DE3612699C1 - Device for determining the ammonium nitrogen content - Google Patents

Abstract

A device for determining the ammonium nitrogen content in fertilisers and the like is provided. The device has a reaction vessel (1), a reactant vessel (4) connected thereto and a gas volumeter (9). For simplified production and handling, the gas volumeter (9) has a measurement vessel (14) and a liquid vessel (10), one of which is arranged in the other. The two vessels are connected together at the base. <IMAGE>

Description

The invention relates to a device for determining ammonium nitrogen content according to the preamble of claim 1.

The content of ammonium nitrogen in fertilizers is for the Farmer is an important characteristic. On the one hand, he makes a statement about the fertilizing effectiveness of the fertilizer and on the other hand also about the environmental impact. The practitioner should therefore have a device be given the hand easily and quickly a sufficient accurate ammonium nitrogen determination allowed. The principle of the Mes solution is based on the fact that the ammonium salts contained in the fertilizer be oxidized to nitrogen gas by a reagent. That included resulting gas volume is measured and displayed; it is direct proportional to the ammonium nitrogen content. This measuring principle is in Laboratory scale has long been known, and also for the farmer Appropriate devices have been known for some time, but all of them are defective.

A device of the type described above is from DE-GM 85 12 637 known. The gas volumeter consists of two arranged side by side Vessels, one of which is a liquid vessel and the other one Measuring vessel forms, built. The two vessels are under one Communicate the line connection routed to the two floors according to type of the tubes connected together. The reagent bottle is over  rigid lines arranged above the reaction vessel. In the connecting line is a valve for optional feeding provided by reagent. The construction of the device is through the two adjacent vessels of the gas volumeter and the reagent vessel arranged above the reaction vessel complicated structure.

The object of the invention is to provide a device as described in the introduction to create a kind that simplifies its structure and is stable.

This task is accomplished by the device of the type described above the features of the characterizing part of claim 1 ge solves.

The invention is explained in more detail below on the basis of exemplary embodiments illustrated in the figures.

From the figures show:

Fig. 1 is a schematic representation of a first embodiment

Fig. 2 is a schematic representation of a modified form of management

Fig. 3 is a vertical section through a further embodiment form along the line III-III in Fig. 4 and

Fig. 4 is a plan view of this embodiment.

The device has a reaction vessel 1 which is filled up to the level of a marking 2 with the substance to be examined, for example liquid manure, liquid manure or sewage sludge. The reaction vessel is then closed with a stopper 3 .

Furthermore, a reagent vessel 4 is provided, in which 5 reagents are filled in the required amount up to the level of a marking. The reagent vessel is plug 6 closed by a closure. The reaction vessel 1 and the reagent vessel 4 are connected to each other by elastic tubes 7 , 8 which are inserted through the sealing plugs 3 , 6 into the interior of the container. One of the elastic hoses 7 leads in the manner shown in the figures to close to the bottom of the reagent agent vessel 4 , while the other of the elastic hoses 8 ends directly on the inner surface of the sealing plug 6 .

A gas volumeter 9 is also provided. This has a liquid container 10 . This is closed by a plug 11 . To connect the interior of the reaction vessel 1 with the interior of the liquid container 10 , a connection line 12 is provided through the respective sealing plugs 3 , 11 . The liquid container 10 is filled up to egg ner predetermined mark 13 with a liquid in the form of water. Through the plug 11 , a measuring vessel 14 is also inserted into the interior of the liquid container 10 . The measuring vessel 14 has a tubular first section 15 with a smaller diameter. The first section extends with its free end 16 only centimeters over the plug 11 to the outside. A tubular second section 17 is inserted into the free end 16 . This has a measuring scale. The second section has a much larger diameter, which significantly reduces the overall height of the device.

In the exemplary embodiment described above, the measuring vessel is constructed in two parts. This ensures that the device height is reduced during transport. Instead of the two-part construction, the measuring vessel can also be formed in one piece, in which case the part that projects upward above the sealing plug 11 has the measuring scale.

The first section 15 of the measuring vessel 14 extends in the manner shown in the figures to the bottom of the liquid keitsbehälters 10 , so that a clear positioning of the measuring vessel or the measuring scale relative to the liquid container bottom is reached. The first section 15 has on its bottom recesses 18 in the tubular wall. These recesses ensure that the water level in the liquid container 10 and in the measuring vessel 14 is the same. A valve 20 is connected to the interior of the reaction vessel 1 via a line 19 .

The modified embodiment shown in FIG. 2 differs from the embodiment described above only in the design of the gas volumeter. Respectively corresponding parts are marked net with the same reference numerals.

The gas volumeter 21 comprises a liquid container 10 'with a housing wall and a housing cover 22 for hermetic sealing. The connection between the inside of the liquid keitsbehälters 10 'and the reaction vessel 1 is in turn formed on the through the housing cover and the plug 3 through the connecting line 12 . A measuring vessel 14 'is passed through this closely surrounding housing cover 22 and is at its bottom end on the bottom of the liquid keitsbehälters 10 '. At its bottom end, recesses 18 are again provided so that the water in the liquid container 10 'up to the mark 13 is at the same height in the measuring vessel 14 '. The measuring vessel 14 'is open as in the embodiment shown in Fig. 1 at its upper free end 23 .

In the embodiment shown in FIGS . 3 and 4, the reaction vessel 1 and the reagent vessel 4 have the same structure as described above. The gas volumeter 24 has a cylindrical outer wall 25 , which is connected by means of a suitable seal to a base 27 common to all vessels for forming a cylindrical vessel. A cylindrical inner wall 26 is arranged coaxially to the cylindrical outer wall and at a distance from the outer wall, which is also supported on the common base plate 27 . The cylindrical inner wall 26 has adjacent to the common floor 27 Ausnehmun gene 28 , via which the inner space enclosed by the cylindrical inner wall is connected to the inner space enclosed between the two cylindrical walls. The cylinder formed by the cylindrical inner wall 26 is hermetically sealed on its upper side by a cover 29 with a sealing plug 30 arranged therein. A connecting line 12 is guided through the sealing plug 30 and, as in the previous embodiments, leads to the interior of the reaction vessel 1 . Furthermore, a ventilation valve 31 is seen in the sealing plug 30 , which essentially corresponds to the valve 20 in the above-described embodiments.

The cavity enclosed between the cylindrical inner wall 26 and the cylindrical outer wall 25 is open at the top through openings 32 . The cylindrical outer wall 25 is formed from a transparent material and has a measuring scale, not shown, which is designed such that a liquid level in this space can be read in the same way as in the measuring scale of the gas volumeter of the above-described embodiments.

The three vessels of the described embodiment are arranged in a stable manner on the common base 27 . An outer cylinder wall 33 surrounding the housing is provided. On the upper side of the cylinder wall, a removable cover 34 is arranged, which carries a handle 35 .

In the last-described embodiment, the container formed by the cylindrical inner wall, the bottom and the lid 29 thus corresponds to the liquid container 10 of the above-described embodiments, and the cylindrical container made from the inner cylinder wall 26 , the outer cylinder wall 25 and the common bottom 27 is the container 14 of the above-described embodiments.

In operation, the reaction vessel 1 is filled with liquid manure, liquid manure or sewage sludge and sealed with the sealing plug 3 again in order to carry out a measurement. In the Reagenzmittelge vessel 4 , the required amount of reagent is filled, and then this vessel is closed with the plug 6 . The measuring vessel 14 is filled with water until the water level in the measuring vessel and thus at the same time in the liquid container 10 has reached the height of the mark 13 . After all the plugs are tightly closed, the entire system is vented through the valve 19 . The reagent vessel is then moved into the position shown in dashed lines, as a result of which the reagent flows into the reaction vessel. There the reagent and the substance to be examined mix. This creates N ₂ gas. This flows over the connecting line 12 in the liquid liquid container 10th There it displaces a certain amount of water, so that the water level in the liquid container 10 drops and rises accordingly in the measuring vessel 14 . The water level and therefore the nitrogen content of the sample in kg / m ³ can be read off on the measuring scale of the second section 17 . Since the N ₂ gas is released only gradually, the measurement must be between the beginning and reading the measured values from about 8 - 10 minutes to be serviced.

After the measurement, all containers can be emptied and rinsed with water and are ready for a next measurement ready to use.

In the exemplary embodiments shown in FIGS . 1 and 2, with the exception of the base plate carrying the parts, they are commercially available laboratory equipment articles, which enables particularly inexpensive manufacture.

While in the embodiment shown in FIG. 1 the stability of the measuring device 14 is achieved by its guidance in the sealing plug 11 , in the embodiment shown in FIG. 2 the stability is achieved in that the measuring vessel is firmly attached to the base plate, for example by gluing.

In the embodiment shown in FIGS. 3 and 4, the operation proceeds accordingly. For commissioning, the cover is first removed together with the cylindrical side wall 33 . The substance to be examined and the reagent are poured in in the same manner as described above. The water is poured in by taking out the part 31 designed as a valve through the opening that is freed up until the water level at the mark 13 is reached. Then the valve 31 is closed. Through the gas entry via the connecting line 12 , water is forced out of the space enclosed by the cylindrical inner wall 26 through the recesses 28 . The increase is on the attached to the cylindrical outer wall 25 measuring scale, which is calibrated in the same way as the two first embodiment examples.

After operation, the wall with the lid for transportation applied again.

Claims (6)

1. Apparatus for determining the ammonium nitrogen content, in particular in fertilizers, with a reaction vessel, a reagent vessel and a compound for optionally connecting the reaction vessel and reagent vessel for supplying the reagent into the reaction vessel and a gas volumeter connected to the reaction vessel with a liquid container and one with the same connected measuring vessel, characterized in that the measuring vessel ( 14 , 25 ) in the liquid container ( 10 , 26 ) to the bottom thereof or the liquid container ( 10 , 26 ) in the measuring vessel ( 14 , 25 ) protrudes to the bottom thereof and Recesses ( 18 ) in the wall of the protruding part for binding Ver measuring vessel ( 14 , 25 ) and liquid container ( 10 , 26 ) are seen before. 2. Device for determining the ammonium nitrogen content, in particular in fertilizers according to claim 1, characterized in that the connection between the reaction vessel ( 1 ) and the reagent vessel ( 4 ) is designed as a flexible line ( 7 , 8 ) such that a supply of the reagent by lifting and tilting of the reagent vessel ( 4 ). 3. Device for determining the ammonium nitrogen content, in particular in fertilizers according to claim 1 or 2, characterized in that the liquid container ( 10 , 26 ) is closed by a sealing plug ( 11 ) and the measuring vessel ( 14 , 25 ) through this into the liquid container ( 10 , 26 ) is introduced. 4. Apparatus for determining the ammonium nitrogen content, in particular in fertilizers, according to one of claims 1 to 3, characterized in that a valve ( 20 ) is provided for venting the interior of the reaction vessel. 5. Apparatus for determining the ammonium nitrogen content, in particular in fertilizers according to claim 3 or 4, characterized in that the measuring vessel ( 14 , 25 ) has a first section ( 15 ) used in the liquid container ( 10 , 26 ) and one inserted in its outer end , has a measuring section having a second section ( 17 ). 6. Device for determining the ammonium nitrogen content, in particular in fertilizers according to one of claims 1 to 5, characterized in that one of the reaction vessel ( 1 ), the reagent medium vessel ( 4 ) and the liquid container ( 10 , 26 ) with the measuring vessel ( 14 , 25 ) receiving base plate ( 27 ) with a wall ( 33 ) surrounding the vessels and a cover ( 34 ) are provided.