RU186728U1 - LABORATORY DEVICE FOR WASHING POWDER CHEMICAL REACTIONS FROM EXTERNAL IMPURITIES - Google Patents

Abstract

The utility model relates to the field of experimental development of multi-stage technological processes, namely, to a laboratory device for washing powder starting substances or products of chemical reactions from impurities, consisting of an ultrasonic bath (1) with power supply and control units, into which a container is immersed (2), equipped with a porous filter baffle at the bottom for separating the solid phase from the liquid phase, connected inlet with the air flow at the inlet, and with direct flow through the liquid phase at the outlet a litter (3) located outside the bathtub (1), to the exit from which through a corner allonge (4) having a lateral outlet, a liquid phase receiver (5) is attached, equipped at the bottom with a tap for its selection or discharge, and the allonge (4 ) a lateral outlet is connected through a stream of air with a three-way valve (6), which ensures the connection of a set of nodes (2) - (5) with a rarefaction device or with the atmosphere. The utility model provides almost complete exclusion of losses of the target product, a significant reduction in the amount of water used for washing water or solvent, the number and time of washing necessary to achieve the required degree of purification of the target product.

Description

The technical field to which the utility model relates.

The utility model relates to the field of experimental development of multi-stage technological processes. More specifically, it relates to laboratory devices used in the study and development of methods for producing biologically active preparations, in particular, at the stages of purification of intermediate synthesis products from foreign impurities. The device may find application for the purification of dispersed precipitates extracted from mother liquors using precipitants from impurities adsorbed or occluded by the precipitate.

State of the art

The processes of isolation of chemical reaction products using precipitants are widespread in chemical technology. Moreover, the resulting products always contain impurities that adversely affect the quality of such substances. In the pharmaceutical industry, extremely high demands are placed on the content of impurities in the intermediate products obtained at individual stages of production, and especially at the final stages of preparation of substances.

In particular, heparin plays an important role in medical practice, an organ preparation obtained from the lungs and mucose of cattle or pigs, which is a direct anticoagulant and is used to prevent and treat thromboembolic diseases, thrombosis during operations on the heart and blood vessels, acute myocardial infarction, as well as to maintain the liquid state of the blood in the apparatus of cardiopulmonary bypass and hemodialysis. Therefore, the urgent problem is the development of technology for the production of low molecular weight heparins such as enoxaparin, dalteparin, nadroparin, etc. [patent RU 2512768 C1, publ. 04/10/2014; Patent RU 2133253 C1, publ. 07/20/1999]. In these processes, the stages of purification of raw materials and intermediate products, as well as the isolation of target products using precipitants, are implemented. Precipitated precipitates are isolated from the mother liquors, usually by centrifugation or filtration on a Buchner funnel or Schott funnel. Then, multiple washing of precipitates from extraneous impurities with water or solvents is performed, loading the precipitates into an apparatus for resuspending and extraction of impurities. The washed solids are again separated as described above. The process is repeated many times until the desired result is achieved, which leads to a significant loss of the target product and a significant consumption of water or solvent.

Thus, there is a need to create an installation that can eliminate these disadvantages.

Utility Model Disclosure

As a result of the development, a laboratory device for washing powder products from impurities obtained by the interaction of the necessary reagents in an aqueous or non-aqueous medium and isolated from the mother liquor by the action of a precipitant is proposed. The proposed device allows for multiple washing of amorphous and crystalline precipitates without moving the target products to other devices, which allows to achieve the following technical results - almost complete elimination of losses of the target product, a significant reduction in the amount of water or solvent used for washing, the number and time of washing necessary to achieve the required degree of purification of the target product.

The technical result is achieved due to the fact that the laboratory device for washing powder starting substances or chemical reaction products from impurities consists of an ultrasonic bath (1) with power supply and control units, into which a container (2) is immersed, equipped with a porous filter partition in the lower part for separating the solid phase from the liquid phase, at the inlet connected with the air flow with the atmosphere, and with the liquid phase at the outlet, with a direct refrigerator (3) located outside the bath (1), to the exit of which through corners oh allonge (4) having a lateral branch, a liquid phase receiver (5) is attached, equipped with a tap in the lower part for sampling or draining, and the allonge (4) is connected by a lateral branch through a stream of air with a three-way valve (6), providing connection of the aggregate nodes (2) - (5) with a device that creates a vacuum, or with the atmosphere.

In a preferred embodiment, in the proposed device (a), the power supply and control unit provides adjustment and maintenance of the ultrasound frequency, its power and bath temperature in the range of 30-40 kHz, 200-400 W and 40-60 ° C, respectively; (b) the porous filter screen is a glass screen such as a Schott filter of classes 1, 2 or 3 with porosity of 0.1-0.16 mm, 0.04-0.1 mm or 0.016-0.04 mm, respectively; (c) a direct refrigerator (3) is a Liebig refrigerator.

In yet another preferred embodiment, the negative pressure generating device is selected from a water jet pump, a diaphragm pump, or a liquid ring pump.

And in another preferred embodiment, the container (2) is provided with a lid on top, preventing the liquid phase from splashing outside the specified container, but allowing communication with the atmosphere.

Brief Description of the Drawing

In FIG. 1 shows a diagram of a laboratory device for washing powder starting materials or chemical reaction products from impurities.

Utility Model Implementation

The design and operation of the proposed utility model will now be described with reference to the positions of FIG. 1. To implement the utility model, it is necessary to provide an ultrasonic bath (1) with an adjustable frequency and temperature of the working medium in the range of 30-40 kHz at 200-400 W and 40-60 ° C, respectively. A container (2) is placed in an ultrasonic bath (1), which is a Schott filter - a glass funnel with a porous glass partition soldered into it. Schott filters with a capacity of 125, 150, 250 or 500 ml are suitable for laboratory purposes. The filter (2), preferably mounted on a tripod with a holder, is connected to a direct water cooler (3) (Liebig refrigerator), into the shirt of which cold, preferably tap water is supplied. The connection of the filter outlet (2) with the inlet of the refrigerator (3) can be made by a curved glass tube with a thin section at the end. Alternatively, the connection can be made with a vacuum hose, a rigid polypropylene tube or a soft siloxane (silicone) hose with a flexible metal or plastic spiral with tightly wound inside. At the end of the hose or tube is a glass pipe with a thin section.

The refrigerator (3) is connected to the liquid phase receiver (5) using an angular allonge (4) with a side outlet. The receiver (5) is made taking into account the work in the conditions of rarefaction created by a water-jet, water ring or diaphragm pump. The residual pressure in such cases is in the range of 0.8-2.6 kPa for a water jet, 5-10 kPa for a water ring and 1-10 kPa for a diaphragm pump. The receiver (5) connected to the allonge (4) with a polished joint may have a capacity exceeding the maximum used volume of the washing liquid by 10-20%. In the event that the receiver (5) has a valve for draining the washing liquid, its capacity may be less than the volume of the liquid phase (washing liquid). The vacuum hose allonge (4) is connected with its lateral outlet through a three-way valve (6) with the vacuum line of the vacuum pump.

The device operates as follows. Working water is poured into the ultrasonic bath (1) in accordance with the operating instructions. The processed solid product is placed in the upper space of the Schott filter (2) in the form of powder or paste, the required amount of washing liquid (water or solvent) is poured so that the liquid level in the filter (2) is lower than the level of working water in the ultrasonic bath (1). To avoid splashing, the filter is covered with an airtight cover (not shown in FIG. 1). They turn on the heating of the working water and set the required temperature, after which they set the necessary working frequency and processing time of the sludge, include ultrasonic emitters and carry out ultrasonic exposure. In this case, the three-way valve (6) is installed in such a position as to isolate the lower space of the filter (2) both from the atmosphere and from the vacuum pump.

After the end of the ultrasonic action, the vacuum pump is turned on, and the valve (6) is moved to the position that connects the filter (2) with the receiver (5) along the flow of the liquid phase. After complete removal of the washing liquid from the filter (2) with a tap (6), the set of units (2) - (5) is disconnected from the vacuum pump. In the event that the capacity of the receiver (5) is less than the volume of the liquid phase, observe its level in the receiver and, upon reaching 80-90% of its capacity, the valve (6) is moved to the position connecting the set of nodes (2) - (5) with the atmosphere , pour the collected liquid phase into a container for storage and further research. The tap (6) is returned to its previous position and the filtering operation is repeated with the collection of portions of the liquid phase necessary for its complete removal the number of times.

The wash liquid is collected in a suitable container for the necessary studies. Rinsing is repeated until reaching the specified parameters of the washing liquid. The washed powder is used in accordance with the technological instruction.

Example 1. Purification of Benzetonium Heparinate

In a glass placed on a thermostatic platform of a magnetic stirrer, pour 62.5 ml of a 16.8% (mass.) Aqueous solution of benzetonium chloride and place the anchor of the magnetic stirrer in it. The solution is heated to 60 ° C. with stirring, and without stopping stirring, 37.5 ml of a 10.7% (w / w) aqueous solution of heparin are added in portions. The reaction is carried out for 50-60 minutes.

The precipitate formed is filtered off and subjected to fractional washing with purified water from excess benzetonium chloride until the wash water absorption at a wavelength of 270 nm (A ₂₇₀ ) is less than 1.50, determined spectrophotometrically (Cary 60 UV-Vis spectrophotometer, Agilent). Measure the absorption of the liquid phase (A ₂₇₀ ). The absorption values of A ₂₇₀ when washing the indicated volumes of water (V, ml) are shown in table 1.

From the above data it follows that the number of washes and the volume of washing water during sonication are reduced by approximately 40%, which confirms the achievement of technical results.

Claims (7)

1. A laboratory device for washing powder starting materials or chemical reaction products from impurities, characterized in that it consists of an ultrasonic bath (1) with power supply and control units, into which a container (2) is immersed, equipped with a porous filter partition in the lower part for separating the solid phase from the liquid phase, at the inlet connected with the air flow with the atmosphere, and with the liquid phase at the outlet, with a direct refrigerator (3) located outside the bath (1), to the outlet of which through an angled allonge (4), having th lateral branch, a liquid phase receiver (5) is attached, equipped with a tap in the lower part for its selection or discharge, and the allonge (4) with a lateral branch is connected via a stream of air to a three-way valve (6), which provides a connection between the set of nodes (2) - ( 5) with a device that creates a vacuum, or with the atmosphere. 2. The device according to p. 1, characterized in that (a) the power supply and control unit provides adjustment and maintenance of the frequency of ultrasound, its power and bath temperature in the range of 30-40 kHz, 200-400 W and 40-60 ° C, respectively; (b) the porous filter screen is a glass screen such as a Schott filter of classes 1, 2 or 3 with porosity of 0.1-0.16 mm, 0.04-0.1 mm or 0.016-0.04 mm, respectively; (c) a direct refrigerator (3) is a Liebig refrigerator. 3. The device according to claim 1 or 2, characterized in that the rarefaction device is selected from a water-jet pump, a diaphragm pump or a liquid ring pump. 4. The device according to p. 1 or 2, characterized in that the tank (2) is provided with a lid on top, preventing the liquid phase from splashing outside the specified tank, but allowing communication with the atmosphere.

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