DE10006846C2 - Process for photometric COD measurement - Google Patents

Description

The invention relates to a method for photometric COD measurement of liquid samples in which the liquid in a cuvette containing a reagent filled and the cuvette is then closed, and at which then contains the cuvette content from the liquid sample and reagent in a photometer its COD content is examined.

The chemical oxygen demand (COD) is one of the most important parameters for the evaluation of commercial and municipal wastewater. The standard procedure according to DIN 38409, part 1 ( 1980 ) is known for the determination of the COD. Rapid tests have also been developed in the past based on this standard procedure. In the case of such rapid tests, a closed round cuvette is used in which the reagent in the form of chromic sulfuric acid has already been pipetted. After opening the cuvette, adding the liquid sample, closing the cuvette and shaking the contents of the cuvette and heating to 148 ° C for two hours and then cooling, the evaluation is carried out in a photometer. The COD value can be read off directly in mg / l (cf. also DE 30 30 103 A1).

In the previously known method, the cuvettes are one tents handled. As a device come only a thermo block for heating the cuvettes and the photometer for use. In between, the handling is manual. This applies in particular to the filling of the liquid sample.

The cuvettes themselves have a cylindrical glass body with opening on the top, with a screw cap is closed. The screw cap consists of a Plastic material. For pipetting in the samples liquid, the screw cap must be removed. There is a risk of contamination from ver pour the reagent.

JP 9-021794 A (Patent Abstracts of Japan 1997 ) describes a method in which a metering device is used, with the aid of which various liquids, including the liquid sample itself, can be filled into open containers. Since work is carried out with open containers, the risk of contamination is high. There is no photometric evaluation.

Also in the method described in US 5,531,960 a dosing device is used. In doing so multiple cuvettes in a single cuvette rotor mat adjusted to the liquid content contained in the cuvettes  to mix better. Like this in detail happens and how the preparation and subsequent off this publication is not refer to.

JP 6-160388 A (Patent Abstracts of Japan 1994 ) discloses a method for determining dissolved oxygen. It is not clear what type of cuvette is used. The subsequent evaluation is also not described in detail.

DE 198 07 177 A1 describes an analysis system for Carrying out clinical-chemical and immunological Ana lysen revealed. A COD determination is not mentioned. It is not with single cells, but with Systemrea gene carriers that can only be handled jointly beitet. The system reagents are on their tops with membranes made of an elastically soft material hermetically sealed from the tip of a pipet can be pierced. After pulling out The membranes close behind the pipette tube again, so that no foreign bodies get into the inside of the measuring head vette can penetrate.

The invention has for its object a method provide a variety of COD measurements largely automated.

According to the invention, this object is achieved by a method having the features of patent claim 1.  

In the process, a multiple or a plurality of cuvettes in a holding device and a plurality or plurality of liquid samples in egg collected in a sample holder. Then the filling of the Liquid samples using a dosing device au performed automatically, in such a way that the cuvettes located in a holding device others are filled and only later the photometric Survey takes place. The previous mix and ther Mixing is done in for each holding device one operation. Multiple stops can also be used directions with several cuvettes in one area be filled in the corridor. It is understood that through the  extensive automation with the help of the dosing device a much safer handling of the cuvettes is guaranteed so that it accelerates the ar implementation is coming.

In a development of the method it is provided that in the Dosing device also a holder with dilution medium set and the liquid sample and the dilution medium taken up by the dosing cannula and into the predetermined cuvette is filled. It can in the Dosing device also a holder with several dilutions media and one diluent each taken up by the dosing cannula and into the predetermined Cuvette to be filled.

According to a further embodiment of the method, the Dosing unit for each cuvette a sample number and one sample at a time based on the expected COD content volume entered. This can be done with the help of a PC and a suitable software.

In the drawing is an apparatus for performing the method using a schematic table shown embodiment closer shows. Show it:

Figure 1 is a partial plan view of a dosing device.

FIG. 2 shows the partial top view according to FIG. 1 with the dosing device during the dosing process;

Fig. 3 is a partial side view of the dosing device according to Figures 1 and 2 during the dosing process.

. Figure 4 shows a test tube in vertical section prior to insertion of the discharge tube of the metering device according to FIGS. 1 to 3;

FIG. 5 shows the round cuvette according to FIG. 4 after inserting the dosing cannula;

FIG. 6 in side view the support block with the filled cuvettes with Fuse L direction for mixing;

FIG. 7 rotated the holding block according to FIG. 6 by 180 °;

Fig. 8 shows the holding block with the cuvette in a heating block,

Fig. 9 is a plan view of the metering device according to FIGS . 1 to 3 when aspirating the cuvette contents and

Fig. 10 shows a cuvette in longitudinal section when aspirating the cuvette contents and measuring in a photometer.

The dosing device 1 shown in FIGS . 1 to 3 has a device housing 2 , in which the control devices and pumps are included. As can be seen in particular from FIG. 3, the metering device 1 has two actuating cylinders 3 , 4 , from whose upper openings openings piston rods 5 , 6 protrude. At the protruding into the actuating cylinders 3 , 4 ends of the piston rods 5 , 6 pistons are provided which can be struck on both sides with a pneumatic or hydraulic pressure medium so that the piston rods 5 , 6 can be extended and retracted. This can be done with the help of the control device and the pumps provided for this purpose.

At the free end of the left-hand piston rod 5 , a crossbar 7 is attached, on the end of which is remote from the piston rod 5 , a metering device 8 is suspended. This metering device 8 has a cylinder 9 into which a piston rod 10 projects, which is connected to the cross-member 7 . On the underside, the piston rod 10 has a seal 11 which rests sealingly on the inside of the cylinder 9 .

The lower end of the cylinder 9 opens into a dosing cannula 12 . About two cross members 13 , 14 , which are connected via a vertical rod 15 , the dosing cannula 12 and thus also the cylinder 9 can be vertically moved by the piston of the piston rod 6 being pressurized from the corresponding side. The Kol rod 10 is on the crossbar 7 and the piston rod 5 vertically movable. Both are symbolized by the arrow pairs A and B respectively.

The metering device 1 has a support table not shown here, which can be moved horizontally in four mutually perpendicular directions according to the arrows A and B shown in FIG. 2, with the aid of appropriate motors. A support block 16 and a sample holder 17 are located on the support table. The holding block 16 and the sample holder 17 have a multiplicity of receiving recesses arranged in rows, for example designated 18 and 19, respectively. In Figs. 1 and 2 are of the holding block 16 and provided to the sample holder 17 is only partially.

In Fig. 1, in addition to the metering device 1, a cuvette tenblock 20 with a total of 20 cuvettes used - referred to as 21 at playful. In Figs. 4 and 5, the detailed construction of such a vial 21 is shown. It consists of a cylindrical glass body 22 , rounded at the bottom in a hemispherical shape, which has an external thread 23 in the upper region, onto which a cap-shaped cover 24 is screwed. The cover 24 consists essentially of a rigid plastic material and has an upper cover wall 25 which has a circular opening 26 in the center. The inside of the lid wall 25 is covered with a membrane 27 made of butyl rubber. The membrane 27 closes the opening 26 and has a PTFE coating on the inside. A chromosulfuric acid reagent 28 is filled into the cuvette 21 .

The cuvettes 21 shown in FIG. 1 are placed in the holding block 16 for a COD measurement. In the receiving recesses 19 of the sample holder 17 sample vessels are set with different liquid samples. Sample numbers are assigned via a connected PC and the desired sample volumes are preselected depending on the expected COD content. Subsequently, by moving the support table, the sample container set in the first recess 19 is moved under the dosing cannula 12 (see FIG. 2). By appropriately pressurizing the pistons of the piston rod 6 , the latter is moved downward with the cross members 13 , 14 and the vertical rod 15 and takes the metering cannula 12 and the cylinder 9 with it. As a result, the dosing cannula 12 moves with its tip into the sample vessel in the recess 19 of the sample holder 17 . At the same time, the volume in the cylinder 9 increases below the device 11 , which means that the dosing cannula 12 sucks the liquid sample out of the sample vessel after immersion. This continues until the entered sample volume is sucked in.

By reverse pressurization of the piston of the piston rod 6 , the dosing cannula 12 is raised again. So that there is no ejection of the liquid sample, the piston rod 10 is simultaneously raised rod 5 by appropriate pressurization of the piston, so that the volume below the seal 11 does not change.

The support table is then moved from the position shown in FIG. 2 to the position shown in FIG. 3, in which the dosing cannula 12 is located directly above the first cuvette 21 . This situation can also be seen in FIG. 4. Then the Dosierein direction 8 by simultaneously moving the piston rods 5 , 6 moves downwards, the metering cannula 12 piercing the membrane 27 (see FIG. 5). Then the piston rod 6 is stopped, while the piston rod 5 is moved further down. As a result, the liquid sample 29 held in the dosing device 8 is expelled and thus reaches the reagent 28 . Thereafter, the metering device 8 is raised again by simultaneously extending the piston rods 5 , 6 until it has reached the position shown in FIG. 3.

Subsequently, the support table is again proced so that the sample container placed in the second receiving recess 19 comes to rest below the dosing cannula 12 . It repeats the above-described process of taking up a certain volume of liquid sample 29 and transporting it to a second cuvette 21 . This is as long as has been pipetted into the cuvette 21 to all existing fluid samples 29th

After all the cuvettes are provided with liquid samples 29 21, the upper side - as shown in Figure 6 is to erse hen -. A holding cover 30 is placed, which receives the upper ends of the cuvettes 21 in matching recesses. The holding cover 30 is connected to the holding block 16 via clamps 31 , 32 , so that the holding block 16 , holding cover 30 and the cuvettes 21 form a fixed unit. This unit is then shaken in order to intensify the mixing of liquid samples 29 and reagent 28 , which now form the cuvette content 33 , and - as shown in FIG. 7 - also turned upside down. This can be done in a corresponding device. Then the holding cover 30 and the clamps 31 , 32 are removed again, and the combination of holding block 16 and cuvette 21 is set in a heating block (not shown here) (see FIG. 8). The arrow E symbolizes that the cuvettes 21 are heated from below by the holding block 16 , so that the cuvette contents 33 are heated to about 148 ° C. for 2 hours.

After cooling, the cuvettes 21 together with the holding block 16 are again placed on the support table of the Dosiervor device 1 (see. Fig. 9). The dosing device 1 is now controlled so that the cuvettes 21 are moved one after the other and in each case the cuvette contents 33 are sucked out of the cuvette 21 . This process can be seen in Fig. 10. It shows the cuvette 21 with the dosing cannula 12 which is pierced through the membrane 27 and protrudes into the cuvette contents 33 . The other metering device 8 with all actuating devices is omitted for the sake of clarity. The dosing cannula 12 is connected to a hose 34 which projects into the dosing device 1 and in which a pump 35 is inserted. The pump 35 sucks the cuvette content 33 out of the cuvette 21 and transports it into a photometer 36 . There, the cuvette contents 33 pass through a continuous cuvette 37 , which sits in the beam path of the photometer 36 and is therefore illuminated from one side by a lamp 38 . A receiver 39 receives the radiation passing through the cuvette 37 . Since the cuvette 33 assured by the reaction between the reagent 28 and Probenflüs dyed 29, the radiation is partially absorbed, the absorption is a measure of the COD content. This can then be displayed directly in concentration units by the display device 40 . The measured value can also be calculated on the PC and assigned to the sample number.

Claims (6)

1. A method for photometric COD measurement of liquid samples ( 29 ), in which the liquid sample ( 29 ) in a with a reagent ( 28 ) provided cuvette ( 21 ) and the cuvette ( 21 ) is then closed, and in which then the cuvette content ( 33 ) from liquid sample ( 29 ) and reagent ( 28 ) is examined in a photometer ( 36 ) for its COD content, characterized in that cuvettes ( 21 ) are used in which a reagent ( 28 ) has already been filled is and the top-side openings are each closed with a lid ( 24 ) ver, the top cover wall ( 25 ) is covered with a pierceable but self-closing membrane ( 27 ) that several such cuvettes ( 21 ) in a common holding device ( 16 ) and several liquid samples ( 29 ) are placed in a common sample holder ( 17 ), the holding device ( 16 ) and the sample holder ( 17 ) being in a dosing device ( 1 ) b or find that the cuvettes ( 21 ) are then filled with liquid samples ( 29 ) with the help of at least one dosing cannula ( 12 ) by relative movement between the dosing cannula ( 12 ) on the one hand and the holding device ( 16 ) and the sample holder ( 17 ) on the other hand are each taken by a liquid sample ( 29 ) from the dosing cannula ( 12 ) and the membrane ( 27 ) with the predetermined cuvette ( 21 ) is pierced, and that the cuvettes ( 21 ) in the holding device ( 16 ) after filling with the liquid samples ( 29 ) are subjected to mixed movements and thermal treatment, and that finally the cuvette contents ( 33 ) are aspirated by means of the dosing cannula ( 12 ) and pumped into a flow cell ( 37 ) into the photometer ( 36 ) for measurement. 2. The method according to claim 1, characterized in that in the dosing device ( 1 ) also a holder with dilution medium is set and the liquid sample ( 29 ) and the dilution medium from the dosing cannula ( 12 ) are taken and in the predetermined cuvette ( 21 ) is filled. 3. The method according to claim 1, characterized in that in the metering device ( 1 ) also a holder with a plurality of dilution media is set and in each case a dilution medium from the metering cannula ( 12 ) is added and filled into the predetermined cuvette ( 21 ). 4. The method according to any one of claims 1 to 3, characterized in that in the metering device ( 1 ) for each cuvette ( 21 ) a sample number and a desired sample volume is entered according to the expected COD content. 5. The method according to any one of claims 1 to 4, characterized in that cuvettes ( 21 ) are used in which the membrane ( 27 ) consists of a vulcanized butyl rubber. 6. The method according to any one of claims 1 to 5, characterized in that cuvettes ( 21 ) are used in which the membrane ( 27 ) is provided on the inside with a FEP or PTFE coating.