CS266110B1 - Method of liquid-phase type's change indication and equipment for realization of this method - Google Patents

Abstract

The solution relates to the method of indicating the change type of liquid phase in immiscible liquid polar and non polar systems phase. The transition between the two phases is indicated by changing the electrical conductivity measured the effects of alternating current with a frequency of 0.05 to 100 kHz and with voltage 0.05 to 10 V. Jump change in value electrical conductivity of the investigated environment means changing the type of liquid phase (shift interface). This change is indicates a device consisting of a metering device member, evaluation member, generator alternating low frequency voltage and from an amplifier member. The measuring member is electrode system in a non-conductive protective probe is coupled to an evaluation member, na which are connected to the generator and amplifier a member with a functional switching circuit. solution can be used in the chemical industry.

Description

The invention relates to a method for indicating a change in the type of liquid phase in immiscible liquid systems with a polar and a non-polar phase, as well as to an apparatus for carrying out this method.

In the chemical industry, it is necessary to indicate quite often a change in the type of liquid phase at a particular point in the chemical apparatus, as this may be due to failure or instability of the technological process and timely and reliable indication of this condition is very important to prevent emergencies. Indication of a change in the type of liquid phase in a certain place resp. the indication of the position of the interfacial interface is particularly important in the separation of immiscible phases from the emulsion in phase dividers (separators), where the phases are separated on the basis of their different densities.

Due to the different densities of the two immiscible phases forming the investigated environment, methods for monitoring the position of the interfacial interface are often used in practice. In practice, however, it has also been found that this seemingly simple and reliable method has some significant disadvantages in terms of long-term operation which make the use of this method impossible. The condition for the correct function of devices based on this principle is the constancy of the densities of both phases; however, the densities very often change to a certain extent - either due to concentration changes in the composition of the individual phases or due to temperature changes of the emulsion injected into the separation node. These negative factors are particularly evident in cases where the technological process in the previous stage is not stable, which is typical for the start of production, shutdown and various fault conditions, where, however, it is especially necessary to reliably determine the position of the interfacial interface. The fluctuation of the phase densities then results in the unreliability of the data on the position of the interfacial interface, which changes as a result of these density fluctuations of the divided phases. .

Another serious disadvantage of determining the position of the interfacial interface by a method based on the difference in density of separated phases is that in industrial application of phase separation from emulsion very often over time the so-called third phase is formed at the interfacial interface. separation node gradually accumulate and are often the cause of deactivation of the indication system).

The method of indicating a change in the type of liquid phase in immiscible liquid systems with a polar and a non-polar phase according to the invention eliminates these drawbacks. The essence of the invention lies in the fact that the transition between two phases, one of which is formed by a non-polar solvent with possible content of other organic substances and the other is formed by an aqueous solution of electrolyte, is indicated by a change in electrical conductivity. The electrical conductivity is measured by the effects of an alternating electric current with a frequency of 0.05 to 100 kHz and a voltage of 0.05 to 10 V, whereby a step change in the value of the electrical conductivity means a change in the type of liquid phase.

By changing the type of liquid phase in immiscible liquid systems with one polar phase and the other non-polar phase, it is possible to indicate by the device according to the invention the essence of which consists of a measuring member consisting of a measuring electrode system in a protective probe made of non-conductive material . The evaluation element is further connected to an alternating low-frequency voltage generator and to an amplifying element with a functional switching circuit.

The advantage of the method for indicating a change in the type of liquid phase and the device according to the invention is that it makes it possible to reliably indicate the phase interface of two immiscible liquids with defined properties without cold to change the density of phases forming the environment.

Another advantage is that a suitable choice of the material of the measuring electrodes and their arrangement achieves a long-term reliable function of the device even in those cases when the so-called third phase is formed at the interface interphase.

An advantage of the device according to the invention is also that the protective probe with measuring electrodes is galvanically separated from other parts of the device (evaluation element, alternating current generator).

CS 266 110 B1 low-frequency voltage and amplifier element) and is supplied with alternating electric current with a voltage of 0.05 to 10 V via an isolating transformer, which, with a suitable design of the probe, allows its use even in potentially explosive atmospheres.

The last advantage is that it is possible to place several electrode pairs at different heights in the chemical apparatus and to optically monitor the gradual movement of the interfacial interface in the individual zones, which is suitable especially in phase dividers.

The device according to the invention is schematically shown in the attached drawing.

The device consists of a measuring member 2 formed by a system of measuring electrodes in a protective probe made of non-conductive material, connected to an evaluation member 2, which is further connected to an alternator 3 of low-frequency alternating voltage and ^{to an} amplifying member 2 with functional switching circuits.

The measuring electrodes of the measuring member 2 ^{in the} form of a wire, plate or roller made of electrically conductive material, sufficiently corrosively stable in the given environment are placed in a protective case made of non-conductive material which substantially protects them from adverse effects of the examined environment and are connected to the evaluation member 2. which is supplied from the AC voltage source - generator 2 · The evaluation member 2 evaluates two basic states of the electrode pair: the on state, when there is an electrically conductive phase between the electrodes, and an open state, when there is an electrically non-conductive phase between the electrodes. Optical or electroacoustic signaling of the type of liquid phase in a certain part of the device resp. of the pipeline is provided by an amplifier member 2 with functional switching circuits, which is connected to the evaluation member 2.

Both baseline and emergency conditions are signaled; signaling of an exceptional state allows starting or blocking of other devices, most often pumps or control valves, thus creating a basis for simplifying and automating the handling of two-phase mixtures in apparatus for their separation and handling.

The following examples illustrate but do not limit the scope of the invention.

Example 1 (comparative)

O • An emulsion consisting of a heavier aqueous phase containing up to 15% by weight, inorganic salts and up to 20% by weight, sodium salt of 4-nitrosodiphenylamine and a lighter toluene phase containing up to 10% by weight, organic substances of pitch was injected into a phase separator with a volume of 63 m. character (diphenylamine derivatives). To indicate the interfacial interface in the separator, an instrument based on the principle of different densities of the two phases was installed.

However, due to fluctuations in the densities of both phases, the data of the device were unreliable and over time the measurement completely failed due to the gradual precipitation of substances of pitch-like character on the walls of the separator as well as at the interfacial interface.

Due to the presence of impurities at the position of the interfacial interface, there were overflows of one phase to another with a negative impact on the following technological stages.

Example 2 '

An emulsion consisting of a heavier aqueous phase containing up to 20% by weight, inorganic salts and a lighter toluene phase containing up to 10% by weight, organic substances of a pitch character (diphenylamine derivatives) was continuously injected into the model phase separator. To indicate the position of the phase interface, two measuring members 2 of the probe at a height of 1/3 and 2/3 of the separator were installed in the separator. In each probe there were two platinum electrodes with dimensions of 1.5x1.5 cm, the distance between the electrodes was about 2 cm. The electrodes were placed in a protective case

CS 266 110 B1 made of electrically non-conductive material and is connected by a coaxial cable with an evaluation member 2, formed by a Wheetstone bridge connection. An alternating voltage of 0.5 V with a frequency of 1 kHz was applied to the electrodes.

When the interfacial interface in the separator was in the desired range (between 1/3 and 2/3 of the height), the lower electrode was in the on state and the upper in the open state, which was optically signaled as a normal state. When moving the interfacial interface (change of liquid phase type) outside the required range (above the range-both electrodes in the on state, below the range-both electrodes in the open state) this fact was optically and acoustically signaled, which allowed timely and operative intervention of the separator and penetration phases have been virtually ruled out. The electrodes were resistant to deposits and the device worked reliably for a long time.

Example 3

In the phase separator operating under the conditions as in Example 2, 4 electrodes at different heights were installed in a common protective housing made of non-conductive material, and an alternating voltage was applied to each of these electrodes. The electrically conductive skeleton of the saster was a common electrode for 4 electrodes installed in the separator.

The evaluation device, constructed on the principle of measuring the current flowing through a resistive divider, evaluated the state of the electrodes against the separator ground (on, open), which corresponded to the position of the interfacial interface in the separator and this fact was optically signaled by LEDs.

Example 4

Emulsion of an aqueous phase containing 20% by weight, sodium sulphate and a toluene phase containing 40% by weight. N-nitrosodiphenylamine was fed to a separator, from where the toluene phase flowed into a reservoir, from which it was pumped (through a sampling neck at a distance from the bottom of the reservoir) to the Salsel technological stage - conversion of N-nitrosodiphenylamine to 4-nitrosodiphenylamine in an anhydrous medium. However, in the toluene solution tank of N-nitrosodiphenylamine, after a long time, a certain amount of aqueous phase imperfectly separated in the separator settled on the bottom and there was a danger of its penetration into the rearrangement reactor with negative technological consequences.

In the pipeline route of the toluene solution of N-nitrosodiphenylamine in the immediate vicinity of the reservoir, electrodes were installed in a measuring probe, connected to an evaluation member and energized with an alternating voltage of 0.5 V at a frequency of 1 kHz.

In the event of the penetration of the aqueous phase into the measuring probe, the electrodes are switched on and the switching element unlocks the pump and triggers light and optical signaling, which makes it practically impossible for the aqueous phase to penetrate the non-aqueous medium of shear reactors.

The device worked reliably for a long time. .

Claims (2)

Method for indicating changes in the type of liquid phase in immiscible liquid systems with one polar phase and the other non-polar phase, characterized in that the transition between the two phases is induced by a change in electrical conductivity measured by alternating electric current at 0.05 to 100 kHz and voltage of 0.05 to 10 V, whereby a step change in the value of electrical conductivity indicates a change in the type of liquid phase. ' 2. a device for indicating a change in the type of liquid phase in immiscible liquid systems according to item 1, characterized in that it consists of a measuring member (1) consisting of A system of measuring electrodes in a protective probe made of non-conductive material, connected to an evaluation element (2), which is further connected to a generator (3) of alternating low-frequency voltage and to an amplifying element (4) with functional switching circuits.