KR100193220B1 - Method of measuring evaporation rate using steady state evaporation-condensation method - Google Patents

Abstract

The present invention relates to a method for measuring the evaporation rate of a liquid sample in a steady state of the same evaporation rate and condensation rate of the liquid sample, and to an evaporation rate measuring apparatus including a plurality of evaporator collectors used therein. According to the present invention, since the evaporation rate of all liquid samples can be measured by a simple method without any initial error that may occur at the initial evaporation rate, and the precision of the apparatus used for the evaporation rate measurement is not greatly required, the evaporation rate measuring device The configuration is relatively simple.

Description

Method of measuring evaporation rate using steady state evaporation-condensation method

1 is a schematic diagram of an evaporation rate measuring apparatus according to the present invention.

Figure 2 is a graph showing the temperature and pressure changes over time of water, ethanol and isopropanol measured according to Example 1 of the present invention.

3 is a graph comparing the evaporation rates of water obtained in Examples 1, 2, 3, 4, and 5 of the present invention with theoretical values, and calculating the evaporation-condensation coefficient, and then comparing the results with conventional experimental results.

* Explanation of symbols for main parts of the drawings

1: evaporation cell 2: thermostat

3: thermometer 4: pressure gauge

5: vacuum pump 6: cooling tank

c1: first evaporator collector c2: second evaporator collector

v1: valve 1 v2: valve 2

v3: valve 3 v4: valve 4

v5: valve 5 v6: valve 6

v7: Needle Valve

The present invention relates to a novel method and apparatus for measuring evaporation rate. More specifically, the present invention relates to a method for measuring the evaporation rate of a liquid sample in a steady state where the evaporation rate and the condensation rate of the liquid sample are the same, and an apparatus for measuring an evaporation rate including a plurality of evaporator collectors.

Evaporation is one of the methods that has long been used for the separation of liquid or solid mixtures. However, in order to use this method, it is essential to know the physical properties of the evaporation rate of pure components. Therefore, various methods for measuring this evaporation rate have been proposed, and many measurement values through this method have been reported. However, conventional methods of measuring evaporation rates are methods for measuring evaporation rates in most abnormal conditions.

For example, a method of measuring the evaporation rate of water and ice by measuring the pressure change of the evaporation cell with respect to the initial time in an abnormal state and comparing it with the evaporation rate theory has been reported [LJ Delaney et al. , Chem. Eng. Sci., 19: 105-114 (1964)]

There is also an example in which the evaporation rate of water is measured by calculating the evaporation rate by measuring the weight change of the evaporation in an abnormal state [W. J. Hisatake et al., Appl. Phys., 73: 7395-7401 (1993).

This method of measuring the evaporation rate in an abnormal state is a method of calculating the evaporation rate by measuring a variable that can calculate the evaporation rate at an initial time in a state where the evaporation rate changes with time. At this time, mainly measured variables are the pressure or weight of the system or the diameter of the droplets. When the evaporation rate is measured by such an abnormal state method, since the evaporation is very fast at the initial time, the measurement value is likely to include an error, and the measurement of the change amount according to the initial evaporation time should be very accurate. To this end, the precision of the device must be increased. In the case of measuring the evaporation rate by measuring the pressure in an abnormal state, a precise pressure gauge and a pressure recorder without time delay must be attached, and the method of measuring the evaporation rate by measuring the weight in an abnormal state is required It is unaffected and requires a high level of precision and weighs up to 10 ^-4 g or less and is complex on the device. In addition, if the evaporation rate is measured by measuring the change in the diameter of the droplet in an abnormal state, the diameter of the droplet should be measured continuously every very short time. Transparent evaporation cells must be used, and such complex devices can be used to reduce errors in evaporation rate measurements. As a result, conventional abnormal state measurement methods have a lot of influences on the initial value, and have a disadvantage that the accompanying device must be precise.

Accordingly, the present inventors have made intensive studies to solve the problems of the prior art, and as a result, a steady state in which the evaporation rate and the condensation rate of a liquid sample are the same by using an evaporation rate measuring device equipped with a double evaporator collector After evaporating the liquid sample for a certain period of time to condense, and calculating the evaporation rate directly from the measured amount of condensation, it is confirmed that the evaporation rate of the liquid sample can be measured by a relatively simple method without errors occurring at the beginning of evaporation. The invention has been completed.

After all, the main object of the present invention is to provide a novel method of measuring the evaporation rate for measuring the evaporation rate of a liquid sample at steady state.

Another object of the present invention is to provide an evaporation rate measuring apparatus used for measuring the evaporation rate in the steady state.

Other objects and advantages of the present invention will become apparent from the following detailed description.

The evaporation rate measuring method of the present invention for achieving the object of the present invention comprises the steps of evaporating and condensing a liquid sample until reaching a steady state without temperature and pressure change over time; Further evaporating and condensing the liquid sample for a predetermined time in the steady state; And obtaining an evaporation rate from the evaporation time at the steady state and the measured amount of condensation.

The liquid sample to measure the evaporation rate by the evaporation rate measuring method according to the present invention can be any liquid capable of evaporation and condensation, it is preferable to use the dissolved gas in advance.

That is, in the method of measuring the evaporation rate according to the invention, the evaporated liquid evaporated until reaching a steady state is preferably condensed and removed, and before the steady state is reached and the steady state is reached, the evaporated liquid is collected. The silver should be carried out in the same state without changing pore conditions such as miso and pressure, respectively. Preferably, it is preferable to use a collector in a new evaporated liquid having the same collection conditions.

In addition, the apparatus for measuring the evaporation rate in the steady state according to the present invention, the evaporation unit consisting of the evaporation cell and temperature control and measuring end; A condensation collecting unit comprising a plurality of evaporating liquid collectors for condensing and collecting the liquid sample evaporated in the evaporating unit; And, it characterized in that it comprises a pressure adjusting unit for adjusting the pressure of the total gauge.

In the evaporation rate measuring apparatus of the present invention, a thermostat and a thermometer are used as the temperature adjusting and measuring means, and the evaporator collector is installed in a double manner so that evaporation and condensation do not affect each other before and after reaching a steady state. The pressure regulator consists of a vacuum pump, a needle valve and a pressure gauge.

Hereinafter, preferred embodiments of the evaporation rate measuring method and apparatus of the present invention will be described in more detail with reference to the accompanying drawings.

First, with reference to Figure 1 will be described in detail a preferred embodiment of the evaporation rate measuring apparatus of the present invention.

1 is a schematic diagram of an example of an evaporation rate measuring apparatus used to measure the evaporation rate of a liquid sample in a steady state according to the present invention. Evaporation rate measuring apparatus of the present invention is divided into three parts, evaporation unit, condensation collecting unit and pressure control unit. The evaporation unit is composed of an evaporation cell (1) capable of evaporating a liquid sample, a thermostat (2) for maintaining the evaporation cell at a constant temperature, and a thermometer (3) for measuring the temperature of the liquid. The condensation collector is a first evaporator collector (c1) for collecting the evaporated liquid sample before reaching the steady state and a second evaporator collector (c2) for collecting the evaporated solution evaporated for a predetermined time after reaching the steady state. ) And cooling tanks 6 and 6 'for maintaining the first and second evaporator collectors at a low temperature. In FIG. 1, the evaporator collectors c1 and c2 are shown only in duplicate, but can also be configured in multiples for accuracy. The pressure regulator consists of a vacuum pump 5, a needle valve v7 and a pressure gauge 4.

Next, a specific example of the evaporation rate measuring method according to the present invention will be described with reference to FIG. 1 as follows: (1) First, a liquid from which dissolved gas has been previously removed is placed in an evaporation cell 1, and an evaporation cell ( Close valve 1 (v1) attached to 1). The thermostat 2 is operated to maintain the evaporation cell 1 at a constant temperature.

(2) The outside of the evaporation cell 1 is lowered to a predetermined pressure by using the vacuum pump 5 and the needle valve v7. At this time, the valve 1 (v1) and the valve 3 (v3) are closed.

(3) When a certain pressure is reached, the first evaporator collector (c1) and the second evaporator collector (c2) are immersed in a cooling tank (6, 6 ') containing liquid nitrogen and the temperature is lowered.

(4) Open valve 1 (v1) and measure the change in temperature and pressure over time. At this time, the evaporated liquid is condensed in the first evaporator collector c1. However, the temperature and pressure of the first evaporator collector c1 and the second evaporator collector c2 should be kept the same.

(5) After a certain time has elapsed, when the temperature and pressure have reached a steady state, the valve 3 (v3) is opened at the same time while closing the valve v2. At this time, the temperature and pressure of the first evaporator collector c1 and the second evaporator collector c2 are maintained in the same state.

(6) From this point, the evaporated liquid is condensed in the second evaporator collector c2, and the time is measured again. After a certain period of time, all the valves are closed and the evaporation rate is calculated by measuring the amount of condensation in the second evaporator collector (c2).

Hereinafter, the present invention will be described in more detail with reference to Examples. These examples are only for illustrating the present invention in more detail, it will be apparent to those skilled in the art that the scope of the present invention is not limited to these examples.

Example 1

In order to find out the time to reach the steady state of various liquid samples and the temperature and pressure at the steady state, the pressure of water (○), ethanol (□) and isopropanol (△) The temperature change was measured. The result was as shown in FIG.

As shown in Figure 2, the temperature and pressure of the system decreases with time, and reaches a steady state, which is an area in which the evaporation rate can be measured in which the temperature and pressure do not change after a certain time. For water, the temperature at steady state was 14.3 ° C and the pressure was 12.8mmHg. The steady state was reached 5 minutes after the start of evaporation. Ethanol and isopropanol took 7 and 2 minutes to reach steady state, respectively.

Example 2-5

The temperature and pressure at steady state and the time to reach the steady state may vary depending on the external conditions for the evaporation rate measurement, ie the initial conditions. To confirm this, the temperature and pressure at steady state and the time to reach steady state were measured while changing the initial external temperature among various liquids, especially for water. The results were as shown in the table below.

[Table 1] Effect of initial temperature change on temperature, pressure and arrival time at steady state

Example 6

After the evaporation rate of water was measured under various conditions of Examples 1, 2, 3, 4, and 5, it was converted into a condensation coefficient according to the following equation and compared with the evaporation rate published by other conventional methods.

Wherein As is the evaporation surface; dn _e / dt is the evaporation rate (moles of evaporated molecules per hour); P ^* is saturated steam pressure; P is pressure; M is molecular weight; R is a gas constant; T is the absolute temperature. The result is as shown in FIG. In FIG. 3, ○ indicates Delaney et al., LJ Delaney et al., Chem. eng. sci., 19: 105 (1964), and □ is the Pruger (Pr). ger) et al. [WZ Pr ger, Physik, 115: 202 (1940)] and Δ is measured by Alty et al. (T. Alty et al., Proc Roy Soc., A149: 104 (1935)). Value.

As shown in FIG. 3, it can be seen that the measured value obtained by the present invention coincides well with the condensation coefficient obtained by the conventional method according to the temperature.

As described in detail and demonstrated above, according to the present invention, the evaporation rate of all liquid samples can be measured by a simple method without any initial error that may occur at the initial evaporation rate, and the precision of the apparatus used for the evaporation rate measurement is Since it is not greatly required, the configuration of the evaporation rate measuring device is relatively simple.

Claims (1)

Evaporating and condensing the liquid sample from which the dissolved gas has been removed in advance until reaching a steady state without temperature and pressure change over time; The second evaporator collector which condenses and removes the evaporated liquid which evaporates until reaching the steady state, and maintains the liquid sample which reached the steady state under the same conditions as the collection conditions before the evaporant collection reaches the steady state. Further evaporating and condensing for a predetermined time using; And estimating the evaporation rate from the evaporation time and the measured condensation amount in the step.