CS263361B1 - Process for preparing a mixture of hypocholesterolemic compounds - Google Patents

Abstract

The solution concerns the design of a storage tank for active ventilation of granular and loose materials, consisting of a storage tank, where on one side of the storage tank there is at least one aeration pipe with a branch for connecting a conditioned air unit, with fans, and the other side of the storage tank is permeable to air. The perforation of the aeration pipe is fixed or adjustable by adjustable flaps. A sealing piston, a sealing piston with a sealing tube or sealing shutters connected to a winding device by a rope can be located in the pipe. The heating pipe can be located in the aeration pipe or on its periphery. The solution aims to reduce energy requirements for active ventilation of granular and loose materials.

Description

BACKGROUND OF THE INVENTION The present invention relates to the construction of a container for actively ventilating granular and loose materials consisting of a container, one side of which is air-permeable and the other side of which comprises at least one aeration line.

In the case of accumulators combined in batteries, the ventilation is actively done by sucking or pushing air from the top or bottom of the container. In this way, the stored materials are aerated in the entire poured height. Because active ventilation is used not only to cool the material but also to dry it, the air along a certain path is saturated with moisture, further movement of the material causes unnecessary energy losses and, in addition, the saturated air releases moisture when it exits the grain embankment into a cooler environment. layer of material in the container. Placing the aeration element at half the height of the plug only partially removes the above-mentioned drawbacks, and the construction of such a construction is technically difficult. A calmer existing construction of active ventilation is the use of a central aeration pipe located in a container with a perforated jacket. This solution reduces the aerated embankment depth of the material, but can only be used for small containers due to the complicated design of the aeration duct for larger container heights. In this solution, the containers must be spaced apart to allow air to flow through their housing.

In other designs, aeration pipes are placed on opposite walls of the container, either from the outside or from the inside. This solution achieves uniform active ventilation of the entire grain embankment, but their disadvantage is that it is not possible to increase the volume of blown air here due to the high ventilation resistance of the aeration pipes.

The above-mentioned drawbacks are eliminated by a container for actively ventilating granular and loose materials according to the invention, the principle of which is to place at least one branched aeration pipe on one side of the container and to create an air wall on the other side of the container. The aeration pipe perforation has constant dimensions or is adjustable by means of flaps. A sealing piston, a sealing piston with a sealing tube or sealing blinds connected to the winding device of the rope may be placed in the aeration pipe. The heating and cooling ducts may be located within or around the aeration duct.

By placing the aeration pipe on one wall of the container and creating an air wall, the ventilation resistance is reduced, and more evenly active ventilation of the embankment of granular and loose materials is achieved. By using either a sealing piston, sealing piston and sealing pipe or sealing roller shutter, the material filling in the hopper is actively ventilated at a variable height. The use of heating or cooling tubes utilizes efficient waste heat or cold in active ventilation.

The object of the invention is shown schematically in the accompanying drawings, wherein FIG. 1 is a cross-sectional view of the container at a height in which a perforated aeration line with perforated plates is disposed on one side of the container and an air-permeable wall with perforated plates on the other side of the container; FIG. 2 is a cross-section of FIG. 1 in the position A-A where the square aeration pipe is in the square container and is closed by sealing roller shutters, FIG. 3 is a cross-section of FIG. 1 in position A-A, where the round aeration pipe is in a rounded reservoir and is closed by a sealing piston; Fig. 4 is a sectional view of the container at a height in which the aeration duct of the adjustable flaps is located on one side of the container in which the heating duct is stored, and on the other side of the container is an air wall formed of the adjustable flaps; 5 is a cross-section of FIG. Fig. 4 is a cross-sectional view of Fig. 4 in the position A-A, where the aeration pipe with adjustable flaps and the air wall with adjustable flaps are located in an angular container; 4 in the position A-A where the aeration pipe with adjustable flaps and the air wall are located in the rounded container, fig. Fig. 7 is a sectional view of the container at a height where the perforated aeration line is closed by a sealing cylinder and a sealing piston; Figure 8 is a cross-sectional view of the container where the aeration line is located on the outer periphery of the container; Figure 9 is a cross-sectional view of the container wherein a portion of the aeration line is from an inner wall of the container and a portion from an outer wall of the container; 10 is a side view of a battery of cartridges; FIG. 11 is a cross-sectional view of the cartridge battery in position A-A of FIG. 10 and FIG. 12 is a cross-sectional view of the cartridge battery in position B-B of FIG. 10th

At least one aeration pipe 1 with at least one fan 6 and at least one branch 7 for the connection of the conditioned air aggregate is arranged on the one side of the container. On the aeration line 2 and on the branch 7 there are shut-off flaps 6. The aeration line 2 is in one case formed by a sheet with a constant perforation dimension, whereby the pins 8 have perforated thatch 6 with a smaller perforation dimension. In the second case, the aeration pipe 2 is formed by adjustable slotted flaps 16 around the pins 17. The aeration pipe 2 may be located on the inner wall, the outer wall and the middle of the wall of the container 6. The air wall 3 is in one case formed of a fixed perforated thatch 21, of rotatable perforated plates 23 on the pins 24 and of fixed slotted flaps 22. In the second case, the air wall 6 is formed of adjustable flaps 25 around the pins 26.

In the aeration line 4 there is a sealing piston 60 or a sealing piston 60 and a sealing cylinder 15, or at least one sealing roller 14 connected by a cable to a winding device 11. At least one heating or cooling device may be present in the aeration pipe 2 or at its periphery. pipe 8, provided with heat exchange ribs 19.

An aeration line 34 connected to the aeration line 2 may be located in the hopper 28 of the container. The container is provided with a discharge flap 29 below which the conveyor 40 is located. The reservoir is provided with a level sensor 12 and a temperature and humidity sensor 27 of the material. The cartridges are combined into batteries having a technology tower 31, a stacking conveyor 32, and a discharge carriage 33.

The tank for active ventilation of granular and loose materials works in the following way:

Depending on the granular or bulk material to be stored, it adjusts the size of the openings in the air wall 4 and in the aeration line 2. This can be achieved by tilting or pressing the rotatable perforated plates 9 onto the aeration tube 2, further folding or pressing the rotatable perforated plates 23 onto the air wall. When using the adjustable flaps, the size of the openings in the aeration pipe 6 is adjusted by rotating the adjustable flaps 16 and the size of the openings in the air wall is adjusted by rotating the adjustable flaps 25.

When the material 6 is fed into the container 6, air is blown into the material 6 by the fan 6. In order to prevent air from escaping through the openings in the part of the aeration line 6 not covered by the material 5 by means of the winding device 11, close the aeration line 2 with the sealing piston 10 or sealing roller 14. When the sealing piston 10 or sealing roller 14 is correctly positioned, the air passes from the aeration tube 2 And thence passed through the air wall 6 outside the container 11. When the container 6 is completely filled with material 6, the sealing piston 10 or the sealing roller 14 is positioned in an extreme position where they are out of function. The level sensor 12 and the moisture and temperature sensor 27 of the material 6 serve to control the active ventilation process.

If only a narrow layer of material 6 in the reservoir 11 is required to be active, only the fan 6 in the upper part of the aeration pipe 6 is operated, the air passes through the sealing cylinder 15 and enters the material 4 only through the part of the aeration pipe 6 defined by the lower edge the upper part of the sealing piston 10.

In order to efficiently use waste heat or cold to treat air for active ventilation, the heat or cold carrier passes through the heating or cooling duct 18 located in the aeration duct 6 where the duct 18 is blown with air from ventilator 263361 whereby superheated or cooled air then passes 5 in the reservoir 2 If the air to be treated is actively ventilated by the aggregate, it is connected to the branch 2 with the flaps 6 in front of the fans 4 closed. When the aeration pipe 2 is made of adjustable slotted flaps 16, these can be closed in the prescribed length and air penetrates into the material 5 only through the open slotted flaps 16. When the batteries are formed, the containers 2 face each other through the airtight walls. The conveyor 30 is used ^to unload the material 5 from the containers 2.

Claims (9)

Container for actively ventilating granular and loose materials, characterized in that at least one aeration pipe (2) with at least one fan (4), with at least one branch (7) for connecting the aggregate, is located on one side of the container (1) The air wall (3) is formed to allow air to enter the surrounding space, Container for the active ventilation of granular and loose materials according to claim 1, characterized in that the permeable wall (3) consists of a fixed perforated thatch (21), rotatable perforated plates (23) on the pins (24), fixed slotted flaps (22) and on the aeration line (2) are perforated thatch (9) rotatable about pins (8). Container for the active ventilation of granular and loose materials according to items 1 and 2, characterized in that a sealing piston (10) is connected to the winding device (11) in the aeration line (2). Container for actively ventilating granular and loose materials according to items 1 and 2, characterized in that a sealing tube (15) and a sealing piston (10), which are connected to the winding device (11), are located in the aeration line (2). . Container for actively ventilating granular and loose materials according to items 1 and 2, characterized in that at least one sealing roller (14) connected to the winding device (11) is located on the wall of the aeration pipe (2). Container for actively ventilating granular and bulk materials according to claim 1, characterized in that the aeration pipe (2) is formed by adjustable slotted flaps (16) around the pins (17) and the air wall (3) of the container is formed of adjustable flaps ( 25) around the pins (26). Container for actively ventilating granular and loose materials according to items 1, 2, 5 and 6, characterized in that at least one heating or cooling conduit (18) provided with heat exchange fins (19) is inserted into the aeration line (2). Container for the active ventilation of granular and loose materials according to Claims 1 to 6, characterized in that at least one heating or cooling pipe (18) provided with heat exchange ribs (19) is arranged on the outer wall of the aeration pipe (2). Container for actively ventilating granular and loose materials according to items 1 to 8, characterized in that an air duct (34) is connected to the air duct (2) in the hopper (28) of the container (1).