WO2007115556A2 - Determination of the volume of bodies of water - Google Patents

Abstract

A method of determining the volume of open and closed hollow bodies, pits and also garden waters (V) is claimed which comprises the steps A. where necessary charging V with water, B. introducing a defined amount MB of reactant and indicator having a defined transition point, C. addition of water from V to reactant and indicator from step B in an amount until the indicator shows a colour change, if appropriate determination of the added amount of water Vc, D. addition of a defined amount MD of a substance which changes the properties of the water, E. addition of water from step D to a defined amount ME of reactant indicator, until the indicator indicates a colour change, if appropriate determination of the added amount of water VE, F. determination of the difference D between the amounts of water, Vc and VE, added in C and F, G. determining the volume V from the measured parameters difference G, pH, hardness and/or redox potential of the water at the transition point of the indicator and the amount of substance added in step D. Using the claimed method, it is simple, even for lay persons, to determine the volumes of unknown size.

Description

 "Volume Determination of Waters"

The present invention relates to a method for determining the volume of open and closed hollow bodies, pits and water bodies and a kit, with the components of which the volume determination can be carried out.

The determination of unknown volumes is difficult in practice if the solid has no exact geometric shape, for example at

Water reservoirs, such as garden ponds etc .. Especially in the garden area are of the

Garden operators preferred pond systems, which are characterized by a special

Distinguish design form. When it comes to pond maintenance, the operator encounters the problem that, without precise knowledge of the volume of water, it is only possible to roughly estimate the fish population and the planting or design of pond technology. Also the addition of feed,

Pond care products, etc. depends on the volume of water.

It is an object of the present invention to provide a method with which even non-linear volumes of hollow bodies, including containers, pits, basins, waters of unknown size can be determined.

The present invention accordingly provides a method for determining the volume of open and closed hollow bodies, pits and garden waters (V), which comprises the steps A1. if necessary, fill V with water

B1. Presenting a defined amount of M _B i reactant and indicator with a defined

Transshipment point

C1. Adding water from V to reactant and indicator from step B1 in an amount until the indicator indicates a color change, optionally determining the added amount of water V _d ,

D1. Addition of a defined amount M _D i of a substance, the properties of the

Water changes,

E1. Adding water from step D to a defined amount of M _E i reactant indicator until the indicator indicates a color change, optionally determining the added amount of water V _E1> F1. Determining the difference D of the quantities of water V _C i and V _E i, G1 added in C and F. Determining the volume V from the variables difference G, pH, hardness and / or redox potential of the water at the point of transition of the indicator and the amount of substance added in step D.

Another object of the present invention relates to a method for determining the volume of open and closed hollow bodies, pits and garden waters (V), which comprises the steps

A2. if necessary, fill V with water B2. Presenting a defined amount of water V _B2

C2. Addition of a reactant M _G2 and indicator with a defined transition point to the water Step B until the indicator indicates a color change, optionally determining the added amount of reactant Mc ₂ ,

D2. Addition of a defined amount of a substance M _D , which alters the properties of the water,

E2. Addition of reactant ME ₂ and pH indicator with a defined transition point to a defined amount of water from step _{D 2} until the indicator indicates a color change, optionally determining the added amount of water V _E ,

F2. Determining the size difference D from the amounts of reactant added in C2 and F2,

G2. Determining the volume V from the variables Difference D, pH, hardness and / or redox potential of the water at the point of transition of the indicator and the amount of substance added in step D.

With the method according to the invention, it is possible in a simple manner to determine volumes of unknown size. The process according to the invention can also be carried out by laymen. Another advantage is that inexpensive, commercially available substances and devices can be used to carry out the method, which can be disposed of after determination of the volume readily.

If the volumes of waters are determined, the water hardness or the buffer capacity of the water can be determined from the measured quantities obtained in addition to the volume. Thus, the method according to the invention additionally provides information about the water quality.

The inventive method is based essentially on the property of water, the pH of water by the addition of acids and / or bases very quickly and this change can also be detected and quantified by lay people. The changes in the redox ratio or the water hardness are also rapid and can easily be determined by the layman in prepared kits.

The inventive method can be used to determine the volume of any hollow bodies, including open hollow bodies, such as containers, pits, basins, waters, z. As garden waters, ponds, liquid-filled caverns, are used. Particularly suitable is the method for the determination of volumes that are intended to absorb water, such as natural and artificial waters. In the following, the volume to be determined is denoted by V. In the event that the volume to be determined is unfilled, this is filled in a first step A with water.

The two claimed methods differ in that in the former method the reactant is a constant quantity and the added amount of water is a variable and in the second method the amount of water is kept constant and the amount of reactant varies depending on the water introduced.

The process steps D1 and D2, F1 and F2 and G1 and G2 are usually the same.

In process step B1, a defined amount of M _B reactant and an indicator with a defined conversion point are presented. Subsequently (step C) water is added from volume V to the mixture of reactant and indicator until the indicator shows a color change. The amount of water added until reaching the turnover point can be determined, if necessary, and is designated V ₀ .

In method step B2, a defined amount of water V _{B2 is} introduced and a quantity of M _B reactant and an indicator with a known transition point are added to the water until the indicator shows a color change. The amount of reactant added until reaching the transition point is determined.

Suitable reactants are those compounds which can alter the properties of water in such a way that they are indicated with a suitable indicator. Examples of reactants are acids, bases, reducing agents, oxidizing agents, buffers, complexing agents, etc. Suitable acids are any inorganic and organic acids, for example hydrochloric acid, sulfuric acid, oxalic acid, phosphoric acid, Nitric acid, acetic acid, alkali hydrogen sulfates, organic acids such as citric acid, tartaric acid, etc. Suitable bases are any inorganic substances, preferably alkali metal or alkaline earth metal oxides. Hydroxides, carbonates, bicarbonates. Examples of reducing agents are Na ₂ S ₂ O ₃ , iodides, such as NaI, vitamin C, as the oxidizing agent can nitrite, permanganate, hypochlorite, chlorate, peroxoanions or, peroxides, are used. Chelating agents such as are suitable which are able, to bind alkaline earth metal ions, in particular Ca ²⁺ and Mg ²⁺ complex, wherein preferred compounds are used, which can be used in standard solutions for the titration, chelating agents such as polyoxycarboxylic acids, polyamines, EDTA , NTA etc, (Römp-Chemie-Lexikon, Thieme Verlag Stuttgart / New York).

The indicator used according to the invention is suitably adjusted with the substance presented, i. if the reactant is an acid, lye or buffer, a pH indicator should be used, if a reducing or oxidizing compound is used, a redox indicator and a complexing compound is presented as the reactant, a metal-bromide indicator to be matched with this compound, a corresponding indicator mixture or System used.

As a pH indicator, an indicator or indicator mixture is usually used. The indicator preferably has a clearly perceptible color change. It is preferable to choose a transition area which has a distance of at least 1 to 2 pH units to the pH of the water in the volume V. This ensures that the transition point and thus the added amount of water from the volume V amount of reactant is unique.

Suitable indicators include Congo red, bromophenol blue, bromochlorophenol blue, methyl orange, α-naphthyl red, bromocresol green, 2,5-dinitrophenol, alizarin red, aniline blue, methyl red, ethyl red, carminic acid, phenolphthalein or mixtures of 2 or more indicators. The color change of the indicator takes place at a certain pH, which depends on the selected indicator and is known. A color change of the indicator in the pH range between 3.0 and 5.5 or 7.8 and 9.3 is preferred. This means that when the color change of the indicator occurs, the pH of the indicator and thus the H ⁺ ion concentration or buffer capacity is known.

Suitable redox indicators are, for example, methylene blue, ferroin indicator or iodine starch solution, cf. a. Römp-Chemie-Lexikon, Thieme Verlag Stuttgart / New York and mentioned there. Indicators used in combination with complexing compounds may, for example Eriochromic dyes, calcein, Aurintricarbonsäure, Calmagnit, Calconcarbonsäure, Zincon, Thorin, Murexid etc ..

In one possible embodiment of the present invention, an acid is introduced. Tap water shows a pH of about 7.8, standing water, such as garden ponds and similar waters have a pH> 7.5 and in some cases even over 8.3. The pH of waters is thus in the weakly basic range, rarely in the acidic range below pH 4.3. A change in the pH from the alkaline to the acidic range has the further advantage that indicators with a clear color change point can be used. Suitable indicators are described above.

According to a further embodiment, a reducing agent can be introduced as reactant and a corresponding redox indicator as indicator. In this embodiment, the substance added in step D is preferably an oxidizing agent. If the reservoir does not contain any naturally occurring oxidants, no value can be determined as V _c . Then the size V _E alone is inversely proportional to the pond size.

In another possible embodiment, a complexing agent is used as the reactant and an indicator adapted to this complexing agent. One possible combination of reactant and indicator is EDTA and murexide. In this embodiment, should in the volume to be tested (V) in step D, a quantity M ₀ hardener or also a complexing agent introduced. Due to the change in the measurable water hardness before and after the addition, the difference between V _c and V _{E is} determined.

In the next method step D, the volume V is given a defined amount M _{D of} a substance which alters the properties of the water. The substance M _D can for example change the pH of the water, have buffering, redox-active and / or water-hardness-forming properties to V. By adding these substances, the buffer capacity, and / or the pH of the water and / or water hardness changes and / or it changes the redox potential. The reactant presented in process step B, the indicator and the substance added in process step D are suitably matched to one another.

If a buffering or pH-changing substance is used in step D, then the reactant should be an acid or alkali and the indicator should be a pH indicator. If a redox-active substance is used in step D, the reactant is preferably a reducing agent or an oxidizing agent and the indicator is a suitable redox indicator.

When a hardening or complexing substance is used, the reactant is preferably a chelating agent and the indicator is a suitable metal hole chromium indicator.

Examples of compounds that alter the pH of the water are acids or alkalis, with hydrochloric acid being preferred. Suitable substances having a buffer action for use in step D are alkali metal or alkaline earth metal oxides, carbonates, bicarbonates, in particular NaHCO ₃ , KHCO ₃ .

As redox-active, oxidizing substances for use in step D, alkali and / or alkaline earth peroxides, such as 2NaCO3 * 3 (H ₂ O ₂ ), 2KCO ₃ * 3 (H ₂ O ₂ ), CaO ₂ , MgO ₂ , H ₂ O ₂ Peracetic acid, hypochlorite or nitrites are called. Thiosulfates, vitamin C, oxalic acid, etc. can be mentioned as redox-active, reducing substances.

As compounds having water hardness-forming properties for use in step D which can be complexed, there may be mentioned alkaline earth metal chlorides, sulfates, carbonates and / or nitrates, but also preparations as described in European Patent 0 737 169 may be used , As substances for lowering the measurable water hardness for use in step D, there are, among others. Chelating agent into consideration.

In addition to the already mentioned indicators and buffer systems, any further components known to the person skilled in the art can be used. Further examples can be found in the analytical literature.

Depending on the nature of the water, it is also possible to use the compounds MD mentioned for process step D as reactants in steps B and E and to use the substances mentioned for steps B and E in step D.

In order to achieve sufficient mixing of the water from the volume V with the added substance and, in the case where the substance is added in solid form, also the dissolution, the water in the volume can be agitated, stirred or mixed in a similar manner. After a period of a few minutes, usually 10 to 3 hours, in process step E1, water which has been mixed with the substance according to process step D is added to a defined amount of M _E reactant and indicator. Depending on the size of the hollow body, this period may be 10 to 20 minutes, if fast mixing is achieved with a small size, or up to 2 to 3 hours with larger bodies of water, pools, etc. Preferably, the same reactant M _E and indicator gate are used in this process step as in step B. The water becomes, as in step B is added in such an amount until the indicator indicates a color change. Subsequently, the amount of water V _E added in step E can be determined.

In the second process variant, a defined amount of water V _E2 is introduced in process step E2, indicator is added and a quantity of reactant M _F2 is added until the transition point of the indicator is reached. Subsequently, the amount M _F2 can be determined.

Determining the amounts of water V _C i and V _E i or the amounts of reactant M ₀₂ or

M _E2 in the process steps C and E can be carried out in a known manner by simple determination of the volume or determination of the amount. The addition of water preferably takes place in two separate containers, which preferably have a scaling.

By comparing the filling heights in the containers and form the difference of these

Fill levels, the volume difference between the added in steps C and E amounts of water Vc and V _E can be determined. If the volume difference D between the volumes V _c and V _E can be read directly from the scaling of the vessels, it is not necessary to separately determine the individual values for V ₀ and V _E.

The volume determination of the amount of water added in C and F can be carried out in conventional manner in conventional measuring containers. Preferably, the acid and the indicator are presented in steps B and E in a volume which has a scaling such that the difference in the scale parts represents the difference in the water volume D. In a particularly preferred embodiment, the volume S is suitable for removing the water from the volume V. Suitable devices for this purpose are commercially available pipettes, syringes or pistons. It can also be used any other container that allow volume determination. The reactant and the indicator can be presented in the vessel S. As favorable, the template has been found in powdered form or as a tablet.

In the last method step F, the determination of the volume V from the difference D takes place the pH of the water, the redox activity and / or the water hardness or complexing

Properties at the point of transition and the amount of substance added in step D.

The calculation of the volume V from the above variable and constant Measured quantities can be carried out in a manner known per se by formulas known to the person skilled in the art. In order to make it easier for the consumer to determine the volume, it has proved to be advantageous to graphically depict the dependence between the volume V and the difference D of the water added in steps C and F, so that the consumer derives directly from the difference D to the volume V of the hollow body or garden water can close.

If the water quality or initial values of the water, such as water hardness, indicate that the relative volume difference is too small to be able to make an accurate determination, it has proved to be advantageous if, prior to step C, one of the substances Mc and M _c complementary substance (eg the reactant) is added in equimolar mass. This may be necessary, for example, if the water hardness is very high.

Another object of the present invention is a kit for carrying out the method described above for determining the volume V of open and closed hollow bodies and garden waters and pits, comprising the following components: a) a defined amount of a reactant, b) indicator, c) at least 1 vessel for receiving reactant and indicator and water from the volume V, d) a defined amount of a substance which has buffering, redox-active and / or water hardness-forming or complexing properties.

This kit according to the invention also makes it possible for a layman to determine the volume V of eg garden waters in a simple and uncomplicated way. The kit contains at least one receptacle for reactant and indicator as well as for the water to be sampled from volume V. After the water has been removed in a first pass and added to the reactant and the indicator in an amount until reaching the transition point of the indicator was, the volume or the filling level of the added water is determined. After the defined amount of a buffering, redox-active and / or water-hardness-forming or -komplexierende substance was added to the volume V, in a second step, water from the volume V is added to the further defined amount of reactant and an indicator and determines the added amount of water. From the difference D of each added amount of water, the volume V is determined. To the layman the determination of the volume V from the To facilitate the data obtained, the kit is accompanied by a graphical representation, from which, starting from the difference D, the volume V can be determined directly.

In a preferred embodiment, the kit according to the invention contains at least two vessels into which the reactant and the indicator can be filled or which are already filled with it. Preferably, these vessels have a scaling. In these two vessels are added before and after the addition of the buffering, redox-active and / or water-hardening substance corresponding amounts of water until the indicator indicates a color change.

If the water in the reservoir whose volume is to be determined has only a very low water hardness or buffer capacity, there is a risk that the amount of water V _c to be added is too great for practical handling. In this case, it has proved to be advantageous if a buffer or hardness former is added to the volume before step C. Conversely, in the case of water with a high degree of hardness or buffering, the amount of water Vc to be added can be very small, so that the determination is faulty. In such a case, it has proven to be advantageous if the volume before step C, a complexing agent or an acid is added.

As a rule, the water hardness / carbonate hardness is known. If this is not known, the kit according to the invention may contain a test for determining the water hardness.

For these cases, the kit can be equipped from the outset with 2 substances ME, which in turn would complement to reactants. If the one substance is a buffer or a base, then the supplemental substance in the kit is one

Acid. Respectively. vice versa.

If the substance is an oxidizing agent, then the supplemental substance is included in the kit

Reducing agent, or vice versa.

If the substance is a hardness-forming agent, then the supplementary substance in the kit is a complexing agent or vice versa.

If substance and supplemental substance are used in equimolar amounts, the respective effects on water chemistry cancel out accordingly.

The method according to the invention or the kit according to the invention has the advantage that, in addition to determining the volume V of the hollow body or body of water, it can also be used to determine the water quality, for example the carbonate hardness (Buffering capacity) of the water. From the determined data the carbonate hardness can be calculated by a simple equation. In a preferred embodiment, the kit according to the invention in the graphical representation for determining the volume V is accompanied by a further representation for determining the carbonate hardness.

Example:

4.1 mg sodium hydrogen sulfate and a pH indicator with a conversion point (Ks value) of 4.3 (bromocresol green + alizarin red S) are placed in two test tubes V = 20 ml. From a garden pond, a water sample is taken and the 1st test tube is filled with it slowly until a color change from yellow to blue occurs. The filling level in the experiment was 15 cm. In the garden pond 84 g of sodium bicarbonate (previously dissolved) are well distributed. After 15 minutes of waiting for a good mixing a second water sample is taken and the second test tube is filled with it until the color change occurs. The filling height was 10 cm in the experiment.

4.14 mg of sodium hydrogen sulfate neutralize the alkalinity of 15 ml of water with a carbonate hardness of 2 mmol HCO3 / l.

The addition of a "pack" of NaHCO3 (84 g (1 MOL)) to the pond increases the alkalinity according to the volume of water present. With a water volume of 1 m ³ , the alkalinity is increased by 1 mmol / l; the amount of acid introduced will now be sufficient when water is added to neutralize 10 ml of water. The test pond had a size of 1 m ³ .

If the pond had had a different initial alkalinity, the difference between the two carbonate gardens would still be inversely proportional to the pond volume. The comparison does not require any absolute measurements to be taken; only the volume V _c and the volume difference V ₀ to V _E are significant for the determination of the pond size.

If large and small volumes of water are to be determined by this method, the number of packs used must be varied. This results in a directly proportional factor for the calculation of the pond size. The test tubes are prepared in advance with the acid and the indicator in always the same concentration. (Tablets can also be made). For our example, we added a solution of sodium hydrogen sulfate and indicator volumetrically in the test tubes and this solution was evaporated in a drying oven.

Berechnunqsvorschrift:

M (NaHSO ₄ .H ₂ O) = 138.07 g / mol M (NaHCO ₃ ) = 84 g / mol

Reservoir nominal volume 20 ml; Height 20 cm, 1 cm / ml.

Weighed acid m (NaHSO ₄ ^* H ₂ O) = 4.14 mg

Indicator: mixed indicator of bromocresol green and alizarin red S.

From a stock solution containing 41, 4 g NaHSO ₄ * H ₂ O and 50 ml mixed indicator per liter, was metered into each receiving vessel 0, 1 ml and concentrated to dryness.

The amount of acid introduced is consumed by the buffer capacity present in the water; the equivalence point can be recognized by the color change from yellow (acid) to blue (pH = 4.3). By adding the Natriumhydrogencarbonates to the reservoir V, there, the bicarbonate concentration is increased.

The amount of acid introduced in the second vessel will therefore be used up earlier. The volume of water ~ filling height is therefore lower.

The carbonate hardness of the water is inversely proportional to the filling level or the volume in the measuring vessel: The increase in carbonate hardness decreases with increasing size of the water reservoir. The simple connections apply:

2

On the measuring vessel or on an enclosed scale, the carbonate hardness and not the filling level is to be brought on, so that the evaluation for laymen is simply possible.

If the volume determination is to be determined by increasing the hardness, increasing the redox capacity or the like, the same calculation rule applies; the sizes must be replaced.

V _x = consumption included Measurement [ml]

V ₂ = consumption at second measurement [ml] n = amount of acid introduced in μmol IL n _d = amount of bicarbonate introduced in minor L

V _τ = determining volume [m ³ ]

KH = carbonate hardness in mmol I L

Claims

claims

1. Method for determining the volume of open and closed hollow bodies (V), which comprises the steps

A1. if necessary, fill V with water

B1. Presenting a defined amount of M _B reactant and indicator with a defined turnover point,

C1. Adding water from V to reactant and indicator from step B in an amount until the indicator indicates a color change, optionally determining the added amount of water V _c , D1. Addition of a defined amount of a substance M _D , which has the properties of

Water changes,

E1. Adding water from step D to a defined amount of M _E reactant and pH indicator at a defined transition point until the indicator one

Indicates color change, optionally determining the added amount of water VE, F1. Determine the size difference D from the amounts added in C and F.

Water.

G1. Determining the volume V from the variables Difference D, pH, hardness and / or redox potential of the water at the point of transition of the indicator and the amount of substance added in step D.

2. Method for determining the volume of open and closed hollow bodies (V), which comprises the steps A2. if necessary, fill V with water

B2. Presenting a defined amount of water V _B2

C2. Addition of a Reactant M _C2 and indicator with a defined transition point to the water Step B until the indicator indicates a color change, optionally determining the added amount of reactant M ₀₂ , D2. Addition of a defined amount of a substance M ₀ , which has the properties of

Water changes,

E2. Addition of reactant M _E2 and pH indicator with a defined transition point to a defined amount of water from step D2 until the indicator indicates a color change, optionally determining the added amount of water V _E ,

F2. Determining the size difference D from the amounts of reactant added in C2 and F2, G2. Determining the volume V from the measured quantities difference D ₁ pH, hardness and / or redox potential of the water at the point of transition of the indicator and the amount of substance added in step D.

3. The method according to claim 1 or 2, characterized in that the volume V is a pit, a basin, a natural or artificial body of water or a cavern.

4. The method according to claim 1 to 3, characterized in that the reactant or the substance is selected from acids, bases, reducing agents, oxidizing agents, buffers, complexing agents, etc.

5. The method according to claim 4, characterized in that the acid is selected from inorganic or organic acids having a KS value less than 6.5.

6. The method according to claim 5, characterized in that the acid is selected from hydrochloric acid, nitric acid, sulfuric acid, phosphoric acid, nitric acid, acetic acid, alkali metal hydrogensulfates, organic acids such as acetic acid, citric acid, tartaric acid, oxalic acid.

7. The method according to any one of claims 1 to 6, characterized in that the indicator ^'is selected from pH indicators, redox indicators or Metallochromindikatoren.

8. The method according to any one of claims 1 to 7, characterized in that the added in step D substance M _{D changes} the pH of the water or has buffering, redox-active and / or water hardness-forming or -komplexierende properties to V.

9. The method according to claim 8, characterized in that the substance M _{0 has} buffering properties and is selected from alkali or alkaline earth, oxides, - carbonates, -hydrogencarbonaten, in particular NaHCO ₃ , KHCO ₃ , or acids or alkalis, in particular Hydrochloric acid, sulfuric acid, hydrogen sulfates, acetic acid.

10. The method according to claim 8, characterized in that the substance M ₀ is selected with redox-active properties of alkali and / or Erdalkaliperoxiden, such as 2NaCO ₃ ^* 3 (H ₂ O ₂ ), 2KCO ₃ * 3 (H ₂ O ₂ ), CaO ₂ , MgO ₂ , or peroxo compounds or peracetic acid, H ₂ O ₂ , hypochlorites, ozone, chlorine or nitrite.

11. The method according to claim 8, characterized in that the substance M _{0 is selected} with water hardness forming or-lowering properties of Erdkalimetallchloriden, sulfates, carbonates and / or nitrates, from a composition of CaCl ₂ , CaCO ₃ and alkali ₂ CO ₃ consists of complexing

Fabrics, such as chelating agents ..

12. The method of claim 1 or 2, wherein the substance is an oxidizing agent, the reactant is a reducing agent with a redox indicator, in which only the volume V _{e is} to be determined in order to determine the size V.

13. The method of claim 1, in which prior to step C, one of the substance M ₀ or Mc complementary substance (eg the reactant) is added in equimolar mass.

14. The method according to any one of claims 1 to 13, characterized in that the reactant and the indicator in steps B and E are the same.

15. The method according to any one of claims 1 to 13, characterized in that reactant and indicator are presented in steps B and E in a volume S with scaling.

16. The method according to claim 15, characterized in that volume S is adapted to remove water from the volume V.

17. The method according to claim 15 or 16, characterized in that volume S in the form of a pipette, syringe, flask, test tube is designed.

18. The method according to any one of claims 1 to 17, characterized in that the difference E is read from a graph or a table.

19. The method according to any one of claims 1 to 18, characterized in that the Auswertegleichung the general form: V _τ = n _d / (AB) =

20. Kit for carrying out the method according to any one of claims 1 to 19, characterized in that it comprises the following components: a) a defined amount of a reactant, b) indicator, c) at least 1 vessel for receiving reactant and indicator and water from the volume V, d) a defined amount of a substance that changes the properties of the water.

21. Kit according to claim 20, characterized in that it contains 2 vessels filled with reactant and indicator.

22. Kit according to claim 20 or 21, characterized in that the reactants M _B and M _E in liquid form and the substance M _D in solid form or the reactants M _B and M _E in solid form and the substance M _D in liquid form available.

23. Kit according to one of claims 20 to 22, characterized in that the vessels have a scale.

24. Kit according to any one of claims 20 to 23, characterized in that it contains a graph or table with which the difference D the

Volume can be read.

25. Kit according to any one of claims 20 to 24, which in addition to the substance M _d an additional substance is included, wherein MD is preferably a bicarbonate and st the additional substance is an acid.