RU57139U1 - PLANT FOR EXTRACTION OF EXTRACTS FROM SOLID MATERIALS - Google Patents

Abstract

The installation relates to technical means of a chamber type of periodic action, and is designed to extract water-soluble substances from solid materials, and can be used to obtain extracts from tissues of plant materials, for example, small batches of chain water-soluble components (polysaccharides, mannitol, alginates, etc.) from brown algae (kelp) used in food and pharmaceutical industries. The installation consists of a container (chamber) for conducting extraction, technological pipes, a filtering partition and a squeezing device designed to prepress the material during the extraction process. At the same time, the tank is structurally made in the form of a rectangular case made of channels, equipped with a hinged lid and a removable bottom. A distinctive feature of the installation from existing analogues is the fact that the body can be given a rotational movement, changing the frequency and direction of rotation depending on the type of processed raw materials and the specified process parameters, which makes the installation universal, and allows to increase its productivity. Design features of the installation case, as well as the presence of an squeezing device made in the form of an elastic membrane, which is driven by compressed air, allows the installation to be made compact, less metal-intensive, to reduce specific energy consumption to a minimum, and by changing the valve pressure in the compressed air line (indication which gives a manometer), smoothly adjust the mode of extraction of the extracted material in the "thin layer". The design of the filter septum, made in the form of a multilayer composition consisting of a fine mesh,

a perforated metal sheet and a drainage plate having drainage channels cut into its body for collecting and draining the extract from the cavity of the container, allows extracting the resulting extract uniformly over the entire area (filtering partition, avoiding significant clogging of holes in its elements, increasing the throughput of the partition, obtaining a product with improved quality characteristics 9 s. description of utility model 1 s. - formula of utility model 2 s. - drawing of utility model

Description

The utility model relates to technical means of periodic action and is intended to extract water-soluble substances from solid materials, and can be used to obtain extracts from tissues of plant materials, for example, valuable water-soluble components (polysaccharides, mannitol, alginates, etc.) used at food enterprises and the pharmaceutical industry, from brown algae (kelp).

A well-known installation of periodic action for the extraction of extracts from solid materials of plant origin, in particular, from the seeds of cereal crops, containing a vertical cylindrical body, technological pipes for feeding raw materials and extractant into the cavity of the body, pipes for unloading waste and finished product, filtering partition and squeezing device whose function is performed by flat mixing blades mounted on a vertical drive shaft at an angle to the horizontal (V.P. Stabnikov et al., “Processes and pparaty food production ", textbook, ed.," Food Industry ", Moscow, 1966 s.617-618).

The rotating blades of the installation while mixing the extracted material form a vertical flow of extractant directed downward to the filtering baffle, and, acting on the material with a certain overpressure, create a wringing effect of this material placed on the surface of the baffle, which helps to accelerate the extraction process.

Characterizing the indicated type of installation, it should be noted the complexity of its design, high metal consumption, high manual labor costs during operation, significant losses of the extracted substance, particles of which are often unloaded with the last portions

solvent, significant destruction of the structure of the processed material, difficulties in regulating the technological process, in particular, the degree of squeezing of the raw material mass, relatively low productivity with a large specific consumption of extractant and energy carriers.

The closest in combination of features, technical nature and the achieved result to the claimed technical solution is the installation of the type "ET-04", including a housing, process pipes, filtering partition and squeezing device with a screw drive, designed to extract enzymes from medicinal plants used in the production enzyme medicines, as well as tinctures and syrups for food industry enterprises (“Extractor ET-04”, general view drawing No. ET-04.01.000BO, Design Bureau Tech ologiya "Ulyanovsk, 1990).

However, this installation has a number of significant drawbacks of both structural and operational nature.

These include: low productivity at a relatively high consumption of extractant, a significant proportion of manual labor in the process of servicing the installation, the inability to regulate the operating mode when extracting various types of raw materials, the inability to objectively control the extraction process of the extracted material, including the amount of excess pressure at which it carried out. An uncontrolled spinning process leads to the fact that when exceeding a certain threshold of the degree of extraction of the material, its lower layers adjacent to the filter baffle are excessively compacted, which, in turn, leads to the pressing of holes and blocking of sections of its surface, and this reduces its throughput, increases extractant consumption, and, as a result, productivity decreases. The latter also contributes to the structural imperfection of the filtering partition, made in the form of a metal mesh,

Loosely laid on a perforated metal plate. The fact that the casing is fixed to the supports fixedly does not allow to intensify the technological process due to the turbulization of the extractant flow, acting on it by periodic rotation of the installation casing relative to its horizontal or vertical axis. The presence of the drive of the squeezing device, made in the form of a screw rod, the rotation of which is carried out manually by the helm, as well as the absence of devices that control the degree of squeezing of the extracted material, does not allow to control the amount of excess pressure on this material, and, as a result, to conduct the process in optimal mode , in which the removal of the extract occurs most fully, and the structure of the processed material is not destroyed.

The objective of the utility model is multipurpose use, increasing productivity with minimal extractant consumption, improving the quality characteristics of the target product, ensuring the optimal process mode, reducing labor intensity, lowering metal consumption and manufacturing costs.

The task is realized in that in the known installation for extracting extracts from solid materials containing a housing, technological nozzles, a filtering partition and a squeezing device, according to the claimed technical solution, the housing is pivotally mounted on vertical posts of the support frame with the possibility of rotation relative to the axis of attachment, which is carried out reversible electric drive with adjustable speed, and the squeezing device is made in the form of an elastic membrane fixed between the housing and its cover along the perimeter of the abutment, with the possibility of squeezing into the body cavity with compressed air for a given amount of deflection. At the same time, the filtering partition, fixed by clamps to the bottom of the housing, is made in the form of a multilayer composition consisting of a fine mesh

mesh, perforated metal sheet and drainage plate having channels for collecting and draining the extract from the body cavity.

A distinctive feature is the case pivotally mounted on vertical racks of the support frame with the possibility of reverse rotation relative to the mounting axes, allowing, by rotating the case and periodically changing the direction of rotation, turbulence of fluid movement in its cavity, improving the hydrodynamic mode of the installation, as a result of which the extraction process is intensified and proceeds more evenly, since the entire surface of the material particles is involved in the extraction process, which significantly reduces the extraction period ai, improves the quality indicators of the selected target product and increases the productivity of the installation.

In addition, the installation is universal, as it can be used to isolate the target products from various types of feedstock in their characteristics. This is achieved by the fact that during the transition to processing from one type of raw material to another, the operating mode of the installation can accordingly be changed, in particular, by changing the rotation frequency of the housing up or down, periodically changing the direction of rotation, and also the air pressure in the diaphragm cavity .

As an squeezing device, an elastic membrane is used, fixed between the body and its cover along the abutment perimeter, which during the technological process is squeezed from the cover by compressed air for a specified amount of deflection into the body cavity, and with a certain excess pressure acts on the processed material, squeezing it. And since the thickness of the layer of dispersed mass loaded into the cavity of the housing for pressing is limited by the height of its side walls, the linear size of which is much smaller than their length, it can be argued that the pressing process is carried out in a “thin layer” (60-80 mm), which known to significantly increase

separation of the liquid phase. In addition, since the pressing of the material is carried out by compressed air through an elastic membrane, all technological processes can be carried out in the same working volume, that is, in the cavity of the housing in which the extraction is carried out, while there is no need to reload the dispersed mixture from one apparatus to another , which is important when performing several subsequent extraction operations (preliminary, acid, neutralization) and separation of the liquid phase, which makes the installation compact and obn in operation. The extraction process of the extracted material is controlled and regulated by only two devices - a manometer and a safety valve installed on the compressed air pipeline, while the safety valve prevents the rubber furniture from breaking when the operating pressure limits are exceeded.

The design of the filtering partition, made in the form of a multilayer composition, consisting of a fine mesh nylon mesh, laid with a certain number of layers (depending on the type of processed raw material) on a perforated metal sheet, which rests on the adjoining area on the protrusions of the drainage plate, which are cut in its body drainage and drainage channels for collecting and removing the extract from the body cavity. This design of the filtering septum and its elements can significantly optimize and speed up the filtering process of the separated extract due to its uniform movement over the entire area of the filtering septum, which makes it possible to obtain a product with improved quality characteristics and facilitate the cleaning process of the septum elements after completion of the technological process.

The claimed installation was implemented in the specific embodiment shown in the drawings.

Figure 1 shows the installation for extracting extracts from solid materials (front view, longitudinal section).

Figure 2 shows the drainage plate of the same installation (section AA).

Figure 3 shows the drainage plate of the same installation (top view).

Figure 4 shows a schematic diagram of the same installation with its connection to a compressed air system.

The apparatus for extracting extracts from solid materials contains a rectangular housing 1 made of a channel, in the cavity of which a squeezing device 2 is installed, made in the form of an elastic rubber membrane located between the housing 1 and the cover 3, as well as a filter partition, consisting of a fine mesh 4, a metal perforated sheet 5 made of stainless steel and a drain plate 6 made of sheet nylon 10 mm thick, which are placed on a removable bottom 7 and fixed between with a flange 3 and a bottom 7 with clamps 8. In the plate 6 there are drainage 9 and outlet 10 channels, and in the center there is a drain hole 11. An axis 12 and a shaft 13 mounted in bearings 14, which are supported by vertical posts, are fixed to the housing 1 from the sides 15 of the supporting frame 16, while the shaft 12 is connected to an electric drive consisting of an electric motor 17 and a variator 18, which is designed to regulate the speed of the housing 1. The cover 2 is attached to the housing 1 by means of hinges 19 and coupling bolts 20 with nuts 21. The installation is equipped with technological patr by the sides, in particular, a nozzle 22 with a shut-off valve 23 and a fitting 24 is fixed to the housing 1, designed to fill the extractant with the cavity of the housing 1. On the lid 2, a nozzle 25 with a shut-off valve 26 and a fitting 27 is fixed for supplying compressed air to the drive of the squeezing membrane 2, and on the bottom 7 a pipe 28 is fixed with a shut-off valve 29, designed to remove the resulting extract from the cavity of the housing 1.

The auxiliary equipment designed to drive the squeezing device 2 into operation includes: a small-sized compressor 30 with a receiver 31, by means of a shut-off valve 32, connected to a compressed air pipe 33, at the end of which there is a threaded threaded sleeve coupling 34, interfaced with the nozzle 27 for supply of compressed air into the process pipe 25. A safety valve 35, a manometer 36 and a valve 37 are installed on the pipeline 33 to relieve excess pressure in the compressed air system and its product Application.

Installation for extracting extract from solid materials works as follows.

The housing 1 is deployed in a horizontal position, and the cover 3 on the hinges 19 together with the squeezing membrane 2 attached to it is pushed to the side, and crushed material is loaded into the cavity of the housing, placed evenly on the surface of the filtering partition, after which the cover is attached to the housing with hinged bolts 20 , the coupling nuts 21 of which uniformly compress the cover 3 and the membrane 2 along the perimeter of the abutment to the housing 1. In this case, with the clamps 8, all elements of the filter partition are fixed along the perimeter of the abutment to the bottom 7. the housing 1 is installed in a vertical position (Fig. 1, dotted) and in its cavity through the pipe 22 through the valve 23 and the fitting 24, the extractant is poured, after which the valve 23 is closed, and the coupling 34 is connected to the fitting 27, and the valves 26 and 32 open . From the included compressor 30, compressed air is pumped into the receiver 31, and from it with steady pressure through a pipe 33 enters the space between the housing 3 and the membrane 2, squeezing the latter by a certain amount of deflection into the cavity of the housing 1, the more prog used, the more positive pressure acts on the membrane 2 is swollen by contact with the extractant material, pressing it. The excess pressure (150 ÷ 350 kPa) is controlled by

manometer 36 and is set depending on the type of raw material, characteristics and stages of extraction (preliminary, acid, neutralization, etc.). The extraction period in time depends on the above characteristics and can be from 1 to 12 hours

The optimally established value of the mechanical effect on the processed material during squeezing out the liquid phase from its swollen particles significantly improves the molecular diffusion process, accelerates the extraction of target components from raw materials, thereby increasing plant productivity and increasing the quality of the extract.

The technology for extracting extracts from solid materials at the claimed installation provides for its phased processing in several stages, and since pressing and extraction are carried out in the same cavity of the housing 1, there is no need to reload the dispersed mixture from one apparatus to another, the processing time is reduced, which is important, since a sufficiently large number of extraction operations (preliminary extraction, 1, 2 and 3 extraction, 1, 2, 3 and 4 neutralization) is carried out sequentially, after each of them requires the maximum separation of the liquid phase.

The intensification of the process by turbulization of the components in the cavity of the housing 1 is carried out by rotation with a given number of revolutions with a periodic change in the direction of rotation, and the modes of turbulization are set depending on the type of material being processed, its degree of grinding and extraction stages. The process of rotation of the housing 1 is carried out with closed valves installed on the technological pipes and the disconnected compressed air system, and is carried out by an electric motor 17 by means of a variator 18.

The pressing process in the installation is carried out with the horizontal arrangement of the housing 1, while the extract moves from top to bottom,

seeping through the mesh 4, and passing through the perforated holes of the sheet 5, enters the drainage channels 9 and the outlet 10. To remove the extract obtained from the working cavity of the housing, the valve 29 is opened and through the drain hole 11 of the drainage plate 6 through the technological pipe 28, the extract is discharged into the receiving capacity, after which they begin to unload the solid phase, having previously disconnected the compressed air system from the installation. To do this, the valve 32 is closed and the valve 37 is opened, through which the pressure in the pipe 33 is released, and the system is purged, and the threaded sleeve coupling 34 is disconnected from the fitting 27. Then, the nuts 21 and the coupling bolts 20 are tilted away from the cover 3, after which it is retracted on hinges 19 to the side, allowing access to the cavity of the housing 1, from which the solid phase is unloaded. After the above operations are completed, clamps 8 and all elements of the filtering partition that are cleaned and rinsed are removed from the body cavity.

Claims (6)

1. Installation for extracting extracts from solid materials, comprising a housing, process pipes, a filtering partition and a squeezing device, characterized in that its housing is pivotally mounted on vertical posts of the support frame with the possibility of rotation relative to the axis of attachment. 2. Installation according to claim 1, characterized in that the rotation of the housing is carried out by a reversible electric drive with an adjustable speed. 3. The installation according to claim 1, characterized in that the squeezing device is made in the form of an elastic membrane installed between the housing and its cover along the perimeter of the abutment with the possibility of squeezing the membrane into the cavity of the housing by a predetermined amount of deflection. 4. Installation according to claim 1, characterized in that the squeezing device is driven by compressed air. 5. Installation according to claim 1, characterized in that the filtering partition is made in the form of a multilayer composition consisting of a fine mesh, a perforated metal sheet and a drainage plate, the latter having drainage channels for collecting and draining the extract from the body cavity. 6. Installation according to claim 1, characterized in that the extraction process of the extracted material is carried out in a "thin layer".