EP1474667A1 - Device for measuring quantities of heat while simultaneously measuring the evaporation kinetics and/or condensation kinetics of the most minute amounts of liquid in order to determine thermodynamic parameters - Google Patents

Abstract

The invention relates to a device for measuring quantities of heat while simultaneously measuring the evaporation kinetics and/or condensation kinetics of the most minute amounts of liquid in order to determine thermodynamic parameters. The aim of the invention is to determine low thermal outputs, which are absorbed or released by the sample, as well as small differences between thermal outputs with regard to a reference measurement of the same magnitude. To this end, a most minute amount of liquid is located inside a measuring chamber having a constant temperature and air humidity. At least one thermal sensor is provided for repeatedly measuring the thermal radiation emitted from the most minute amount of liquid. A measuring means serves to determine the time-dependent change in the most minute amount of liquid. A computer is assigned to the measuring chamber in order to register, display, evaluate and/or subsequently process the measured values.

Description

Arrangement for measuring quantities of heat while simultaneously measuring the evaporation and / or condensation kinetics of the smallest quantities of liquid for determining thermodynamic parameters

description

The invention relates to an arrangement for measuring amounts of heat while simultaneously measuring the evaporation and / or condensation kinetics of the smallest amounts of liquid for determining thermodynamic parameters according to the preamble of the claims. The quantities of heat can be taken up from very small samples, which mainly consist of liquid, during the evaporation and / or the condensation. The arrangement according to the invention is used primarily for the simultaneous measurement of specific heat of vaporization and vapor pressure of solutions near room temperature. If there is a chemical equilibrium in the liquid and the evaporation and / or condensation process is associated with a shift in the chemical equilibrium, the arrangement also serves to measure the specific chemical heat of reaction. On composite systems, consisting of a solution in contact with a solid (crystalline) phase of the solute, the device also serves to measure the concentration of the saturated solution and the specific heat of solution. The smallest amount of liquid can also be a gel-like substance that binds the solvent. The arrangement is intended for measurements on solutions in which the vapor pressure of the solvent does not exceed that of saturated water vapor and the vapor pressure of the solute over the solution is negligibly small compared to that of the solvent.

For all previous calorimeter principles, the knowledge can be derived from the prior art that the faster the amount of heat to be released, the smaller the still demonstrable performance. The resulting characteristic time determines the time constant that the calorimeter must have at least in order to to determine the total amount of heat released. With the currently technically realizable maximum time constant of approx. 1000 s, the still reliably detectable power is approximately 0.1 μW; it drops to approx. 10 nW at a time constant of 30 s. The miniaturization of the calorimeters that is desirable when using very small amounts of substance, for example using thermally controlled micro-measuring cells on a chip basis, can consequently only be used advantageously when measuring amounts of heat in the nJ range if this amount of heat is available within a few seconds. This knowledge, which corresponds to the state of the art, is precisely the opposite of the requirements placed on the measurement task to be solved with the device according to the invention.

Starting from the prior art, the invention is based on the object of small thermal outputs in the nW range which during the evaporation and / or condensation of a part of the liquid of the sample over a period of preferably 1000 s of the sample of the order of magnitude 1 μl itself or given, as well as to determine small differences in heat outputs compared to a reference measurement of the same order of magnitude. Since the thermal output to be measured also depends on the rate of evaporation and / or condensation, the desired arrangement according to the invention should also enable measurement of the evaporation and / or condensation kinetics of the smallest liquid samples, these measurements simultaneously determining the vapor pressure of the liquid or small differences of the vapor pressure compared to a reference sample. Because of the small size of the samples, there is a need to design the measurement so that the influence of interference on the measurement is largely eliminated by the measurement process itself. Finally, it should be possible to use model analysis to calculate the thermal output and vapor pressure directly determined from the data obtained directly from the measurement (sample temperature, sample volume or sample mass as a function of time). According to the invention, this object is achieved by the characterizing features of the first claim and advantageously embodied by the features of the subclaims.

In one embodiment of the arrangement according to the invention, a sample is introduced into a measuring chamber in which the temperature and vapor pressure of the solvent (relative air or gas humidity) are kept constant. The spontaneous loss of mass of the sample and the spontaneous lowering of the temperature on the sample surface compared to the temperature in the measuring chamber are measured as a function of time. The arrangement is basically constructed in such a way that the sample is in thermal contact exclusively with the gas in the measuring chamber and a substance transition on the sample surface can only take place with the gas in the measuring chamber. The surface temperature of the sample becomes pyrometric, i.e. H. measured without contact. The evaluation of all data is computer-supported in a subordinate periphery.

In the arrangement according to the invention, the sample itself represents the working substance of a calorimeter, which is preferably operated under the condition of quasi-steady-state heat exchange with the surroundings, the heat output released or absorbed by the sample being calculated from the time course of the temperature measured on the sample surface. The arrangement is particularly intended to carry out measurements on small samples in the event that the amount of heat to be detected is released very slowly. With a sample mass of approx. 1 mg, a resolution of the thermal output in the order of 10 nW should be achievable with a time constant in the order of 1000 s. Based on the directly determinable measured quantities of heat and vapor pressure, the arrangement according to the invention serves in particular to determine thermodynamic variables that can be derived therefrom, such as the excess contribution of the chemical potential or the enthalpy of the solvent, the interaction of the dissolved substance with the solvent or the interaction of the molecules of the Characterize solvents with each other. On composite systems, that is Containing solid and / or gel-like substances, the arrangement also serves for the direct determination of parts of the phase diagram.

Specifically, the device according to the invention should meet with regard to its performance parameters and its structural details the requirements which are required for measurements on aqueous solutions of biological macromolecular compounds, e.g. Proteins, including

Add electrolyte and buffer. These requirements are based on the following requirements: a) Proteins, in particular protein single crystals, are often only in the smallest

Quantities (order of magnitude μg) are available. b) Protein solutions contaminate glass, silicon and other surfaces that are difficult to clean using chemically aggressive agents. These contaminations can be highly sensitive and expensive microchip calorimeters after one time

Make measurement of protein solutions unusable. c) Compared to conventional (inorganic) systems, the growth or dissolution rate of protein crystals is one to two orders of magnitude lower. This means that the thermal outputs to be verified during crystallization or dissolution are correspondingly lower than with conventional systems. d) Under normal conditions (room temperature, atmospheric pressure), the protein single crystals prove to be stable only in constant contact with the saturated solution, and they are also very sensitive to mechanical and thermal

Stresses. Improper handling of the protein crystals in calorimetric measurement procedures can therefore falsify the results.

In addition, the arrangement according to the invention is intended to enable thermodynamic measurements in a time-economical manner, so that it can be used for routine characterization (comparable to differential thermal analysis in inorganic systems) in all investigations of the crystal growth of proteins. In the arrangement according to the invention, two independent measurements are carried out simultaneously on the sample to be examined (aqueous solution). During the entire measurement period, the mass loss of the sample due to a constant evaporation of the solvent due to the environmental conditions to be selected is recorded. Secondly, a calorimetric measurement of the heat of vaporization per unit of time is carried out during the entire measurement period, the working substance of the calorimeter arrangement, which represents the arrangement, being represented by the sample to be examined itself. This calorimetric measurement is implemented in a non-invasive way in that the surface temperature of the sample is determined pyrometrically and continuously recorded with the help of at least one thermal sensor. The sample to be examined (aqueous solution) is located in the arrangement according to the invention in an airtight sealed measuring chamber, in which the temperature and relative air humidity can be set precisely and are kept constant during the entire measuring period, and temperature gradients and convection are largely avoided. The arrangement is such that the sample has thermal contact with its surroundings practically only via its free interface to the surrounding gas space and a substance transition from the sample to its surroundings can practically only take place via this free interface. An elliptical concave mirror and a radiation receiver are located inside the measuring chamber for pyrometric measurement of the surface temperature of the sample. These are positioned so that one focal point of the concave mirror is exactly on the interface of the sample to the measuring chamber and the other is on the sensor surface of the radiation receiver. This part of the free interface of the sample is thus mapped onto the aperture opening of the radiation receiver, so that a measurement of the surface temperature can be carried out.

In one embodiment, the invention can, for example, be designed such that the sample is present as a hanging drop at the tip of a fine, vertically aligned capillary. The geometry of the capillary is chosen so that the hanging drop is as large as possible Diameter, based on the outer diameter of the capillary, is formed in a coaxial alignment with the capillary (capillary with a wall thickness that decreases in a wedge shape towards the tip, for example, produced by grinding. Outside or inside diameter of the capillary at the tip about 80 μm or 50 μm) , In addition, the surface of the capillary in its mouth area is passivated (e.g. by applying a silane film) to prevent deformation of the spherical drop shape or loss of mass of the drop due to the formation of a liquid film on the outer surface of the capillary. In this case, the drop mass is determined using a measuring microscope, which leads from the outside into the measuring chamber and is arranged in such a way that the drop is in its object plane and allows the geometric parameters of the drop to be measured. To generate the drop, the capillary can be formed as the tip of a measuring pipette that can be filled and operated from the outside, which can simultaneously serve as a reservoir for the sample liquid and for thermal equilibration of the sample before the start of the measurement. In a second embodiment, the arrangement according to the invention can, for. B. be constructed so that the sample to be examined is in an upwardly open cup-shaped container inside the measuring chamber, so that only the upper meniscus of the liquid has contact with the measuring chamber volume. The container must consist of a very difficult to wet, inert material with extremely low thermal conductivity and have typical internal dimensions of a maximum of 4 mm in diameter and 1 mm in height. In this case, the sample mass is determined by weighing. For this purpose, the container is connected to a weighing pan of a precision balance with electromagnetic force compensation and a measuring accuracy of approx. 0.1 μg which leads into the measuring chamber, whereby the mass of the liquid in the container can be registered continuously. For operation, a pipette that leads from the outside through the wall into the measuring chamber and can be operated from the outside is attached in such a way that it can be used to fill a defined amount of sample liquid into the well-shaped container. At the same time, this pipette serves as a reservoir and for thermal equilibration the solution to be examined. For measurements on composite systems, consisting of a solution in contact with a solid (crystalline) phase of the solute, this measuring pipette can have such a large outlet opening that a small single crystal (typical dimension a few hundred μm) into the solution with the solution to be examined provided for receiving the solution can be introduced. Finally, the measuring chamber wall can contain a feedthrough for a measuring microscope (eg endoscope), which is arranged in such a way that the liquid meniscus in the cup-shaped container and possibly a single crystal located therein can be observed.

According to the invention, the measuring arrangement includes a peripheral for data acquisition and evaluation as well as for control. The temporal recording of the geometry parameters of the hanging drop via the measuring microscope is preferably carried out by means of a downstream image processing.

The vapor pressure of the solvent (e.g. water) in the measuring chamber is determined at a great distance from the sample by the relative air humidity in the measuring chamber and is usually lower than the equilibrium vapor pressure of the solvent over the solution, which is directly above the liquid meniscus. The sample is introduced into the measuring chamber as soon as the temperature of the sample liquid in the pipette has adjusted to the temperature in the measuring chamber (temperature differences of up to 1 degree C are permissible). Immediately after the sample has been introduced, the evaporation of the solvent begins by directional diffusion from the free interface of the sample into the measuring chamber volume. The evaporation rate of the solvent is determined from the measured change in the mass of the sample over time, and the equilibrium vapor pressure of the solvent is determined therefrom.

As a result of the evaporation of the solvent, the temperature of the sample lowers compared to the temperature in the measuring chamber (at a great distance from the drop) until the heat of evaporation (evaporation enthalpy of the solvent) and the drop due to heat conduction from the gas space of the measuring chamber are reduced supplied heat output almost balanced and a quasi-steady temperature difference arises. The evaporation enthalpy of the solvent is determined from the pyrometrically measured time-dependent difference of the temperatures on the sample surface on the one hand and in the measuring chamber on the other hand and by using the measured time-dependent evaporation rate of the sample.

The continuous evaporation of the solvent during the measurement results in a constant increase in the concentration of the solution and thus a constant change (generally a decrease) in the vapor pressure of the solvent as long as the dissolved components do not crystallize. In particular, there are characteristic deviations in the evaporation rate compared to a sample consisting of pure solvent, which are measured and from which the excess proportion of the chemical potential of the solvent is calculated as the target variable. As a result of the increasing concentration of the solution during the measurement, the enthalpy of evaporation of the solvent also depends on the time. The excess of the molecular enthalpy of the solvent in the solution is determined as the target variable from the characteristic deviations, based on the constant enthalpy of evaporation of the pure solvent. If the relative air humidity in the measuring chamber is set so that the vapor pressure of the solvent in the measuring chamber is lower than that above the saturated solution, an initially undersaturated solution shows an increase in the concentration over time as a result of the delayed nucleation kinetics of the crystalline phase , If a small single crystal of the solute of the above-mentioned typical dimensions is introduced into the undersaturated solution of known concentration at a suitable point in time, its dimensions are first reduced by dissolution until crystal growth takes place with the transition to the region of the supersaturated solution. The mass of the crystal introduced is so small that the additional increase in the concentration of the solution caused by its dissolution remains negligible. With the help of the measuring microscope and possibly a downstream image processing, the dimensions of the introduced crystal recorded in time and determined the saturation concentration (point in the phase diagram) from the time of the transition from dissolution to growth. When single crystals are used with sufficiently large dimensions (possibly larger than those mentioned above), the transition from dissolution to growth is registered as a significant kink in the pyrometric temperature measurement, since a change in the heat of solution used and released takes place. If the dissolution or growth rate (mass per time) of the crystal can be determined from the observations with the measuring microscope, the molecular enthalpy of solution follows from the data of the pyrometric temperature measurement, from which the temperature dependence of the saturation concentration (curve in the phase diagram) can be determined ,

In all embodiments of the arrangement according to the invention, if necessary, calibration measurements must be carried out on solutions with a known vapor pressure or known heat of vaporization. In the case of measurements on the hanging drop, those measurement errors are eliminated which result from the fact that the signal applied to the radiation receiver also has a weak dependence on the drop radius. If the sample is placed in the cup-shaped container, the calibration measurements are used to determine transition coefficients of heat and mass transfer between the sample and the measuring chamber.

All versions of the arrangement according to the invention can be expanded such that a plurality of smallest amounts of liquid are arranged in the same way in a common measuring chamber in such a way that the surface temperature and the evaporation or

Condensation kinetics can be measured. If there is a sample among these smallest amounts of liquid, the heat of vaporization and vapor pressure of which are known, the measurement data of the other samples can be related to this known sample, so that those measurement errors which are based on an inaccurate determination of Temperature and vapor pressure in the measuring chamber at a great distance from the smallest amounts of liquid are caused.

In contrast to conventional calorimeters, in the arrangement according to the invention the time-dependent temperature difference ^Δ7 to the surroundings measured on the working substance is a measure of the thermal output N (t) emitted or absorbed by the sample, provided quasi-steady-state conditions are met, ie when

N (t) changes so slowly in time that the course of N (t) at earlier times than the measuring time t only increases as a small correction

Δ7χt) affects. The typical ones to be measured in practice with the arrangement according to its design and its intended use

Heat outputs are in the order of 10 to 100 μW and change with a characteristic time constant τ = \ N (t) l (dN (t) / dt) \ ≥ l Λ0 ³ s. The theory shows that this

Quasi-stationaryity exists. For measurements on the hanging drop, the sensitivity is Δ7χt) / N (t) ≤ l / (4 ^ _g Ä _o (t)), where iζ, (t) is the time-dependent drop radius and a _{g is} the thermal conductivity of the air. From this follows AT (t) / N (t) ~ 6- 10 ³ K / W for the typical values ζ, = 5 • 10 ^{~ 4} m and a _g = 0.025 W / K ^« m.

The theoretical resolving power of the arrangement when measuring N (t) is limited by two fundamental influencing factors: the noise of the thermal sensor together with the downstream electronics and the accuracy of the determination of the evaporation rate. A highly sensitive thermal sensor with a maximum spectral sensitivity in the wavelength range of the maximum of the radiation of the black body at room temperature, ie in the spectral range around 10 μm or above, is used for the pyrometric temperature measurement. This ensures that the surface temperature of the hanging drop is largely independent of the special composition of the aqueous solution. A commercial thermal sensor that does not require cooling is suitable for this. Its time constant is approximately 60 ms. The dynamic range of this thermal sensor is> 10 ⁵ . This allows a convenient calibration of the Thermal sensor to the temperature to be measured in the upper range of the registered radiation power. The detection sensitivity of the thermal sensor was determined in practical operation with a device working on a hanging drop to 170 μV / K. With an optimum key sequence frequency of 10 Hz for the pyrometric measurement, taking into account the influence of the peripheral electronics, a noise-related measurement error of ± 0.5 μV of the registered voltage values results, corresponding to a measurement error of the registered temperature of ± 3-10 ^-3 K per individual measurement. In the subsequent computer-aided evaluation, the temperature data are adapted to the ideal theoretical course over characteristic time intervals of length τ. The statistical error to be assumed (δT ^ άeτ temperature measurement improves to ( _< ST) _Λαf = ± 3 10 ^{~ 5} K, corresponding to a theoretical, noise-related contribution to the resolution limit of the power registered by the device of (r5N) _Ä = 5 -10 ^{" 9} W.

The theoretical accuracy limit with which the sample mass can be determined with the hanging drop is given by the measurement uncertainty SR _Q when determining the drop radius, ie by the limit of the microscopic resolution. For an observation microscope with an aperture <1, an aperture-related measurement error δ ^ «5-10 ^{" 7} m results for an individual measurement. With an automated measurement by means of image analysis, a measurement of the drop radius can be carried out every 10 s. In the subsequent computer-aided evaluation, the Drop radius data over characteristic time intervals of the duration τ adapted to the ideal theoretical course. The theoretical statistical error of the radius measurement improves to (<^ ₎ ) _JtoI = ± 5 10 ^"8 m. When determining the thermal output, this results in an additional error ^ N) ^. This follows from (N) ^ / N (t) _* 3 - (^) _^ / ^ (t) «± 3 -l (r ⁴ and is proportional to the measured power N (t). (ΔN) _Λp has the

The order of magnitude of the theoretical noise-related resolution limit (δN) _R when power in the order of 10 μW is measured. In the case of a device that is equipped with a cup-shaped container for the sample, higher values (but of the same order of magnitude as for hanging droplets) can be achieved with regard to sensitivity, time constants and the noise-related resolution limit of the power measurement, because of the reduced free surface the transition coefficients of heat and solvent transport between the sample and the measuring chamber are smaller than for hanging droplets. With regard to the determination of the evaporation rate of the sample, using precision scales and taking into account the performance of the downstream A / D converter on time-dependent sample masses m (t) of the order of magnitude 5 mg weighings with an accuracy of + 0.1 μg at a time interval of Carry out for 1 s. In the subsequent computer-aided evaluation, these data are adapted to the ideal theoretical course over characteristic time intervals of length r, the statistical error of the weighing to be improved to (δm) ^, = ± 3 - 10 ^{~ 9} g. This causes an error (£ NV in determining N (t) according to

(δN) lN (t) ^ (δm) _slal / m ( _. t) ^ ± l- l ^{~ (} '. For N (t) in the order of 10 μW, (δN) _{w has} the order of 10 ^"π W and is therefore smaller than the noise-related resolution limit.

The invention will be explained in more detail below with reference to the schematic drawing with elevations of three exemplary embodiments. Show it:

1 shows a first arrangement according to the invention, in which the sample is present as a hanging drop, FIG. 2 shows a second arrangement according to the invention, in which the sample liquid is in a nappy-shaped container, and FIG. 3 shows a third arrangement according to the invention with direct measurement of the heat radiation.

In Fig. 1 is a gas-tight measuring chamber 10 with a geometric axis XX by holding means 11 in two parts 101 and 102 divided, of which the upper part 102 can be placed on the lower part 101 after the preparations for the measurement have been carried out. The holding means 11, which are designed as a structure or an intermediate floor with a central opening 111, are intended for holding an elliptical mirror 12 which fills the central opening 111 or is at least located therein and whose optical axis OO preferably coincides with the geometric axis XX. The elliptical mirror 12 is radiolucent in a central part 13 and has two focal points Fi and F ₂ on its optical axis OO, with a liquid drop 14 of a solution at the focal point Fj (and in its immediate vicinity and therefore: focal spot) and at the focal point F. ₂ (and in its immediate vicinity = focal spot) are a thermal sensor 24. The diameter of the drop 14 should be <2 mm and the amount of sample liquid contained in it should be <4 μl. The drop 14 hangs freely and under the effect of gravity, vertically on a capillary 15, the diameter of which is <300 μm, which is connected to a micropipette 17 via a (flexible) pipe or hose connection 16. A measurement beam path 18, which is located essentially in the measurement chamber part 101 and which serves as optical elements, a light source 181, a beam splitter 182, a filter 183 and a lens 184 and an optical sensor 185 (for example a CCD camera) is used for the simultaneous determination of the drop diameter ) contains. The drop 14 is illuminated by the light source 181 via the beam splitter 182 and the lens 184. The measuring beam path 18 reflected and scattered at the drop 14 passes through the lens 184 and the beam splitter 182 to the sensor 185 and generates an image of the drop 14 there. The optical filter 183 arranged in the measuring beam path 18 removes all interfering radiation which influences the thermal equilibrium of the drop 14 and its surroundings. A cooling / heating system 19, which is controlled by a computer 21 using a temperature sensor 20, is used to maintain or regulate the temperature in the measuring chamber 10. In order to maintain a constant moisture in the measuring chamber 10, a moisture sensor 22 and a moisture sensor or dryer 23 are provided, which are also controlled by the computer 21. Finally, the measurement data of the surface temperature from the thermal sensor 24 and the drop diameter, which changes over time, is recorded by sensor 185 and stored and evaluated in computer 21. The following measurement example uses water as solvent and at the beginning of the measurement dissolved 20mM HC1 + 50mM Na citrate + 1% phenol (pH = 6.5) as electrolytic and buffer components as well as 0.6 mg / ml dissolved protein with the molecular weight 35000 (special insulin Mutant) contains. For this measurement, a measurement is carried out on a reference system which, apart from the same composition, contains no protein. This reference measurement simplifies the task of determining the contributions to the measurement data that are directly related to the protein content of the solution. In this example, to achieve defined conditions, all measurements are ended as soon as the drop volume has reached half the initial value or the concentration of the dissolved substances has reached twice the initial value. It takes 1620 s for the actual measurement and 2900 s for the reference measurement.

In the course of the measurement, the droplet radius decreases and the concentration of the dissolved constituents increases as a result of the evaporation, so that the initial data for the droplet radius, the droplet temperature, the absorbed heat output and the vapor or gas pressure of the solvent can be seen more or more change less. Interesting thermodynamic data, which are determined by the protein content, can be determined from the time course of the measured values compared to those of the reference system. In the above example, L / kT = 0.3% _{^ the}

(Molecular) chemical excess potentials of the second and third order solvent in the solution (with respect to the total

Concentration dependence), y the molecular excess enthalpies of the second and third order solvent in the solution (with respect to the total concentration dependence), k the Boltzmann constant and T the absolute temperature.

In this measurement example, both the measured values listed in the table and the corresponding difference amounts to the Reference measurements significantly higher than the noise-related measurement errors derived above. The smallness of the measurement errors caused by noise is very important, for example, if, under the conditions of very slow droplet kinetics (temporal changes in the droplet radius <10 μm / s), small differences (in the range of 1%) to corresponding reference measurements must be reliably determined.

FIG. 2 shows a measuring chamber 25 in which an upper part 251, which forms a hollow body, preferably a hollow cylinder, can be closed airtight by a base 252. A rod-shaped holder 261 of a bowl 262 of an ultra-microbalance (precision scale) 26 is guided through the bottom 252, on which there is a cup or bowl 264 with a sample liquid 265, the capacity of which is 810 μl, directly or via a support 263 the well 264 is thermally insulated from its base. A manipulator 27, which projects through an opening 255 in the wall of the upper part 251 into the measuring chamber 25 and is adjustable in its longitudinal direction, as indicated by a double arrow 29, serves to introduce the sample liquid. The ultra-microbalance 26 is used to determine the sample mass; on the basis of the compensation principle, it keeps the vertical position of the meniscus of the liquid 265 constant due to its rigid coupling to the weighing pan 262 via the carrier 263. The sample liquid 265 is located in the focal point (focal spot) FI or in the vicinity of an elliptical mirror 12 which is attached to the ceiling of the upper part 251 and in whose other focal point (focal spot) F2 and its immediate vicinity a thermal sensor 24 is arranged. The large axis of the ellipse of the mirror 12, on which the focal points FI and F2 are known to lie, coincides with the geometric axis XX of the measuring chamber 25. In order to stabilize or regulate the ambient temperature (T 8. 0.1 ° C.) and air humidity (RH 8. 0.1%), there is a temperature sensor 20 in the measuring chamber 25, with a heating / cooling system 19 and a humidity sensor 22 a humidification / drying system 23. Both the systems, like the Ultarini microbalance 26, are connected to a computer 21, which stores the measured values of the heating / cooling system 19 and the humidification / drying system 23 and controls both systems. On Measuring microscope 28, which projects into the measuring chamber 25 through an opening 254, is adjustable in the direction of a double arrow 30 and is used to observe the sample liquid 265. With the measuring microscope 28, which in the exemplary embodiment can be an endoscope, changes in a crystal introduced into the sample liquid 265 with the manipulator 27 and in the dissolved substance can be observed. The arrangement shown in FIG. 2 can also be used to measure the temporal changes in the sample volume and the temperature, and the vapor pressure and the specific heat of vaporization of the solvent of the substance and further thermodynamic parameters can be determined therefrom by means of the software contained in the computer 21.

In Fig. 3 is similar to Fig. 2, a measuring chamber 25 from a Hohlzy cylinder 251 and a bottom 252. The bottom has a central opening 253 and carries a moisture transmitter or dryer off-center. 23. The holder 261 of a weighing pan 262, which is part of an ultra-microbalance 26, projects through the opening 253. A carrier 263 of a small bowl 264 with a sample liquid 265 is arranged on the weighing pan 262. The bowl 264 has the properties of a gray IR emitter. The hollow cylinder 251 has two openings 254 and 255 for the insertion of an endoscope 28 and a manipulator 27; both can be moved in these openings 254, 255 in the direction of double arrows 30 and 29, respectively. In addition, a cooling and heating system 19 in the form of a spiral attached to the cylinder side walls, a temperature sensor 20, a moisture sensor 22 and a thermal sensor 24 are all arranged in the hollow cylinder 251, all of which are connected to a computer 21 for control purposes. The thermal sensor 24 is thermally insulated and decoupled, taking into account its maximum opening ratio, as close as possible to the carrier 263, in the present case approx. 1 mm below the carrier 263. The distance between the thermal sensor 24 and the well 264 remains constant when the mass of the sample liquid 265 changes due to the compensation principle of the Ulframware balance 26. The cooling and heating system 19 is controlled by the computer 21 in accordance with the temperature uptake of the transmitter 20 in order to maintain or regulate the temperature in the measuring chamber 25. The moisturizer or dryer 23 is controlled by the computer 21 in accordance with the measured values of the transmitter 22 given to the computer 21 in order to maintain a constant gas moisture in the measuring chamber 25. The measured values of the thermal sensor 24 and the balance 26 are likewise forwarded to the computer 21 and processed there for the generation, setting or display of heat quantities, vapor pressure, evaporation ring kinetics or thermodynamic parameters.

When measuring a solution with the starting composition as in the measurement example for FIG. 1, 8 mg of liquid are introduced into the flat cup-shaped container 264 at a measuring chamber temperature of 26.8 ° C and a relative air humidity of 65.0% and initial mass changes of - 1.75 μg / s and an initial temperature decrease of the sample of 1.35 ° C were recorded. This corresponds to an initial power consumption of the sample of 3.9 μW. Compared to the reference system, the differences in mass decrease initially amount to approximately 0.1 μg / s and approximately 0.3 ° C in terms of sample temperature, which corresponds to the detection of a difference in power consumption of 860 nW. Otherwise, the procedure is analogous to the above measurement example for FIG. 1.

All features shown in the description, the following claims and the drawing can be essential to the invention both individually and in any combination with one another.

LIST OF REFERENCE NUMBERS

10, 25 measuring chambers

11 holding means

12 elliptical mirror 13 central part

14 drops of liquid

15 capillaries

16 smoke or hose connection

17 micropipette 18 measuring beam path

19 Cooling and heating system

20 temperature sensors

21 computers

22 Moisture sensor 23 Moisture sensor or dryer

24 thermal sensor

26 Ultra microbalance, precision balance

27 manipulator

28 measuring microscope 29, 30 double arrows

101, 252 lower part, bottom

102, 251 upper part, hollow cylinder

111 central opening

181 light source 182 beam splitter

183 filters

184 lens

185 optical sensor

254, 255 openings 261 holder

262 bowl

263 carriers

264 cells, bowl

265 sample liquid X-X geometric axis

Y-Y optical axis

F "F ₂ focal points

Claims

claims

1. Arrangement for measuring amounts of heat while simultaneously measuring the evaporation and / or condensation kinetics of the smallest amounts of liquid with a uniform evaporating and / or condensing component for determining thermodynamic parameters, characterized in that at least a small amount of liquid is in a measuring chamber with a constant temperature and there is a constant vapor pressure of the liquid, that at least one thermal sensor is provided for repeated measurement of the thermal radiation emanating from the smallest amount of liquid, that a measuring device is provided for determining the time-dependent change in the smallest amount of liquid and that for the registration, display, evaluation and / or further processing of the measured values on

Computer is provided.

2. Arrangement according to claim 1, characterized in that the smallest amount of liquid is in the form of a hanging drop.

3. Arrangement according to claim 1, characterized in that the smallest amount of liquid is contained in a vessel.

4. Arrangement according to claim 1, characterized in that the smallest amount of liquid is a solution.

5. Arrangement according to claim 4, characterized in that the smallest amount of liquid contains a solid phase of a solute.

6. Arrangement according to claim 4, characterized in that the smallest amount of liquid contains a solvent-binding gel-like substance.

7. Arrangement according to claim 1, characterized in that the measuring chamber is closed gas-tight.

8. Arrangement according to claim 2, characterized in that an optical measuring means is provided for determining the time-dependent change in the geometry of the drop.

9. Arrangement according to claim 8, characterized in that the optical measuring means has a filter for the retention of interference radiation.

1 O.Anordnung according to claim 3, characterized in that for the time-dependent change in the mass of the smallest

Amount of liquid is used on a precision balance.

1 1. Arrangement according to claim 1, characterized in that an elliptical reflector is arranged in the measuring chamber, in one focal spot the smallest amount of liquid and in the other

Focal spot is the thermal sensor.

12. The arrangement according to claim 11, characterized in that in

In the case of a smallest amount of liquid contained in a vessel, one focal spot is located on the free interface of the amount of liquid and the other focal spot of the elliptical reflector is located on the

Thermal sensor surface is located.

13. Arrangement according to claim 1, characterized in that the thermal sensor is in the immediate vicinity of the smallest amount of liquid.

14. Arrangement according to claim 1 and 2, characterized in that the drop is generated with the aid of a measuring pipette and an adjustable capillary projecting into the measuring chamber.

15. Arrangement according to claim 1, characterized in that for

Observation and / or measurement of the smallest amount of liquid, including the solid phases contained therein, a measuring microscope is provided which projects through the wall of the measuring chamber and is arranged to be adjustable.

16. The arrangement according to claim 10, characterized in that only the weighing pan of the precision balance with the smallest amount of liquid is within the measuring chamber.

17. The arrangement according to claim 1, characterized in that a corresponding spiral is arranged along the side wall for heating or cooling the measuring chamber.

18. Arrangement according to claim 1, characterized in that a moisture transmitter and or dryer is arranged in the measuring chamber.

19. The arrangement according to claim 1, characterized in that means are provided for generating a constant vapor pressure of the solution.

20. The arrangement according to at least one of the preceding claims, characterized in that the computer also serves to control the heating, cooling, gas moisture and / or gas drying.

21. The arrangement according to claim 1, characterized in that two or more smallest amounts of liquid with a uniform evaporating and / or condensing component are in a measuring chamber.