RU224425U1 - DEVICE FOR SEPARATION DURING EXTRACTION PROCESS - Google Patents

Abstract

The utility model relates to separation in the process of obtaining extracts from plant materials and plant waste and can be used in the food industry. The device for separation during the extraction process consists of a sealed cylindrical housing equipped with an ultrasonic submersible fog generator with a removable housing cover installed in the upper part of the housing and equipped with a sealed lead-in for the power cable of the fog generator and three outlets. The first outlet is connected through a shut-off valve through a raw material supply pipeline to a tank for loading raw materials, covered by a lid of the tank for loading raw materials. The second outlet is connected through a shut-off valve to the compressor via an air supply pipeline. The third outlet is connected through the fog supply pipeline to the condenser cover, which ensures the tightness of the condenser and is equipped with an internal outlet and tap. The condenser cover is connected through a condensed product outlet pipeline with a capillary installed at the end through a collection tank cover equipped with a filter for removing excess air to the collection tank. The condensed product discharge pipeline with a capillary installed at the end is lowered to a height of 5 mm from the bottom of the collection tank. The technical result is the preservation of useful properties and initial temperature during the extraction process, the absence of the need for heat treatment, and also ensuring the possibility of further use of the resulting product in its original form. 3 salary f-ly, 1 ill.

Description

The utility model relates to the food industry, namely to technical and technological solutions for separation in the process of obtaining extracts from plant materials and plant waste. The utility model is aimed at increasing the efficiency of resource use, ensuring the quality and safety of food systems, as well as reducing the number of heat treatments and the use of extracts obtained in the production of food products and aqueous solutions in catering establishments.

A known device for obtaining extracts of plant raw materials contains a housing divided into two zones by a vertical partition that does not reach the bottom of the housing. In one zone of the housing there is a pipe, in the upper part of which there is a hatch for loading raw materials. This zone is closed by a lid with a pulsator with a drive and a liquid level sensor installed on it, connected to each other through a control unit. In this zone, above the nozzle for loading raw materials, but below the liquid level sensor there is a nozzle for extracting the extract. Another zone is connected to a pipe for unloading extracted raw materials, on which there is a pipe for supplying the extractant. The invention makes it possible to provide a high degree of extraction at a lower temperature and in less time than in known devices and extraction methods used in industry. [RF Patent No. 2312697, IPC B01D 11/00 (2006.01)].

The disadvantage of the analogue is the use of a non-separable structure, which is difficult to pre-treat to ensure cleanliness, as well as the use of complex body shapes, which can be made of metal or plastic, but not inert glass.

The closest in technical essence and achieved result is an ultrasonic installation for gas-liquid extraction of plant and animal raw materials and contains a technologically connected and sequentially interacting sealed housing, a quick-release self-sealing hatch, a glass extractor, a funnel for collecting condensate, a cooler, a heater, a manipulator handle, a generator, additionally installed four miscellaneous collectors located outside the sealed housing, and a generator containing an ultrasonic vibration device. [RF Patent PM No. 93688 IPC B01D 11/02 (2006.01)].

The disadvantage of the prototype is the need to use a heater and cooler during the extraction process, which affects the quality characteristics of the resulting product.

The purpose of the utility model is to develop a device of a more advanced, simplified design that allows separation in a heat-free process for obtaining extracts from plant raw materials and plant waste while maintaining beneficial properties and the original temperature.

The technical result of the proposed device is the preservation of useful properties and initial temperature during the extraction process, the absence of the need for heat treatment and the possibility of further use of the resulting product in its original form, including in industrial production and public catering establishments.

The specified technical result is achieved by the proposed device, containing a sealed cylindrical housing equipped with an ultrasonic submersible fog generator with a removable housing cover installed in the upper part of the housing and equipped with a sealed lead-in for the power cable of the fog generator and three outlets, the first outlet being connected through a shut-off valve through a raw material supply pipeline to a tank for loading raw materials, covered by a lid of the tank for loading raw materials, the second outlet is connected through a shut-off valve to the compressor through an air supply pipeline, the third outlet is connected through a fog supply pipeline to the condenser cover, while the condenser cover ensuring the tightness of the condenser is equipped with an internal outlet, a tap and through the condensed product outlet pipeline with a capillary installed at the end is connected to the collection tank through a collection tank cover equipped with a filter for removing excess air, and the condensed product outlet pipeline with a capillary installed at the end is lowered to a height of 5 mm from the bottom of the collection tank.

The sealed housing, condenser, tank for loading raw materials, and collecting tank are made of glass, which is due to the inert properties of glass. The walls of the sealed glass housing eliminate the influence of ultrasonic vibrations of the fog generator on the housing itself; there is no release of microparticles into the product, as, for example, when using a plastic housing. The inert properties of glass do not change the quality characteristics of the resulting product, as, for example, when using metal cases. Due to the glass design and the principle of dismountable design, individual elements can be thoroughly washed and subjected to any method of sterilization without any problems, thereby ensuring microbiological safety before the extraction procedure begins.

The removable housing cover, tank cover for loading raw materials, condenser cover, and collection tank cover are made of stainless steel and can be equipped with a threaded or flange connection, which provides quick access to all elements and ease of operation.

The length of the second outlet is 1/2 of the height of the sealed cylindrical body, which ensures maximum pickup of the generated fog, while the air supplied by the compressor does not mix the processed raw materials.

The length of the internal outlet is 1/3 of the height of the condenser, which ensures the retention of the condensed product in the condenser to prevent backflow into the cylindrical body; in addition, at this height, the most uniform distribution of fog throughout the condenser is ensured.

The ultrasonic fog generator is equipped with a built-in level sensor; when the level in the cylindrical body decreases, the device turns off and extraction stops.

The installation's performance is regulated by selecting and adjusting the air supply compressor, which ensures the displacement of mist from the cylindrical housing into the condenser. The compressor performance should have a ratio with the volume of feedstock of 1 to 4 m3, for example, for 0.25 liters of feedstock a capacity of at least 1 l/min is required.

During operation of the proposed device, no heating is required to separate the extract from the feedstock.

The utility model is illustrated by a drawing.

The inventive device for separation during the extraction process is shown in Fig. 1.

The device for separation during the extraction process includes: an ultrasonic submersible fog generator 1, a sealed cylindrical housing 2, a removable housing cover 3, a sealed inlet 4, a fog generator power cable 5, a first outlet 6, a stop valve 7, a raw material supply pipeline 8, a reservoir for raw material loading 9, tank lid for loading raw materials 10, second outlet 11, stop valve 12, air supply pipeline 13, compressor 14, third outlet 15, fog supply pipeline 16, condenser cover 17, condenser 18, internal outlet 19, valve 20, condensed product discharge pipeline 21, capillary 22, collection tank cover 23, excess air removal filter 24, collection tank 25.

The separation device during the extraction process operates as follows.

To ensure microbiological safety, the unit is completely disassembled and undergoes a sterilization and assembly process. The lid of the tank for loading (pre-crushed) raw materials 10 is removed from the device, then the crushed raw materials are loaded into the tank for loading raw materials 9. Fruits and vegetables and processing waste can be used as feedstock. For example, crushed peelings, cake, trimmings and other waste from the processing of onions, beets, carrots, pumpkins and other products of plant origin with pronounced coloring properties. The degree of grinding should ensure unhindered passage of raw materials through the raw material supply pipeline 8 and through the shut-off valve 7 on this pipeline. After loading, the lid of the tank for loading raw materials 10 is closed (the raw materials are shown in Figure “B”), the shut-off valve 7 on the raw material supply pipeline 8 is opened until the required filling of the sealed cylindrical housing 2 is closed, then it is closed.

After filling the sealed cylindrical housing 2, the ultrasonic submersible fog generator 1 is started, at the same time the compressor 14 is started, which supplies air (air is shown in figure “A”) through the supply pipeline 13 through the stop valve 12 and the second outlet 11. Stop valve 12 provides additional regulation of compressor performance 14. During operation, the generated fog fills the space between the sealed cylindrical housing 2 and the removable housing cover 3. The removable housing cover 3 has a sealed lead-in 4 for passing the power cable (the power supply is shown in Figure “B”) of the fog generator 5 and providing tightness. As air enters from the compressor 14, the resulting fog is forced out through the third outlet 15 through the fog supply pipeline 16 and the internal outlet 19 installed in the cap of the condenser 17 into the condenser 18. As the fog enters the condenser 18, condensate is formed due to the constant supply of fog, which accumulates on cap of the condenser 17. As it accumulates, the condensate is forced out through the tap 20 through the condensed product outlet pipeline 21 and through the capillary 22 into the collection tank 25. The condensed product outlet pipeline 21 has a rigid seal in the lid of the collection tank 23, in which an additional filter for removing excess air is installed 24. The capillary 22 installed at the end of the condensed product discharge pipeline 21 is lowered to a height of 5 mm from the bottom of the collection tank. In the process of displacing the fog and condensed product from the condenser 18, passing through the capillary 22, the fog is further condensed; as the collection tank 25 is filled, due to the passage of the fog through the aqueous solution, complete retention of the resulting product is ensured (the product is shown in Figure “D”). The exhaust air passes through an excess air filter 24, which is made of porous material.

As the level in the sealed cylindrical housing 2 decreases and if there is feedstock in the raw material loading tank 9, during operation of the device, periodic replenishment from the raw material loading tank 9 is possible.

After complete consumption of the feedstock and completion of the extraction process, the device is disconnected from the power supply network, completely disassembled, washed and cleaned of any remaining feedstock. The resulting product can be used without additional heat treatment due to the initial sterility, prepared for operation of the installation and the disinfecting effect of ultrasonic treatment.

Thus, the set of features specified in the formula of the utility model makes it possible to achieve the desired result.

Claims (4)

1. A device for separation during the extraction process, consisting of a sealed cylindrical housing equipped with an ultrasonic submersible fog generator with a removable housing cover installed in the upper part of the housing and equipped with a sealed lead for the power cable of the fog generator and three outlets, the first outlet being connected through a shut-off valve through a pipeline supply of raw materials with a tank for loading raw materials, covered with a lid of the tank for loading raw materials, the second outlet is connected through a shut-off valve through an air supply pipeline to the compressor, the third outlet through a mist supply line is connected to the condenser cover, while the condenser cover, which ensures the tightness of the condenser, is equipped with an internal outlet, tap and through the condensed product outlet pipeline with a capillary installed at the end through the lid of the collection tank, equipped with a filter for removing excess air, is connected to the collection tank, and the condensed product outlet pipeline with a capillary installed at the end is lowered to a height of 5 mm from the bottom of the tank - collection. 2. The device according to claim 1, characterized in that the sealed housing, condenser, tank for loading raw materials, and collection tank are made of glass. 3. The device according to claim 1, characterized in that the removable housing cover, the tank cover for loading raw materials, the condenser cover, and the collection tank cover are made of stainless steel and can be equipped with a threaded or flange connection. 4. The device according to claim 1, characterized in that the length of the second tap is 1/2 of the height of the sealed cylindrical body, and the length of the internal tap is 1/3 of the height of the capacitor.