGS. 3 and 4 show an exemplary embodiment of the invention, a device for determining the nitrate-phosphate content of waste water. An optical measuring cell 22 is arranged on the sample chamber 5 , which delivers a signal to the control and evaluation device 4 when a color change occurs in the liquid sample, which occurs due to the metered supply of reagent through the hose line 14 and the solenoid valve 15 .

FIGS. 5 and 6 show an apparatus for determining the nitrate content of waste water by means of an optical measuring device 23, which is arranged in the measuring buoy. 2 A light wave transmitter 24 throws a light beam onto a reflector 25 in the sample chamber 5 , which is reflected from there and strikes a light wave receiver 26 . The electrical drive energy for the optical device 23 and the signal transmission to the control and evaluation device 4 takes place via electrical lines 27 . A compressor 28 , which is connected to the sample chamber 5 via a solenoid valve 29, serves as the gas exchange device for filling and emptying the sample chamber 5 and the settling chamber 8 . After emptying the sample chamber 5 , a reference measurement can be carried out in order to compensate for the signal changes occurring due to contamination on the light wave transmitter 24 , on the reflector 25 and / or on the light wave receiver 26 .

The embodiment of the invention shown in FIGS. 7 and 8 represents a device for examining the oxidizable carbon content (TOC content) of waste water. The measuring probe 2 is also immersed in the waste water 1 . A pH probe 30 projects into the sample chamber 5 . A closable with a solenoid valve 31 gas supply line 32 opens at the bottom of the sample chamber 5 under a frit 33 to conduct reaction gas (O₃) in the sample chamber 5 . In order to prevent the water introduced into the sample chamber 5 reaction gas drain the sample chamber 5, in the region of the chamber opening 7 there is a valve 34 which is closed when the reaction gas is supplied to the sample chamber. 5

A level sensor 35 protruding into the sample chamber 5 gives a signal when the sample chamber 5 is completely filled. Acid or alkali can be supplied to the sample chamber 5 via solenoid valves 36 or 37 . After the reaction with the wastewater sample contained in the sample chamber 5 , the reaction gas passes via a solenoid valve 38 and a gas discharge line 39 to an evaluation device arranged in the control and evaluation device 4 at a distance from the measuring buoy 2 . The analysis of the escaping reaction gas carried out there provides a measured value for the TOC content of the examined waste water.

In Fig. 7, a settling chamber 8 with dash-dotted lines is only indicated in the lower region of the measuring buoy 2 . This is to show that such a settling chamber 8 can be dispensed with. In particular when determining the TOC, it may be necessary to dispense with the settling of solids in the wastewater to be examined if these solids have to be taken into account when determining the TOC content.

Claims (7)

1. Device for examining liquid samples, with a sample chamber, in which at least one examination device is arranged, with a control and evaluation device, and with a filling and emptying device, through which a liquid sample is fed from a quantity of liquid to the sample chamber and removed therefrom characterized in that the sample chamber ( 5 ) is arranged in a measuring buoy ( 2 ) which can be immersed in the amount of liquid ( 1 ) and is connected via a chamber opening ( 7 ) to the outside of the measuring buoy ( 2 ), that at least one examination device in the measuring buoy ( 2 ) is arranged such that the control and evaluation device ( 4 ) is arranged away from the measuring buoy ( 2 ) and connected to it via lines ( 3 ) and that the filling and emptying device has a gas exchange device with which a Liquid sample displacing gas is introduced into the sample chamber ( 5 ) d is removed from it. 2. Device according to claim 1, characterized in that in the measuring buoy ( 2 ) at least one in the sample chamber ( 5 ) opening reagent metering device ( 15 ) is arranged, which is arranged with a reagent source outside the measuring buoy ( 2 ) via a hose line ( 14 ) is connected. 3. Apparatus according to claim 1, characterized in that the gas exchange device has a gas pump ( 28 ) arranged in the measuring buoy ( 2 ) and connected to the sample chamber ( 5 ). 4. The device according to claim 1, characterized in that the chamber opening ( 7 ) opens into a settling chamber ( 8 ) arranged below it in the measuring buoy ( 2 ) and having a bottom opening ( 9 ). 5. The device according to claim 4, characterized in that in the region of the settling chamber ( 8 ) with the sample chamber ( 5 ) connecting chamber opening ( 7 ) a fill level sensor ( 11 ) is arranged, which is connected to the control for the gas exchange device. 6. The device according to claim 4, characterized in that at a distance below the bottom opening ( 9 ) in the vertical projection on all sides over the bottom opening ( 9 ) extending deflector ( 10 ) is arranged. 7. The device according to claim 1, characterized in that the sample chamber ( 5 ) is connected to a gas supply line ( 32 ) for a reaction gas, that the chamber opening ( 7 ) can be closed by a valve ( 34 ), and that one by a valve ( 38 ) closable gas discharge line ( 39 ) from the sample chamber ( 5 ) leads to an evaluation device arranged at a distance from the measuring buoy ( 2 ).