SU972392A1 - Composition analyzer and its versions - Google Patents

Description

(5) COMPOSITION ANALYZER (ITS OPTIONS)

one

The invention relates to composition analyzers and can be used in the processes of separation, purification and concentration of solutions of synthetic and natural polymers, organic and inorganic substances.

A device is known which includes a vertical rotating column which is two coaxially; , p fastened cylinder, the gap between which is filled with granulated sorbent, solution supply unit, discharge tubes evenly distributed in the lower part of the column, fraction collector., 5 flow rate booster. Using a flow rate driver, the solution of the initial mixture and the solvent are fed to the inlet of the column, thus providing the desired solution flow rate through the 20 rotating annular gap. The solution exits the purl through the outlet tubes, each of which is covered by a filter membrane 1),

One of the basic conditions for maintaining the stationarity of the process of continuous separation in this installation is the uniformity of the solution withdrawal through all discharge tubes. However, under actual operating conditions, this condition is difficult to observe due to the different hydrodynamic resistance of flat filters installed in the output tubes. The porous structure of the filters and the design features of the fasteners have a great influence on the separation efficiency.

A device is known that includes a housing and a lid, between which disks with membrane filters are installed, bolted down, supply and discharge units for the analyzed solution, a flow rate booster and instrumentation. 2

Claims (2)

The disadvantages of this installation are low efficiency and limited application. A known composition analyzer that includes tanks with solvent and analyzed solutions, flow booster, piping system, instrumentation, spiral columns made in disks, collectors, drainage device installed between the disks, and flat semi-permeable filters spaced on the drainage device 3 The disadvantages of the known devices are the impossibility of its use for analyzing a wide range of substances, low productivity and a sufficiently high analysis viscosity. The disadvantages are due to the fact that the flat filters have an insignificant surface (690 cm), and the design features of the installation themselves do not allow the necessary combinations of movement of the analyzed solution to occur due to the fact that there is no independent connection like between spiral columns , and between separate columns and collector. The purpose of the invention is the expansion of analytical capabilities. The goal is achieved by the fact that in an installation that includes a tank with analyzed solutions and solvent, a flow booster, a piping system, instrumentation, collectors, spiral columns in the disks, a drainage device installed between the disks, and flat semi-permeable filters placed on drainage device, the columns are made in the form of two-way spirals on their sides of the disks, equipped with independent entrances and exits connected to the corresponding collectors located inside discs, drainage device outlets and flow impeller inputs are also connected to independent collectors, the outlet has a dispenser with a software for connecting channels to the pressure indicator, the drainage collector is connected to a drain tank, and the output collector is connected to the recirculating manifold, connected to the solvent tank and provided with a shut-off device and a discharge pipe. The plant is equipped with an additional chamber, installed between the tank and the solvent, and the flow booster, with a recirculation trunk connected to this chamber. The device contains a system of valves and control devices according to the number of analyzed fractions, mixture. The goal is achieved by the fact that, in order to separate aqueous solutions of salts with high efficiency of the process, the device is equipped with additional disks installed between the main disks with columns and having spiral columns on both sides, the inputs and outputs of which are connected to a dialysis fluid tank through the channel group of the flow rate driver, while the inputs and outputs of the spiral columns of the main disks are connected to the reservoir with the dialyzed solution through another channel group of the flow rate driver . The disks, the columns of the 8 disks, the collectors, the drainage device and the chambers are made of non-metallic material. The presence of an additional transparent chamber and its connection with the recirculation highway allows visual control of the working solution during the operation of the plant in the modes of concentration and purification by the method of ultrafiltration and diafiltration of solutions of small and large concentrations. Visual inspection additionally provides an improvement in the quality of the analysis, since it makes it possible to intervene in the management of the process. The implementation of the main parts and units of the installation of non-metallic material, such as caprolon, provides the opportunity to explore a larger class of chemical compounds. FIG. 1-3 shows the schema of the system in the first embodiment; for filtration (Fig. 1), diafiltration (Fig. 2) and fractionation (Fig. 3); in fig. assembly scheme of discs with co-tap drainage device and flat semi-permeable filters; in fig. 5 system diagram for the second option. for desalting aqueous solutions; in fig. 6 is an assembly diagram. The system (Fig. 1) consists of a tank with solvent 1, on the lid: a pressure sensor 2 is installed expensively and gas supply lines 3 and solution supply j and a recirculation line 5 are connected, a flow driver 6, connected to the tank by pipeline 7, distributor 8 with a device for programmatically connecting channels to a pressure sensor 9, a collector 10 at the inlet of a column system consisting of extreme disks 11 and average 12 placed one above the other (the circuit for assembling disks with columns is shown separately in FIG.); output collector 13 columns connected to the recirculation line, collector 1 of the drainage device connected to the drain tank 15, shut-off device 16 mounted on the recirculation line and equipped with a discharge pipe. The system assembled according to this scheme operates in the ultrafiltration mode (chromatographic separation without a sorbent). For diafiltration mode operation, the system is assembled as shown in FIG. 2. In addition, a transparent chamber 17 is connected to the supply pipe of solution A with a tank 1 and connected to the collector 7 of the flow rate drive 6. The system is connected to this chamber and recirculated to the main line 5. The system works in the fractionation mode. before-. additional containers 15 and locking-regulating devices 18 according to the number of separating fractions, and the recirculation lines 5 are connected to these containers. The extreme 11 and middle 12 disks have slit-shaped double-stranded columns 19 with autonomous inputs 20 and outputs 21 (average discs have speakers on both sides). A drainage device 22 is installed between the disks, in which annular grooves 23 are made on both sides with a common outlet 2. When assembling, a flat semi-permeable filter 25 is placed on the end disk 11, a porous PTFE substrate 2b is placed on it, and further drainage device 22. the assembly is repeated, and filters of the same type are installed on the same drainage disc. The last to install the upper edge of the research Institute disk 11 and the entire column system is rigidly fixed 1fig. .). In the case of dilution solution, the solution.r tank 1 is filled with a solution, gas 3 is supplied through line 3, the pressure of which is monitored by pressure sensor 2; the solution through the pipeline and the collector 7 serves to stimulate the flow through the distributor 8 channels and the collector 10 in the column system. The pressure in the distributor channels is monitored by pressure sensor 9. The flow of the working solution through the autonomous entrances 20 enters the slit prominent two-way spiral columns 19 of the disks 11 and 12, circulates through the columns and uniformly washes the surface of the flat semi-flexible filters 25. A portion of the solution through the filters and porous substrates 26, passes into the ring-shaped grooves 23 of the drainage device 22 and through the outlet and the collector 14 is withdrawn into the drain tank 15, part of the solution that did not pass the filter through the outlet 21 of the columns and the output collector 13 enters the recirculation The main line 5, through the shut-off device 1b, the resulting concentrate is discharged through the outlet nozzle. In the diafiltration-ultrafiltration of low molecular weight components through a flat semi-permeable filter 25 with preservation of the initial volume, the solutions are fractionated into two fractions. The operation is carried out in the same way as described (ultrafiltration), except that the initial solution and the solvent pass through a transparent chamber 17 for visual observation of the process. When separating the solutions into several fractions, tanks and valves are added to the circuit (fig. 3) according to the number of fractions to be divided. The process is similar to the first case. The system according to the second variant (Fig. 5) consists of a container 1 with a dialyzed solution connected by pipeline 2 through a collector 3 with a flow rate booster k, a collector 5 of the column system consisting of extreme 6 and medium 7 disks placed one above the other. (scheme of assembling disks with columns is shown separately in Fig. 6), output collector 8, to which recirculation is connected to trunk 9, connected to capacity 1, capacity with dialyzing solution 10 connected through collector 11, consumption booster, collector 12 with additional disco input to the booster system, the collector And at the outlet of the column system connected by pipeline 15 with a capacity of 10. The column system (Fig. 6J of the second variant consists of upper and lower disks (not shown) and medium disks 7, in which slit-shaped double-ended spiral-shaped columns 16 having autonomous inputs 17 and exits 18. (in the extreme disks, the columns are made on one side). Additional disks 19 are installed between the disks in which spiral columns 20 are made on both sides having common inputs 21 and output 22. Main The parameters that determine the separation process in the proposed analyzers are the structural and functional characteristics of the flat semipermeable filters, namely, their permeability to solvents and the retarding ability, which allow directly assessing the speed and efficiency of the process. All solutions of biologically active substances containing various have a certain pH and ionic strength to maintain the structure, and therefore the biological activity of the macromoids ekul. As a result of this, flat semipermeable filters must have a high permeability in the presence of inorganic salts. The retention capacity of the filter is related to the ratio of the size and shape of the molecules and particles of the separated substances with the size and shape of the filter pores. The parameters of the filters are also affected by the working conditions — temperature, mixing mode, and especially overpressure and concentration of the biopolymer solution. a The flow of solvent through the filter is expressed as the specific permeability of the filter to the solvent; excessive hydrostatic pressure; filter thickness. The flow of the solute - can be expressed in terms of the retention capacity of the filter R:. 3 C, (1-R) where -p: b-1. - o with concentration of a substance in the filtrate; С (-, - concentration of a substance in the solution above the filter. During ultrafiltration, the delay of the solute by the filter leads to an increase in the concentration on the filter surface (the phenomenon of concentration polarization). The formation of a layer of protein solution leads to an increase in the total filter resistance and, consequently, to a decrease in flow 3p. The formation of a layer of concentration polarization may also lead to a change in the filtering retention capacity, and thus to a decrease in resolution. Analysis of the analysis significantly reduces the effect of concentration polarization by creating an intensive and uniform recirculation of the solution along the entire surface of the filter with a given distribution of fluxes. A decrease in the effect of concentration polarization allows increasing the filtration rate and stabilizing the retention capacity of the system, which leads to an increase in its performance analysis quality and the possibility of expanding the class of the studied substances The following experiments were carried out on mock-up variants in the Scientific and Technological Association of the Academy of Sciences of the USSR: Example 1. Twenty-fold: the concentration and simultaneous partial purification of low molecular weight impurities contained in the cellular homogenate of potato S-virus by ultrafiltration (Fig. 1). PRI me R 2. Fractionation into two fractions and complete washing of the high-molecular component of the oxidizer of combustible shale from the low-molecular diafiltration method (Fig. 2 Example 3. Fractionation into 5 fractions of the concentrate of the high molecular weight component of the oxidant component of the schist by ultrafiltration method (FIG 3) .Example: Desalting of polysaccharide solutions by dialysis method (Fig. 5). 1. Invention Formulation Analyzer, including tanks with analyzed solutions and solvent, flow booster, piping system, control measuring instruments, collectors, spiral columns made in disks, a drainage device installed between disks, and flat semi-permeable filters placed on a drainage device, in order to expand the analytical capabilities of the analyzer, the columns are made in the form of two-way spirals on both sides of the discs, are provided with autonomous inputs and outputs connected to the respective collectors located outside the discs, the outlets of the drainage device and the flow rate stimulation inputs also have autonomous collectors, the flow booster is equipped with a distributor with a programmer connecting the channels to the pressure sensor, the collector of the drainage device is equipped with a drainage tank, and the outlet collector of the columns is equipped with a recirculation line connected to the solution tank and equipped with a 9.10 drainage device and an outlet branch pipe. 2. The ho analyzer p. 1, which has the fact that it is equipped with an additional chamber installed between the tank with the solvent and the flow booster, and the recirculation line is connected to this chamber. 3. The analyzer according to claim T, characterized in that it contains a system of shut-off and regulating devices according to the number of fractions analyzed. mixtures. k. Composition analyzer including dialysis fluid reservoir, flow booster with communication groups. piping system, instrumentation, manifolds, spiral two-column columns made in disks, and flat semi-permeable filters, characterized in that, in order to effectively separate aqueous salt solutions, the analyzer is equipped with additional disks with spiral columns, the inputs and outputs of which are connected to the dialysis fluid reservoir through one communications group of the flow rate booster, while the inputs and outputs of the main-disk spiral speakers are connected to the dialysis reservoir my solution through another group of communications that prompted consumption. Sources of information taken into account in the examination of I.Tubov A. New chroma to graphic separation system. Chromatogr, 1969 AZ, No. i.D .. 2.Ultrafiltration Systems and Equipment Selection Guide and Cataloque, Amicon, No. 26, Paris, p.2, 19793. Reference Guide for Choice of Amikon Materials. Holland, Osterhut, 1979, p. 15 (Russian h.) (Prototype). / // // / J / / / 7 s fug. /  V / 8 Yu // g / cf five fug. f1 / g. J 79 years 23 and Fg / g4 26 2S F1 / g.