KR20120111817A - Shaking table sorter to remove moisture - Google Patents

Abstract

PURPOSE: A vibration separator is provided to improve the separation accuracy of the selected particulate materials by drying water included in the particulate materials. CONSTITUTION: A plurality of selection housing units(10) overlapped in a vertical direction. A punched plate(30) and a screen(20) are inserted between the housing units. Particulate materials are separately selected to a discharge unit(11) according to the particle size of the particulate materials using the vibration of a vibrator(50). The particulate material is dried through the high temperature pressure space. The pressure space includes a partition wall. The partition wall is formed in the inside cylindrical body of the selection housing unit.

Description

Shaking table sorter to remove moisture

The present invention relates to a vibrating separator for screening powders including non-ferrous powders of chemicals, foods or pharmaceuticals, and also removing moisture contained in the powders during the screening process. In particular, a partition wall is formed inside the plurality of sorting housings stacked on the upper end of the vibrator, and the moisture is dried in the process of sorting powder through vibration by supplying air or fluid of high temperature and high pressure to the partition wall, Powders that are easy to be stacked on top of the sorting plate formed inside the sorting housing are related to a vibrating sorter for sorting and removing moisture to blow out the pneumatic powder to enable clean sorting at all times.

In general, the vibrating separator used in the sorting operation for sorting the powder, including non-ferrous powder by size in chemistry, food and medicine ceramics, etc., as shown in Figs. A vibrator 20 connected to the vibrating case 10, a screen 30 installed inside the vibrating case 10, a perforated plate 40 disposed on a lower surface of the screen 30, and It is composed of a plurality of tapping ball 50 disposed between the perforated plate 40 and the screen 30.

The vibrating case 10 is formed of a cylindrical shape that is long in the vertical direction, and is manufactured by stacking a plurality of short pipes 11 having a short length in the vertical direction. At this time, the inlet 12 is formed on the upper surface of the vibration case 10, the discharge port 13 for discharging the powder selected by the screen 30 is formed on the peripheral surface of each of the rough (11).

The screen 30 is composed of a plurality of each is installed between the rough 11 so as to be spaced apart from each other in the vertical direction, the lower screen 30 so that the eyes are smaller than the screen 30 disposed on the upper side It is composed.

The perforated plate 40 has a plurality of through-holes 41 penetrating the upper and lower surfaces is fixed to the vibrating case 10 to be located below the screen 30, the tapping ball 50 is made of silicon When the vibration case 10 and the perforated plate 40 is vibrated, the upper surface of the screen 30 is bumped up and collided with the lower surface of the screen 30 to prevent powder from being caught in the screen 30.

Therefore, while vibrating the vibrating case 10 with the vibrator 20, when the powder is introduced into the inlet 12, the injected powder sequentially passes through the screen 30 of the stage and falls downward to form a screen 30. After sorting according to the size of the eyes of the) through the outlet 13 formed in each of the rough (11) is discharged to the outside of the vibration case (10). In addition, the tapping ball 50 continuously bounces off the screen 30 to prevent powder from getting caught in the eyes of the screen 30 and to block the eyes of the screen 30. Irregular vibrations are applied to allow the powder to pass through the screen 30 more quickly.

However, the conventional sorting device has the following problems.

First, a powder containing a non-ferrous powder contains a large amount of water, there is a problem that such water is selected in a state containing more water, depending on the location of the location of the sorting device.

If the water is contained in the vibration sorting device is selected, it is also possible to sort by the particle size of the powder. If the small particles are entangled with each other through moisture, even if the small powder is a problem that is selected as a large powder.

Second, at the top of the sorting plate formed in the bottom sorting housing, a plurality of powders are entangled and stacked on top of each other without being sorted. As a result, accurate screening is not achieved.

The present invention relates to a vibrating separator for screening powders including non-ferrous powders of chemicals, foods or pharmaceuticals, and also removing moisture contained in the powders during the screening process. In particular, a partition wall is formed inside the plurality of sorting housings stacked on the upper end of the vibrator, and the moisture is dried in the process of sorting powder through vibration by supplying air or fluid of high temperature and high pressure to the partition wall, Powders that are easy to be stacked on top of the sorting plate formed inside the sorting housing are related to a vibrating sorter for sorting and removing moisture to blow out the pneumatic powder to enable clean sorting at all times.

Vibration sorter for sorting the powder and removing water according to the present invention, the sorting housing having a cylindrical body 18, and the discharge portion (11) protruding to one side to discharge the sorted powder according to the size ( 10); A pressure space (16) formed through a partition wall (14) formed at regular intervals inside the cylindrical body (18) of the sorting housing (10), which is an outer circumferential surface; Vibrator 50 for generating a vibration at the bottom of the multi-stage sorting housing 10; And inside the bottom of the sorting housing 10 to which the vibrator 50 is fixed, formed in the horizontal direction on the inner circumferential surface of the body 18 of the sorting housing 10, the center of the body 18 is high and the housing 10 A) a convex sorting plate 17 integrated so that the level of the inner peripheral surface portion of the body 18 is low, wherein the sorting housing 10 is formed in a plurality of stages overlapping each other in a vertical direction, and between the housings The perforated plate 30 and the screen 20 are sandwiched and separated into the respective discharge parts 11 according to the particle size of the powder through vibration, thereby achieving drying through a high pressure space.

In addition, according to the vibration separator for screening the powder of the present invention and removing the water, a plurality of supply nipples 12 are fastened to the pressure space 16 at regular intervals on the outer peripheral surface of the body 18 of the sorting housing 10, In the partition 14, a plurality of blow holes 15 are formed, and high temperature and high pressure air is blown through the air supplied from the high pressure supply nipple 12 into the blow holes 15 to sort and dry the powder, respectively: Combination of the compressor 81 and the heat exchanger 82 connected to the supply line (H) to the supply nipple (12) of: fastening a plurality of nipples at regular intervals on the outer peripheral surface of the body 18 of the sorting housing 10 However, the supply nipple 12 and the discharge nipple 19 are alternately installed, and a recycle structure for supplying a high temperature and high pressure fluid to the pressure space 16 through the supply nipple 12 to exhaust the discharge nipple 19. Equipped.

In addition, according to the vibration separator for screening the powder of the present invention and removing water, each supply nipple 12 is connected to a supply line (H), but the hydraulic tank 85, hydraulic pump 86 and heat exchanger 87 Communicating a hydraulic system consisting of; Each discharge nipple 19 connects a discharge line 88 to return the fluid discharged from the pressure space 16 to the hydraulic tank 85: the sorting plate 17 installed in the lowermost sorting housing 10. To the level of the convex center portion of the blower hole 15 formed in the partition 14, the level of the lowest row of air blown from the blower hole 15, the powder accumulated on the top of the sorting housing (10) Whisk

According to the present invention, there is an advantage that the sorting accuracy of the powders selected for drying the moisture contained in the powder in the process of selecting the powder is high.

In addition, according to the present invention, to form a separate pressure space inside the sorting housing, and to further activate the vibration of the powder through the high-temperature, high-pressure air ejected from the pressure space, and to completely dry the inside of the powder This has the advantage that the screening accuracy and speed is fast.

In addition, according to the present invention, the pneumatic pressure is ejected from the ejection hole is injected to the top of the sorting plate formed in the bottom sorting housing, there is an advantage to minimize the powder laminated on the top of the sorting plate.

1 is a view showing the entire vibrator of the prior art,
2 is a view showing a perforated plate and a screen accommodated inside the conventional vibrator,
Figure 3 is a view showing the vibration separator as a whole of the present invention,
Figure 4 is a view showing a perforated plate and the screen accommodated inside the sorter of the present invention,
5 is a plan view of the sorting housing of the present invention;
6 is a side view of the sorting housing of the present invention;
7 is a view showing the inside of the bottom of the sorting housing of the sorting housing of the present invention,
8 is a view showing an embodiment of a sorting housing equipped with a hydraulic system of the sorting housing of the present invention,
9 is a view showing an embodiment of a pressure space using the pneumatic pressure of the sorting housing of the present invention,
10 is a view showing a state of the housing in communication with the hydraulic system of the sorting housing of the present invention.

The present invention relates to a vibration screening device for screening powders containing various non-ferrous powders by size.

Therefore, the configuration and operation of the present invention will be described in detail with reference to FIGS. 3 to 10.

As shown, there is a sorting housing 10 having a cylindrical body 18 and a discharge part 11 which protrudes to one side and discharges the sorted powder according to the size, wherein the sorting housing is an outer peripheral surface ( There is a pressure space 16 formed through the partition wall 14 formed at regular intervals inside the cylindrical body 18 of 10), the vibrator 50 to generate a vibration at the bottom of the multi-stage sorting housing 10 There is. In addition, the inner side of the bottom of the sorting housing 10 to which the vibrator 50 is fixed, is formed in the horizontal direction on the inner peripheral surface of the body 18 of the sorting housing 10, the center of the body 18 is high and the housing 10 There is a convex sorting plate 17 integrated so that the level of the inner peripheral surface portion of the body 18 is low. Therefore, the combination housing 10 is formed in a plurality of stages are stacked in a plurality of vertically overlapping each other, and the perforated plate 30 and the screen 20 is sandwiched between the housing, depending on the particle size of the powder through vibration While being sorted by the outlet portion 11, the drying through the high pressure space is to achieve.

That is, the present invention consists of a plurality of sorting housing 10 is vertically coupled in multiple stages. When the raw material inlet is formed at the upper end of the sorting housing 10 located at the top, and the powder, which is a raw material, is injected into the inlet, the raw material is gradually lowered to the lower part to sort out the small powder. 3 and 4, the sorting screen 20 and the perforated plate 30 is inserted into the lower end of the sorting housing 10 of the uppermost stage, the next sorting housing 10 is located. The present invention is manufactured by being formed in multiple stages with the same structure. Although FIG. 3 shows a sorting apparatus having a four-stage configuration, the number of stages may be increased, but may be formed in a smaller stage.

And the vibrator 50 is fixed to the lower end of the sorting housing 10, as shown, the powder is more easily sorted through the vibration generated by the vibrator (50). The powders of various sizes introduced into the inlet are first filtered through the screen 20 at the bottom through strong vibration when placed in the sorting housing 10 at the top, and the perforated plate 30 at the bottom thereof through the screen 20. Pass through) to the next stage of sorting housing (10). Of course, the air gap of the screen 20 is inserted into a smaller form toward the sorting housing 10 at the bottom, so that the powder filtered from the discharge part 11 of the sorting housing 10 of the uppermost stage is most It becomes a coarse particle. In addition, the tapping ball 33 shown in FIG. 4 bounces upward when the vibrator 50 transmits vibration, and generates frequent friction with the screening screen 20 at the top, thereby causing the powder to be caught on the screen 20. At the same time, while discharging the particles into the discharge unit 11, the small particles are moved to the lower sorting housing 10 at the lower perforated plate 30.

At this time, the present invention plays a very important role. In other words, the moisture is also dried in the process of sorting the powder by size to be more accurate selection. To explain the operation of the drying, the sorting housing 10 of the present invention is formed in multiple stages as shown in FIG. And only the inside of the sorting housing 10 at the bottom of the multi-stage sorting housing 10 is slightly different form. The upper sorting housing 10 discharges the sorted powder to the discharge part 11, and compared to the sorted powder, small particles of powder must be moved to the lower sorting housing 10, as shown in FIG. Perfectly penetrated up and down. However, if the sorting housing 10 at the bottom is penetrated up and down, the sorting plate 17 blocking the vertical direction is formed integrally because small particles fall into the vibrator 50 at the bottom. That is, as shown in FIGS. 3 and 7 to form a sorting plate 17 integrally on the inner peripheral surface to block the movement in the vertical direction.

In addition, all of the sorting housings 10 are formed with a partition wall 14 formed at regular intervals on the inner circumferential surface thereof, and a pressure space 16 between the outer body 18 and the partition wall 14 of the sorting housing 10. To form. The pressure space 16 is a method of filling or supplying hot air or a fluid, thereby drying the moisture contained in the powder to be selected by increasing the temperature. Through this action, the sorting device of the present invention can sort the powder by size more stably.

Then look at the more detailed configuration and operation of the sorting device of the present invention.

In the present invention, a plurality of supply nipples 12 are fastened to the pressure space 16 at regular intervals on the outer circumferential surface of the body 18 of the sorting housing 10, and a plurality of ejection holes 15 are provided in the partition wall 14. To form a high-temperature, high-pressure air is blown through the air supplied from the high-pressure supply nipple 12 to the blowing hole 15 to sort and dry the powder.

That is, this embodiment is an embodiment in which the supply nipple 12 is fastened to the outer body 18 forming the pressure space 16, and the air of the pneumatic pressure can be introduced. This embodiment is illustrated in Figure 5. In the case of the sorting housing 10 in which the upper housing as well as the sorting plate 17 at the bottom are integrated, the same is formed. Although the drawings show an embodiment in which three nipples are fastened, the present invention is not limited thereto and may be more or less. When the high-temperature, high-pressure air is blown into the supply nipple 12, the high-temperature, high-pressure air is blown out to the discharge hole 15 of the partition 14, which is the inner circumferential surface of the sorting housing 10, and the powder is sorted to dry. Let's go. Of course, when the high-temperature, high-pressure air is blown into the pressure space 16, the partition wall 14 increases the temperature to dry the surrounding moisture and also serves to dry the moisture of the powder.

Each of the supply nipples 12 is used by combining the compressor 81 and the heat exchanger 82 which are connected to the supply line (H). That is, the reason why the supply nipple 12 is fastened is for blowing high pressure air. In addition, the present invention is to blow the high-temperature air, so that it can be dried in the selection process of the powder. A hose is connected to the nipple, and a compressor 81 and a heat exchanger 82 are connected to the hose to blow air at high pressure while changing the state of the air to raise the temperature. The high-pressure, high-pressure air passing through the state of the high temperature through the heat exchanger 82 is blown into the discharge hole 15 of the partition 14 while achieving the formation of the moving power of the fluid through the compressor 81 and the high pressure. To solve this problem, more vibration is generated in the powder to facilitate sorting, and the moisture inside the powder is dried to become entangled.

In addition, the present invention can also be used to increase the temperature of the inner circumferential surface of the sorting housing 10 by using a liquid in the fluid and to dry the moisture inside the powder using this temperature. This embodiment is shown in detail in FIGS. 8 and 10. In this embodiment, a plurality of nipples are fastened at regular intervals to the outer circumferential surface of the body 18 of the sorting housing 10, and the supply nipples 12 and the discharge nipples 19 are alternately installed, and the supply nipples ( 12) has a recycle structure for supplying a high temperature and high pressure fluid to the pressure space 16 through the exhaust nipple (19).

Due to the recycling characteristics of the fluid, the supply nipple 12 and the discharge nipple 19 are alternately formed because the supplied fluid must be recycled. The supply nipple 19 injects a high temperature fluid into the pressure space 16 and discharges it by the amount supplied to the discharge nipple 19 to recirculate it.

More specifically, each supply nipple 12 is connected to the supply line (H), but the hydraulic system consisting of the hydraulic tank 85, the hydraulic pump 86 and the heat exchanger 87 is communicated, each discharge nipple At 19, the discharge line 88 is connected to return the fluid discharged from the pressure space 16 to the hydraulic tank 85. The hydraulic tank 85, the hydraulic pump 86, the heat exchanger 87 is connected to the supply line (H) to supply the fluid in the hydraulic tank 85 to the hydraulic pump 86. At this time, the fluid rises the temperature of the fluid through the heat exchanger 87 before entering the supply nipple 12 to enter the pressure space 16 inside the partition 14 to dry the moisture of the powder as a high temperature fluid. . Of course, the fluid entering through the supply line (H) has to be discharged by the same amount in order to raise the temperature inside the housing through continuous supply, so that the discharge nipple (19) corresponding to the supply nipple (12) It was formed alternately.

The discharge nipple 19 also forms a separate discharge line 88 as shown in FIG. 10, and the discharge line 88 is connected to the hydraulic tank 85 again to move the fluid.

Unexplained symbol "B" is a bending portion bent the end of the flange in order to ensure that the sorting screen 20 and the perforated plate 30 is sandwiched between the sorting housing to ensure and maintain a more stable position during vibration.

Finally, a more detailed configuration of the sorting plate described in the present invention will be described. As shown in FIG. 7, in the present invention, the level of the convex center portion of the sorting plate 17 installed in the bottom sorting housing 10 and the bottom row among the rows of the ejection holes 15 formed in the partition wall 14. At the level, the air emitted from the ejection hole 15 shakes off the powder accumulated on the top of the sorting housing 10.

A plurality of blow holes 15 formed in the partition wall 14 are formed by turning on the inner circumferential surface, and are formed in multiple rows. It is preferable that the level of the blowing hole 15 formed in at least the lowest row among the blower holes 15 of this multi-row is formed in accordance with the level of the uppermost part of the sorting plate 17, ie, the convex part. The small powder that will be most accumulated in the convex portion is not considered to be easily removed because it is not easy to remove through the pneumatic pressure emitted from the ejection hole 15 to discharge to the discharge portion (11).

10; Selective housing 11; The discharge portion
12; Supply nipple 14; septum
16; Pressure space 17; Sorting Plate
18; Body 20; Screening screen
30; Perforated plate 81; Compressor
82; Heat exchanger 85; Hydraulic tank
86; Hydraulic pump 87; heat transmitter
H; Supply line

Claims (6)

A sorting housing 10 having a cylindrical body 18 and a discharge part 11 protruding to one side and discharging the sorted powder according to the size;
A pressure space (16) formed through a partition wall (14) formed at regular intervals inside the cylindrical body (18) of the sorting housing (10), which is an outer circumferential surface;
Vibrator 50 for generating a vibration at the bottom of the multi-stage sorting housing 10; And
Inside the bottom sorting housing 10 to which the vibrator 50 is fixed, a horizontal direction is formed on the inner circumferential surface of the body 18 of the sorting housing 10, and the center of the body 18 is high and the housing 10 is formed. Convex sorting plate 17 is integrated so that the level of the inner peripheral surface portion of the body 18 is low, wherein the sorting housing 10 is formed in a plurality of stages overlapping each other in the vertical direction, perforated between the housing The plate 30 and the screen 20 are sandwiched and separated into the respective discharge parts 11 according to the particle size of the powder through vibration, and the powder is characterized in that it achieves drying through a high pressure space. Vibrating separator to remove moisture.
The method of claim 1,
In the pressure space 16,
A plurality of supply nipples 12 are fastened at regular intervals to the outer circumferential surface of the body 18 of the sorting housing 10, and a plurality of ejection holes 15 are formed in the partition wall 14 to provide a high pressure supply nipple 12. Vibration sorter for sorting the powder and removing the water, characterized in that the high-temperature, high-pressure air is blown through the air supplied to the blowing hole 15 to sort and dry the powder.
The method of claim 2,
Each supply nipple (12) is a vibrating separator for sorting the powder and removing water, characterized in that for coupling the compressor (81) and the heat exchanger (82) connected to the supply line (H).
The method of claim 1,
A plurality of nipples are fastened at regular intervals to the outer circumferential surface of the body 18 of the sorting housing 10, and the supply nipples 12 and the discharge nipples 19 are alternately installed, and a pressure space is provided through the supply nipples 12. A vibrating separator for separating powder and removing water, characterized by having a recycle structure for supplying a fluid at high temperature and high pressure to the exhaust nipple (16).
The method of claim 4, wherein
Each supply nipple 12 connects a supply line H to communicate with a hydraulic system consisting of a hydraulic tank 85, a hydraulic pump 86 and a heat exchanger 87;
Each discharge nipple (19) is connected to the discharge line (88) to sieve the fluid discharged from the pressure space (16) to the hydraulic tank (85) for selecting the powder and removing the vibration separator.
The method of claim 2,
Fire at the spout hole 15 by matching the level of the convex center portion of the sorting plate 17 installed in the bottom sorting housing 10 with the level of the lowest row among the rows of the spout holes 15 formed in the partition wall 14. Vibration sorter for sorting the powder and removing water, characterized in that the air is shaken the powder accumulated on the top of the sorting housing (10).

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