KR20030011110A - Apparatus for collecting small steel partical for shot blacting - Google Patents

Abstract

PURPOSE: A recovering device of forced element particles for a short blasting is provided to simplify the structure and to reduce the production cost by using an air rocket nozzle having a venturi nozzle as a suction force generator. CONSTITUTION: An extended diameter portion having a suction pipe portion is connected with a secondary suction pipe(21). A shrunken diameter pipe is integrally connected with the lower part of the extended diameter portion. An air supply pipe(18) to be connected with an air supply line(22) of a compressor is inserted into the extended diameter portion. An air rocket nozzle(13) to be connected with a venturi nozzle(19) downward is connected with the end of the air supply pipe. Thereby, the structure is simplified.

Description

Apparatus for collecting small steel partical for shot blacting}

The present invention relates to an apparatus for recovering forced elementary particles for shot blasting, and more particularly, to a forced elementary particle (shot) generated during a shot blasting operation and a suction force generator for generating a suction force to suck a scale, having a venturi nozzle. By installing the air rocket nozzle, when the compressed air is rapidly injected through the venturi nozzle, the pressure on the front side of the venturi nozzle is lowered and the pressure on the rear side increases the suction force on the rear side of the venturi nozzle. Forced elementary particles and scales generated during work can be sucked out and discharged to reduce the production cost while simplifying the structure than the conventional forced elementary particle recovery device for shot blasting using the Lutz blower.

In general, a shot blast is a shot or steel plate formed by spraying steel particles such as grit or shot ball or small particles such as sand on the surface of the steel sheet. It refers to the work to remove, it is widely used as a pre-work on the parts that need to remove rust or paint when drying the ship.

After performing the shot blasting as described above, the grit or the shotball (hereinafter referred to as the forced elementary particle) is accumulated on the work site together with the scale, and after the shot blasting work, the forced elementary particles and the scale that are accumulated on the work site are collected and forced. Particles are used for recycling and the scale is disposed of.

An example of such a shot blasting operation is that when the shot blasting operation is performed in the deep inside of the ship 1 as shown in FIG. 1, the forced elementary particles and the scale are accumulated at the work site. In order to collect the accumulated forced elementary particles and scale (hereinafter referred to as short blast residue short blast residue (2)), the forced particle recovery device (3) is placed on the upper part of the vessel (1) and then forced particle recovery device (3). The long suction hose (4) connected to the bottom of the ship (1) down the inside of the ship (1) and brings the end of the suction hose (4) to the stacked short blast residue (2).

Then, when the forced particle recovery device 3 is operated to generate a suction force, the shot blast residue 2 accumulated on the bottom of the ship 1 is sucked up by a suction force of the forced particle recovery device 3 such as a large vacuum cleaner. It is sucked through the hose (4) and is accumulated in the interior of the forced elementary particle recovery device (3), inside the forced elementary particle recovery device (3) is separated separately from the forced elementary particle and scale from the shot blast residue (2), forced elementary particles Is used for recycling and the scale is disposed of.

As described above, the conventional short blast forced particle recovery device used to collect the shot blast residue 2 accumulated in the deep inside of the ship 1, the shot blast residue accumulated in the interior of the ship ( 2) the collection tank 7 which collects and stores the forced small particles 5 which are heavier than a scale such as dust and sends the light scale 6 to the cyclone 8, and the scale transferred from the collection tank 7 ( 6) Cyclone 8 for collecting coarse dust particles, a filter 9 is provided inside the dust collector 10 for collecting small dust passing through the cyclone 8, and the power of the motor 11 is transmitted. It is driven by receiving is made of a roots blower 12 is connected to the discharge pipe side of the dust collector 10 to generate a suction force.

Such conventional shot blasting device for shot blasting is generated by the roots blower (12) to generate the suction force for sucking the shot blast residue (2), the roots blower (12) is expensive and the roots blower ( In order to drive 12), a control device for controlling the motor 11, the motor 11, and the Roots blower 12 is inevitably required, and the product price of the shot blasting device for recovering forced elementary particles is significantly increased. It has a problem that the volume of the blasting forced particle recovery device becomes large.

In addition, the conventional short blast forced particle recovery device for the short blasting is equipped with a motor, a roots blower, a control device, etc., so that a wire for connecting power to each motor, roots blower, and control device is required. Forced particle recovery device is to be used as a mobile device to connect the wire at a long distance, so the long length of the wire is a barrier to various operations, and if the wire is broken, there was another problem, such as impossible to work.

The present invention is to solve the above problems by installing a suction force generator for generating a suction force in the shot blasting device for recovering a small particle using an air rocket nozzle equipped with a venturi nozzle, the conventional conventional shot blasting using the Lutz blower The technical problem is to make the structure simpler than the forced elementary particle collecting device for the purpose of reducing the production cost and to eliminate the work interruption caused by the elongated wires.

The present invention for achieving the above object is provided with a suction hose on one side is installed a collection tank for sucking and collecting the small particles and scale to be accumulated in the work site after the shot blast work, one side of the collection tank is installed inside the collection tank In the shot blast forced elementary particle recovery device connected to the primary suction pipe is inserted into the upper suction pipe to suck the scale floating on the inner upper portion of the collection tank and the secondary suction pipe connected to the suction force generator to generate the suction force on the other side, the suction force The generator has an enlarged diameter portion formed with an intake pipe portion connected to the secondary suction pipe at an upper portion thereof, and a reduced diameter tube having a diameter smaller than that of the enlarged diameter portion is integrally formed at the lower portion of the enlarged diameter portion, and a compressor is provided at the enlarged diameter portion. Air supply pipe connected to the air supply line is inserted into the enlarged diameter part. In the end of the air supply pipe inside the enlarged diameter portion, the venturi nozzle having a thin neck in the middle of the inner diameter of the tube is connected to the lower side of the air rocket nozzle is installed, the air rocket nozzle is filled with a sound absorbing material therein It is characterized in that the insertion is installed to face downward in the interior of the silencer having an air outlet formed on the top.

1 is an explanatory view showing an example of a working state of a shot blast forced particle recovery device.

Figure 2 is a view showing a conventional small blasting device for shot blasting.

Figure 3 is a cross-sectional view showing the structure of the shot blasting forced particle recovery device according to the present invention.

FIG. 4 is a plan view of the apparatus for recovering forced small particles shown in FIG. 3;

Figure 5 is a cross-sectional view of the air rocket nozzle for generating a suction force in the present invention.

6 is an explanatory diagram for explaining the working relationship of the present invention.

<Explanation of symbols for main parts of drawing>

1: Vessel 2: Shot blast residue 3: Forced particle recovery device

4: suction hose 5: forced elementary particle 6: scale

7: collection tank 8: cyclone 9: filter

10: dust collector 11: motor 12: root blower

13: aerorocket nozzle 14: suction pipe portion 15: enlarged diameter portion

16: reduced diameter tube 17: compressor 18: air supply pipe

19: Venturi nozzle 20: Primary suction pipe 21: Secondary suction pipe

22: air supply line 23: sound absorbing material 24: silencer

25: base frame 26: inlet 27: blocking plate

28: opening and closing door 29: opening and closing door 30: air outlet

Hereinafter, the suction force generator of the forced elementary particle recovery device for shot blasting according to the present invention will be described with reference to FIGS. 3 to 6.

3 is a cross-sectional view showing a structure of a shot blasting forced particle recovery device according to the present invention, Figure 4 is a plan view of the shot blasting device for recovering shot element shown in FIG. FIG. 5 is a cross-sectional view of the air rocket nozzle generating a suction force in the present invention, and FIG. 6 is an explanatory view for explaining the working relationship of the present invention.

According to the present invention, the apparatus for recovering the forced small particle for shot blasting is provided with a collection tank 7, a silencer 24, and a cyclone 8 on the upper portion of the base frame 25.

The collection tank 7 collects and collects the forced elementary particles 5 and the scales 6 which are accumulated at the work site after the shot blasting operation, and the forced elementary particles 5 which are accumulated at the work site after the shot blasting work on one side. A suction port 26 to which the suction hose 4 for sucking the scale 6 is connected is installed, and a shot blast residue 2 flowing through the suction port 26 is provided inside the collection tank 7 on the suction port 26 side. Blocking plate 27 is installed to fall down while hitting.

In addition, a primary suction pipe 20 is connected to one side of the collection tank 7 to suck the scale 6 inserted into the upper portion of the collection tank 7 and floating on the inner upper portion of the collection tank 7. The lower side of the body of the collection tank 7 is provided with an opening and closing door 28 for drawing out the forced elementary particles (5) received inside the collection tank (7).

In addition, the cyclone (8) is to collect and collect the dust-like scale (6) floating on the inner upper portion of the collection tank 7, the primary suction pipe 20 is inserted into the inner upper portion of the collection tank (7) The other end of the cyclone (8) is connected tangentially to the cylinder, the lower part is provided with an opening and closing door 29 for drawing out the scale (6) of dust collected in the cyclone (8), the cyclone (8) In the upper portion, the secondary suction pipe 21 is connected to the upper suction pipe part 14 of the air rocket nozzle 13.

The air rocket nozzle 13 is a suction force generator for generating a suction force to suck the shot blast residue (2) from the suction hose (4), the air rocket nozzle 13 is connected to the secondary suction pipe 21 in the upper portion An enlarged diameter portion 15 having a suction pipe portion 14 formed therein is formed, and a reduced diameter tube 16 having a diameter smaller than that of the enlarged diameter portion 15 is integrally connected to the lower portion of the enlarged diameter portion 15. Is formed, the enlarged diameter portion 15 is provided with an air supply pipe 18 connected to the air supply line 22 of the compressor 17 is inserted into the enlarged diameter portion 15 is installed, the enlarged diameter portion 15 At the end of the inside air supply pipe 18, a venturi nozzle 19 having a narrow neck in the middle of the inner diameter of the pipe is connected to the lower side.

At this time, a gap must be provided between the inner circumference of the reduced diameter tube 16 and the outer circumferential edge of the venturi nozzle 19 so that the air sucked through the suction pipe part 14 is enlarged diameter portion 15 and the reduced diameter tube 16. Note that it can be discharged through).

In addition, since the compressed air is ejected at a high speed through the reduced diameter tube 16, the air rocket nozzle 13 is installed with the air rocket nozzle 13 inserted into the silencer 24. . The silencer 24 is formed in a cylindrical shape in which a sound absorbing material 23 is filled inside and an air discharge port 30 is formed in the upper portion, and the air rocket nozzle 13 inserted into the silencer 24 is a suction pipe. The portion 14 is installed to face upward and the reduced diameter tube 16 faces downward.

The working relationship of the present invention configured as described above with reference to Figures 1 and 3 to 6 as follows.

When shot blasting is carried out inside the vessel (1), small particles of steel or iron, such as grit and shot, and forced elementary particles (5) strongly hit the metal surface, peeling off paint or rust on the surface of the metal. At the work site, the forced elementary particles 5 and the scale 6 in the form of dust, which were sprayed during the shot blasting operation, are stacked.

As described above, in the case of recovering the shot blast dregs 2 (the forced elementary particles 5 and the scale 6 collectively referred to as shot blast dregs) accumulated at the work site as shown in FIG. When the forced particle recovery device 3 is operated while the suction hose 4 is extended to the lower side of the ship 1 while the forced particle recovery device 3 is moved to the upper portion of the forced particle recovery device 3, The suction force generated in (3) is collected to suck the shot blast residue (2).

The operation of the forced particle recovery device 3 starts by operating the compressor 17.

3 to 6, when the compressor 17 is operated, the compressed air generated by the compressor 17 is supplied to the air supply pipe 18 of the air rocket nozzle 13 through the air supply line 22. Through the venturi nozzle 19, it is divided into the reduction diameter tube 16 at a high speed.

When the compressed air is injected through the venturi nozzle 19 as described above, compressed air is injected at a high speed in the neck portion of the venturi nozzle 19 which has a narrow inner diameter, and the compressed air is vented through the venturi nozzle 19. As the pressure of the front side of the venturi nozzle 19 decreases and the pressure of the rear side of the venturi nozzle 19 increases rapidly, the suction force in the rear enlarged diameter part 15 and the suction pipe part 14 of the venturi nozzle 19 is increased. Will be produced.

As the suction force is generated in the rear enlarged diameter portion 15 and the suction pipe portion 14 of the venturi nozzle 19 as described above, the secondary suction pipe 21 connected to the suction pipe portion 14 from the suction pipe portion 14 and , An inner space of the cyclone 8 connected to the secondary suction pipe 21, a primary suction pipe 20 connected between the cyclone 8 and the collection tank 7, and a collection tank to which the primary suction pipe 20 is connected ( 7) and the suction force acts on the suction hose 4 connected to the suction port 26 of the collection tank 7, and the shot blast residue 2 accumulated at the work site is sucked through the suction hose 4.

As described above, the shot blast residue 2 sucked through the suction hose 4 flows into the collection tank 7 through the suction port 26 of the collection tank 7, and the collection tank on the suction port 26 side. (7) The blocking plate 27 is installed inside the shot blast dregs (2) that is sucked into the primary suction pipe 20 immediately and does not flow directly to the blocking plate (27) of the collection tank (7) Falls down inside.

At this time, since the shot blast residue (2) is a collective of the small particles, such as steel or iron pieces such as grit and shot and the scale (6) of the dust-like form (6), the relatively small and heavy steel particles (5) is a collection This is accumulated in the inner lower portion of the tank (7), and the light scale (6), such as dust, floats upwards, because the suction force is acting by the air rocket nozzle (13) as mentioned above. A scale 6, such as light dust floating upwards, is sent to the cyclone 8 through the primary suction tube 20.

Thus, when the scale 6 flows into the cyclone 8 through the primary suction pipe 20, the primary suction pipe 20 is installed in a tangential direction to the cyclone 8. The scale (6) flowing into the cyclone (8) causes the vortices and descends to the inner lower portion of the cyclone (8). The scale (6) is collected in a filter (not shown) installed inside the dust scale (6) in the cyclone (8). Gathered and removed.

As above, the suction force that sucks the scale 6 into the cyclone 8 acts on the secondary suction pipe 21 whose end is connected to the upper center of the cyclone 8, so that most of the scale 6 is carried out in the cyclone 8. Air that generates suction force with a small amount of residual fine dust that has been removed is rapidly injected into the silencer 24 from the enlarged diameter portion 15 through the reduced diameter tube 16 through the secondary suction tube 21. do.

As described above, the air is injected at high speed through the reduced diameter tube 16 as described above, and is caused by the action of the venturi nozzle 19, and the enlarged diameter portion 15 side is reduced to the reduced diameter tube 16 side. It is natural that the moving air moves to a gap formed between the outer periphery of the venturi nozzle 19 and the inner periphery of the reduced diameter tube 16.

As described above, the air exiting through the reduced diameter tube 16 is compressed air injected at a high speed through the venturi nozzle 19, and the venturi nozzle is compressed at a high speed through the venturi nozzle 19. The air sucked by the pressure difference formed in the front and rear of the 19) is discharged together, and the air exiting the reduced diameter tube 16 is injected at a high speed, so that a large noise is generated, but the silencer formed of a large cylinder ( Since the inside of the porous absorbent 24 is filled with the porous sound absorbing material 23, the noise is attenuated, and the air passing through the sound absorbing material 23 is discharged to the outside through the air discharge port 30 above the silencer 24.

Then, in the process of sucking and recovering the shot blast residue 2, the forced elementary particles 5 are accumulated in the collection tank 7, and the scale 6 in the form of dust is formed on the inner lower portion of the cyclone 8. They are stacked, and after opening and closing of the aerorocket nozzle 13, the opening and closing of the respective opening and closing doors (28, 29), the forced elementary particles (5) are used for recycling and the scale (6) is disposed of.

As described above, the apparatus for recovering the forced small particle of the shot blasting apparatus uses a rocket nozzle having a venturi nozzle to generate a suction force in the shot blasting apparatus for recovering the suction force, thereby generating a conventional suction force. As the structure is simpler than the forced blower recovery device for shot blasting using blower, the manufacturing cost is greatly reduced, and the work interruption caused by the elongated wires can be eliminated.

Claims (2)

The suction hose 4 is installed at one side, and the collection element 7 which collects and collects the forced elementary particles 5 and the scale 6 which are accumulated at the work site after the shot blasting operation is installed, and one side of the collection tank 7 is installed. It is connected to the suction power generator which is inserted into the inner upper portion of the collection tank (7) is connected to the primary suction pipe 20 for sucking the scale (6) floating on the inner upper portion of the collection tank (7) and generates a suction force on the other side. In the shot blast forced elementary particle recovery device connected to the secondary suction pipe 21, The suction force generator has an enlarged diameter portion 15 formed with a suction pipe portion 14 connected to the secondary suction pipe 21 at an upper portion thereof, and a lower portion of the enlarged diameter portion 15 than the enlarged diameter portion 15. The reduced diameter tube 16 having a reduced diameter is integrally formed, and the enlarged diameter portion 15 has an air supply tube 18 connected to the air supply line 22 of the compressor 17. Is inserted into the inside of the air supply pipe 18 inside the enlarged diameter part 15, and the venturi nozzle 19 formed with a narrow neck in the middle of the inner diameter of the pipe is connected to the lower side installed air rocket Shotblasting forced elementary particle recovery device characterized in that the nozzle (13). The method of claim 1, wherein the air rocket nozzle 13 is installed so that the sound absorbing material 23 is filled therein and the lower side is inserted in the inside of the silencer 24 having the air outlet 30 formed thereon. Forced particle recovery device for shot blasting.