KR101949011B1 - Quantitative Discharge Apparatus for Preventing from Bridging Phenomenon - Google Patents

Abstract

The present invention provides a fixed amount discharging device for preventing bridging phenomenon, comprising: a silo main body (10) having a discharge port (11) at the lower end of which a powder is stored; A conical portion 20 installed at the center of the lower end of the silo main body 10 and having a predetermined height and having a larger diameter as it goes downward to be guided outward by the powder stored in the silo main body 10 by rotation; A cylindrical portion 30 on which the conical portion 20 is fixed; The dust collecting body is horizontally protruded and fixed to the outer circumference of the cylindrical portion 30, and the powdered powder stored in the silo body 10 is crushed and guided to the discharge port 11, A blade 40 provided; Rotating means 50 installed at a lower outer side of the silo main body 10 and coupled to the cylindrical portion 30 to rotate the cylindrical portion 30; And a transfer discharge unit 60 for transferring and discharging the powder discharged to the discharge port 11.

Description

[0001] The present invention relates to a quantitative discharge apparatus for preventing bridging phenomenon,

The present invention relates to a quantitative discharge device for preventing bridging phenomenon, which prevents a bridging phenomenon that does not fall down to a bottom due to a dome-shaped cavity formed in discharging the powder contained in a silo.

The purpose of the general construction of the silo is to make a mass storage, and it is formed differently according to the use, but its appearance is formed in a similar shape. There may be a case where a large-sized cylinder is formed and a lower portion thereof is conically formed.

These silos are used in a wide variety of industrial facilities handling powder. Cement manufacturing process, grain storage facility, BIOMASS (agriculture and forestry product, energy crop, organic waste) storage facility, and sinter ore storage facility of steel mill.

A discharge device for discharging the powdered material is provided in the lower part of the silo. The discharge device is provided in various forms according to the discharge method. The rotary type in which the rotating shaft equipped with the blades is rotated, and the lower part of the powdered material stored in the silo by the blades is pulverized and discharged to the outside is the most used.

Korean Patent No. 10-1347221 (the name of the invention: a silo having a scum discharging blade) has been disclosed as an example of a rotary discharge device used in a silo, which is shown in FIG.

A silo for storing contaminants and discharging the contaminants through an outlet at a lower end thereof, the contaminant storage tank (110) having a storage space for storing contaminants therein; An auger screw means (120) for transferring contaminants accumulated in the inside of the bottom of the impurity storage tank to the center of the bottom, and an agitator means (120) rotatably installed in the bottom of the impurity storage tank for discharging the contaminants accumulated thereon, The discharge blade means being provided at an end of the discharge blade means and being rotatable by the drive motor 140. The rotary shaft means provided at the center of the bottom of the impurity storage tank 150) formed on the lower side of the obstacle storage tank And a discharge port (160) for discharging the material to the outside, wherein the impeller storage tank is provided at its lower end with a power transmitting portion for transmitting the driving force of the driving motor The sludge introduced into the rotating bearing installed in the rotating shaft means is removed from the driving unit mounting passage to prevent the rotating force from being lowered. A cleaning air line for supplying air pressure by the compressor 180 is further provided.

The silo is rotated by the rotation of the driving motor 140 to rotate the rotary shaft means 150 and rotate the discharge blade means 130 provided on the rotary shaft means 150 to remove the contaminants stored in the impurity storage tank 110 The sludge is discharged.

When the silo is applied to the powder discharge, the rotation shaft means 150 is rotated by the rotation of the driving motor 140, and the discharge blade means 130 provided on the rotation shaft means 150 rotates the powder- There is a problem that a bridging phenomenon occurs in which a dome-shaped cavity is formed in the upper part of the discharge blade means 130 and falls down to the lower part. .

In order to prevent such a bridging phenomenon, a vibration device is used to apply an impact from the outside of the silo, or to generate vibrations in the silo as shown in FIG. 2 to cause the powder to fall down. Alternatively, A method of inducing a falling of the powdered material by rotating the powdered material is used.

However, these methods are not a fundamental countermeasure for bridging phenomenon. When bridging phenomenon occurs, a large amount of the powder is dropped when the powder is dropped downward, so that it is difficult to discharge a fixed amount.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a constant amount discharge device for bridging phenomenon which prevents a bridging phenomenon that a dome- .

It is another object of the present invention to provide a constant amount discharge device for preventing bridging phenomenon, which is caused to be discharged while performing crushing of the powder.

In order to accomplish the above object, the present invention provides a fixed amount discharging device for preventing bridging phenomenon, comprising: a silo main body (10) storing powdered material and having a discharge port (11) at a lower end; A conical portion 20 installed at the center of the lower end of the silo main body 10 and having a predetermined height and having a larger diameter as it goes downward to be guided outward by the powder stored in the silo main body 10 by rotation; A cylindrical portion 30 on which the conical portion 20 is fixed; The dust collecting body is horizontally protruded and fixed to the outer circumference of the cylindrical portion 30, and the powdered powder stored in the silo body 10 is crushed and guided to the discharge port 11, A blade 40 provided; Rotating means 50 installed at a lower outer side of the silo main body 10 and coupled to the cylindrical portion 30 to rotate the cylindrical portion 30; And a transfer discharge unit 60 for transferring and discharging the powder discharged to the discharge port 11.

In addition, a spiral blade 21 is formed at an outer periphery of the conical portion 20 so as to be inclined.

Further, each of the blades (40) has a different installation height.

The discharge port 11 is provided in a rectangular shape on the outer side of the cylindrical portion 30 and symmetrically symmetrical about the cylindrical portion 30, And is conveyed by the rotation of a rotary shaft 62 provided with a screw 61 on the outer periphery of the screw 61. The screw 61 is spaced apart from the powder particle inlet side toward the discharge side, .

According to the present invention, there is provided a constant amount discharging device for preventing bridging phenomenon according to the present invention, in which the conical portion 20 is rotated with a predetermined height, so that a bridging phenomenon occurs, It can be efficiently prevented. In addition, since the spiral blade 21 is provided in the conical part 20, the powder stored in the silo body 10 is excavated, thereby bridging phenomenon can be prevented remarkably. Further, by making the installation height of each of the blades 40 different, it is possible to efficiently perform the crushing of the powder compact by the rotation of the blade 40, and to control the discharge of the powder compact falling from the upper part to the lower part .

1 to 3 are diagrams showing a conventional quantitative discharge device for preventing bridging phenomenon.
4 and 5 are a front view and a side view showing the internal structure of the metering device for preventing bridging of the present invention.
Fig. 6 is a view showing a main part of a metered dose discharging device for preventing bridging of the present invention.
Fig. 7 is a plan view of the metered dose discharging device for preventing bridging of the present invention. Fig.
8 is a plan view showing a conical part and a blade structure of the constant-quantity discharging device for preventing bridging of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

4 and 5 are a front view and a side view showing the internal structure of the quantitative discharge device for preventing bridging phenomenon according to the present invention. FIG. 6 is a view showing a main part of the bridging- Fig. 8 is a plan view showing a bristle portion and a blade structure of a metering device for preventing bridging of the present invention. Fig.

As shown in the drawing, the constant-quantity discharging device 100 for preventing bridging phenomenon according to the present invention comprises a silo body 10; A conical portion 20; A cylindrical portion 30; A blade 40; Rotating means (50); And a conveying and discharging part (60).

The silo main body 10 is known to store the powder and has a discharge port 11 at the lower end thereof.

4 and 5, the conical portion 20 is installed at the center of the lower end of the silo main body 10 and has a predetermined height. The diameter of the conical portion 20 increases toward the bottom so as to induce the powder compacts stored in the silo main body 10 to the outside by rotation.

The conical portion (20) is fixed to the upper portion of the cylindrical portion (30).

4 and 5, the blade 40 is fixed to the outer periphery of the cylindrical portion 30 so as to protrude horizontally, and the powdered powder stored in the silo body 10 is crushed to form the discharge port 11, .

The number of the blades 40 is two to four and is radially provided so as to form the same angle (see FIGS. 7 and 8). In the drawing, two blades 40 are shown. When the blade 40 is fixed to be protruded horizontally to the outer periphery of the cylindrical portion 30, the fixing portion of the blade 40 is preferably formed in a flange shape and bolted to the cylindrical portion 30 .

4 to 6, the rotating unit 50 is installed on the lower outer side of the silo body 10 and is coupled to the cylindrical unit 30 to rotate the cylindrical unit 30. [ The rotating means 50 adopts a known structure for rotating by the rotation of the rotating shaft.

The feed / discharge unit 60 serves to feed and discharge the powder discharged to the discharge port 11.

As described above, according to the present invention, since the conical portion 20 rotates with a predetermined height, the bridging body can be effectively prevented from falling due to the bridging phenomenon that the dome-shaped cavity is generated.

In this case, it is preferable that the spiral blade 21 is additionally provided to more effectively prevent bridging due to rotation of the conical portion 20 (see Figs. 4 to 8).

The spiral blade 21 is inclined from the upper part to the lower part on the outer circumference of the conical part 20, and is formed into a spiral shape. When the conical portion 20 is rotated, the powder stored in the silo main body 10 is excavated by the helical blade 21, so that the bridging phenomenon can be prevented remarkably.

When the powder stored in the silo main body 10 falls down to the bottom due to the rotation of the conic section 20, the powder is crushed by the rotation of the blade 40. In order to efficiently perform the crushing of the powder, It is preferable that the blades 40 have different installation heights (see Figs. 4 and 5).

When the installation height of the blades 40 is different from each other, the blades 40 located at the upper part and the blades 40 located at the lower part rotate efficiently, It also functions to adjust the discharge amount of the powder that has fallen to the bottom.

The discharge port 11 is formed in a shape of two rectangles on the outside of the cylindrical portion 30 and eccentric from the center of the cylindrical portion 30 so as to be parallel to each other and symmetrical with respect to the cylindrical portion 30 do. When the discharge ports 11 are provided symmetrically with respect to each other, the amount of discharge can be increased. When the powder is guided to the discharge port 11 by the rotation of the blade 40, do.

The conveying and discharging part 60 is provided so as to be the same as the longitudinal direction of each of the discharge ports 11 and is transported and discharged by the rotation of the rotating shaft 62 provided with the screw 61 on the outer peripheral edge.

At this time, it is preferable that the distance between the screw 61 and the discharge side increases gradually from the powder inflow side to the discharge side. It is preferable that the distance between the screw 61 and the discharge side is gradually increased from the powder inflow side to the discharge side (see FIGS. 5 and 7).

The screw 61 can be discharged in a fixed amount by discharging the particulate matter while keeping the amount of the particulate matter constant even if a large amount of the particulate matter is dropped as the distance between the particulate matter inlet side and the exhaust side increases.

The fixing part of the blade 40 is provided in a flange shape and is bolted to the cylindrical part 30. The cylindrical part 30 is fixed to the blade 40 to adjust the fixing height of the blade 40. [ A plurality of fasteners (not shown) for fixing bolts are provided at predetermined intervals in the vertical direction.

A plurality of fasteners (not shown) for fixing the blades 40 to the bolts 40 are provided at predetermined intervals in the vertical direction. Thus, the blades 40 can be rotated in accordance with the cohesive force, moisture content, So as to facilitate the crushing of the powder compact.

The technical idea should not be interpreted as being limited to the above-described embodiment of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, such modifications and changes are within the scope of protection of the present invention as long as it is obvious to those skilled in the art.

10: Silo body
11: Outlet
20:
21: Spiral blade
30:
40: blade
50: rotating means
60:
61: Screw
62:

Claims (4)

delete delete delete A silo body (10) storing the powder and having an outlet (11) at the bottom;
A conical portion 20 installed at the center of the lower end of the silo main body 10 and having a predetermined height and having a larger diameter as it goes downward to be guided outward by the powder stored in the silo main body 10 by rotation;
A cylindrical portion 30 on which the conical portion 20 is fixed;
The dust collecting body is horizontally protruded and fixed to the outer circumference of the cylindrical portion 30, and the powdered powder stored in the silo body 10 is crushed and guided to the discharge port 11, A blade 40 provided;
Rotating means 50 installed at a lower outer side of the silo main body 10 and coupled to the cylindrical portion 30 to rotate the cylindrical portion 30;
And a transfer discharge unit 60 for transferring and discharging the powder discharged to the discharge port 11,
A spiral blade (21) is formed at an outer periphery of the conical portion (20) so as to be inclined from an upper portion to a lower portion. The helical blade (21)
Each of the blades (40) has different installation heights,
The discharge port 11 is formed in a shape of two rectangles on the outside of the cylindrical portion 30 and eccentric from the center of the cylindrical portion 30 so as to be parallel to each other and symmetrical with respect to the cylindrical portion 30 And,
The conveying and discharging part 60 is provided so as to be the same as the longitudinal direction of each of the discharge openings 11 and is transported and discharged by the rotation of the rotating shaft 62 provided with the screw 61 on the outer peripheral edge,
The spacing between the screw 61 and the discharge side increases gradually from the powder inflow side to the discharge side,
When the blade 40 is fixed so as to protrude horizontally from the outer periphery of the cylindrical portion 30, the fixing portion of the blade 40 is formed in a flange shape and is bolted to the cylindrical portion 30,
Wherein a plurality of fasteners for fixing the blades (40) to the bolts (40) are provided in the cylindrical portion (30) at predetermined intervals in the vertical direction to adjust the fixing height of the blades (40) Quantity discharge device.

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