KR200216327Y1 - A particle mingling system for styrofoam resuscitation - Google Patents

Abstract

The present invention relates to a device for uniformly mixing the newly foamed Styropol cell particles and waste Schiropol to be supplied to the Schiropol molding machine, even if there is a density difference of the cell particles, even if the cell particles are finally uniformly mixed It is intended to be.

Looking at the configuration, and configured a reservoir (1) for storing and storing a large number of cells at the top, and the damper (3) to prevent supply of internal cells to the supply pipe (2) at once and to supply by a predetermined amount after , But the control device 10 for quantitative supply at the lower end of the supply pipe, the control device 10 has an inlet passage 11 in the upper portion and the arc-shaped case (13) connected to the discharge pipe 12 in the lateral direction ) And a trolley 14 having a plurality of wings that rotates in contact with the inner surface of the arc-shaped case 13.

Next, the motor 15 and the reducer 16 are provided and the power is connected to the central axis 17 of the trolley 14 so that the trolley 14 can be rotated, and a mixed brower on one side of the discharge pipe 12 is provided. It is configured by connecting (20).

By using the Schiropol admixture of the present invention, it is possible to form Schiropol products composed of Schiropol cells having different densities. In other words, the densities of Schiropol products can be increased by uniformly mixing cells having different sizes of cell particles. By increasing the strength of the product is effective.

Description

A particle mingling system for styrofoam resuscitation

The present invention relates to a device for uniformly mixing the newly foamed Styropol cell particles and cell particles obtained by crushing the waste Styropol to be supplied to the Styropol molding machine.

As is well known, many studies on the recycling of waste Schiropol have resulted in several developments of devices for obtaining cell particles that can be recycled from the waste Schiropol. However, some technical problems in recycling such recycled cells have been solved. have.

In general, Schiropol manufactures cells by foaming raw materials in the form of particles. In this case, the size of the cell particles is determined according to the degree of foaming, and when foamed with the same raw materials, the particles of the cells become larger and the density of the unit cells is lowered. Will decrease.

On the contrary, when the foam is small, the size of the cell particles is reduced while the density of the unit cell is high, and the weight per unit volume is heavy.

Typically, the conveying of the foamed cell in the manufacturing process of Schiropol is blown out by the broa. At this time, if there is a density difference between the unit cells, the uniform cell distribution is not achieved due to the difference in density of each unit cell when finally put into the molding machine, and the denser cell particles, that is, the small ones, sink down and have a low density. Low cell particles, i.e., large cell sizes, cause the separation phenomenon to rise upwards, resulting in heterogeneous phenomena within the same product, degrading the product's marketability.

This disproportionation is even worse because the particles of the regenerated cells are recovered from various types of waste Schiropol.

Until now, since there is no clear measure to prevent the cell particle from falling out due to the density difference of the cell particles, the mixing ratio of the regenerated cell is set to be extremely low, and the difference in density according to the foaming state of the cell is used. In extreme cases, they cannot be mixed at all.

The present invention devised in view of the above problems is to produce a device that can always be supplied a constant amount of cells, even if there is a difference in density of the cell particles, the purpose is to finally uniformly mix the cell particles.

1 is an overall configuration of the admixture according to the present invention

2 is an enlarged cross-sectional view taken along the line A-A of FIG.

*** Description of the symbols for the main parts of the drawings ***

1: storage 2: supply pipe

3: damper

10: controller 11: inflow passage

12: discharge pipe 13: case

14: cart 15: motor

16: Reducer 17: Center shaft

20: mixed broa 21: motor

22: Fan 23: Case

Looking at a preferred embodiment of the present invention as follows.

A reservoir (1) of a structure suitable for storing and storing a large amount of cells is configured at the top and a damper (3) is formed at the supply pipe (2) below to prevent the internal cells from pouring out at once and to be supplied by a predetermined amount. And again, the control device 10 for quantitative supply was configured below.

Looking at the configuration of the control device 10 in detail, the inlet passage 11 in the upper portion and the discharge tube 12 in the lateral direction constitutes an arc-shaped case 13 connected to the inside of the case (13) After installing the trolley 14 having several wings while rotating in contact with the inner surface of the motor, the motor 15 and the reducer 16 are installed on the side to transfer the power to the central axis 17 of the trolley 14. By connecting, the trolley | bogie 14 is comprised so that rotation may be carried out.

In addition, by connecting the mixing broa (20) to one side of the discharge pipe 12 serves to supply the cell to the molding apparatus as air, the mixing broa (20) is the main power source motor 21, the mixing power and the transfer force It consists of a fan 22 to generate, a case 23 surrounding the outer periphery.

In FIG. 4, reference numeral 4 denotes an input port of a reservoir, and 18 denotes a damper for adjusting the air volume of the broa.

Looking at the operation of the subject innovation in this configuration as follows.

As shown in the figure, a number of cells gathered in the reservoir 1 fall down by a certain amount depending on the degree of opening of the damper 3, and such cells flow back into the control device 10 and the wings of the bogie 14 Each space contains the desired amount of cells.

Since the trolley 14 rotates by the motor 15, the cell contained between the wings of the trolley 14 moves and reaches the portion where the discharge pipe 12 is formed. It is to exit the discharge pipe (12). Therefore, only a certain amount of the supply amount is always supplied by the amount set by the damper 3 and the rotation speed of the trolley 14.

In the supply amount control device 10, several units are installed in parallel at the outlet side of the reservoir 1 so that the mixing ratio of different cells is fixed by adjusting the opening of the damper 3 and the rotation speed of the bogie 14 to adjust the desired mixing ratio. Feed to admixture broa while keeping

The cells supplied at a constant rate from the control device 10 are uniformly mixed while passing through the mixing broa 20 installed at the inlet of the molding machine (not shown). Therefore, it is possible to manufacture products of different cell particle sizes having a uniform distribution even inside the molding machine.

By using the Schiropol admixture of the present invention as described above, it is possible to mold Schiropol products composed of Schiropol cells having different densities. Therefore, it is possible to produce more rigid Schiropol products.

In other words, cells with different sizes of cells can be uniformly mixed, thereby increasing the density of the Schiropol product, thereby increasing the strength of the product.

In addition, the mixing ratio of the regenerated cells can be significantly increased than before, thereby reducing the manufacturing cost of Schiropol products.

It is possible to apply the technical contents of the present invention to other industries to obtain a good effect, for example, to use in the mixing of raw materials of confectionery baking (eg, mixing flour and corn flour, mixing flour and milk powder), composting It can be suitably applied when mixing rice husk and sawdust in manufacturing process and when mixing different kinds of grains in liquor manufacturing.

Claims (2)

In the upper part constitute a storage (1) for storing and storing a large number of cells, The control device 10 for quantitative supply is configured at the lower end of the supply pipe, but the control device 10 has an inlet passage 11 at the upper side and an arc-shaped case 13 in which the discharge pipe 12 is connected to the side. Consists of a bogie 14 having a plurality of wings to rotate in the state in contact with the inner surface of the case 13 in the form of an arc, By installing the motor 15 and the reducer 16 on the side and connecting the power to the central axis 17 of the trolley 14, the trolley 14 is configured to rotate, Particle admixture for Schiropol regeneration, characterized in that by connecting the mixing broa (20) to one side of the discharge pipe (12). The method of claim 1, Schiropol regeneration, characterized in that the supply pipe (2) at the bottom of the reservoir (1) to prevent the internal cells from pouring out at once, and to configure the damper (3) to be supplied by a predetermined amount, and then to the control device (10) thereunder. Particle Admixtures.