KR101266089B1 - solid matter trensferring apparatus - Google Patents

Abstract

According to the present invention, a plurality of terminal silos each having solid particles stored therein and rotary valves provided at a lower end thereof, and an upstream end of the negative pressure line connected to the discharge side of rotary valves provided at each of the plurality of silos in the middle are ventilated with the atmosphere. An intermediate silo is connected at the upper end to the rotary valve at the lower end, and an upstream end of the discharge line connected to the negative pressure source generator is connected at the upper end, and a rotary valve at the discharge side is provided at the lower end. By providing a solid particle conveying apparatus including a final silo whose downstream end of the discharge line is connected to the upper part, the solid particles are brought into non-contact with a pressure source generator that provides a conveying force of solid particles, and thus the negative pressure source generator or solid One negative pressure generator and at the same time It is possible to transfer the solid particles to the final reservoir, and to transfer the solid particles to the final silo disposed over a long distance without increasing the diameter of the delivery tube and without increasing the negative pressure generator. .

Description

Solid matter trensferring apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solid particle transport apparatus, and more particularly, to a device for transporting solid particles stored in a plurality of reservoirs to a main reservoir using negative pressure and positive pressure of one power source.

Conventional solid particles, such as powders, granules, crushed matters, etc., are stored in the first storage and then transferred to the second storage for processing, shipping, transportation, and the like.

The transfer type for this purpose is a conveyor transfer type and a fluid transfer type.

In particular, the fluid transfer type includes a wing of a blower that connects a second cyclone reservoir to a sound pressure source, and connects a first reservoir having a vent to a solid particle suction port of the second reservoir to make a negative pressure in the second reservoir. A positive pressure source is connected to the outlet of the first reservoir having a hopper shape and a rotary valve interposed at the lower outlet, and a vent is provided at the other end of the transfer line having one end connected to the positive pressure source. A second method of non-contacting solid particles to the wing of the blower which is connected to the inlet of the second reservoir to form a positive pressure source, and between the first and second reservoirs to connect the inlet and the outlet to the first and second reservoirs. There is a third method of bringing solid particles into contact with a blade portion of a pump for forming a negative pressure source via a transfer pump.

 These approaches can transfer solid particles from the first reservoir to the second reservoir by one drive source.

However, since the third of these methods contacts the solid particles with the blades providing the transport force of the solid particles, the solids are damaged or different from the blades if the solid particles are, for example, food waste containing food. It is not preferable because there is fear of sticking.

The first and second methods are preferable in view of the fact that the solid particles do not stick to the wing without damaging the wing, since the solid particles are brought into non-contact with the wing providing the transfer force of the solid particles. In order to collect the solid particles stored in various reservoirs and transport them to a long distance, there is a problem that the diameter of the conveying tube is enlarged and the blower which generates a pressure source for conveying is enlarged.

Korea Utility Model Publication 20-1988-0021812 (December 24, 1988) Korean Patent Publication No. 10-1997-0032360 (1997.07.22) Korea Patent Registration No. 10-1201295 (2012.11.08)

The present invention has a problem in solving the above problems.

According to the present invention, a plurality of terminal silos each having solid particles stored therein and rotary valves provided at a lower end thereof, and an upstream end of the negative pressure line connected to the discharge side of rotary valves provided at each of the plurality of silos in the middle are ventilated with the atmosphere. An intermediate silo is connected at the upper end to the rotary valve at the lower end, and an upstream end of the discharge line connected to the negative pressure source generator is connected at the upper end, and a rotary valve at the discharge side is provided at the lower end. The problem can be solved by providing a solid particle transport apparatus including a final silo in which a downstream end of the discharge line is connected to an upper part.

The present invention, by the problem solving means as described above, by contacting the solid particle to the pressure source generator that provides the conveying force of the solid particles, so as not to damage the negative pressure source generator or the solid particles and at the same time Thereby to transfer the solid particles from the end reservoir to the final reservoir, and to transfer the solid particles to the final silo disposed over a long distance without increasing the diameter of the delivery tube and without increasing the negative pressure generator. can do.

1 is an overall conceptual diagram of a solid particle transport apparatus according to an embodiment of the present invention, and
Figure 2 is an overall conceptual view of a solid particle transport apparatus according to another embodiment.

Hereinafter, the solid particle transport apparatus of the embodiment according to the present invention will be described in detail with reference to FIG.

1, a solid particle transport apparatus according to an embodiment of the present invention is indicated as 100.

The solid particle transfer device 100, as shown in Figure 1, is provided with a final vent 11 and the final solid particle inlet 14 at the top and the final rotary valve 13 is discharged the solid particles at the bottom Intermediate storage of the hopper shape is provided with the final hopper shape of the hopper shape, the intermediate solid particle suction opening 24 and the intermediate air suction opening 22 at the upper end, and the intermediate rotary valve 23 through which solid particles are discharged at the lower end. The downstream end is connected to the unit 20, the final solid particle inlet 14, the discharge side of the intermediate rotary valve 23 is connected in the middle, the negative pressure source generator F is interposed upstream, and the upstream end is the intermediate air. Discharge line 25 connected to the inlet port 22, and the downstream end is connected to the intermediate solid particle intake port 24, the terminal rotary valve provided at the lower end of each of the plurality of end-hopper storage portion 30 of the hopper shape ( 33) discharge side is connected and upstream This includes a negative pressure line 35 is vented to the atmosphere.

Each of the plurality of terminal reservoirs 30 includes an injection unit 34 into which solid particles are introduced, at an upper end via a valve V, and an upper end vent hole 31 for venting the inside to the outside. Included in.

The end vent 31 is interposed with an end filter 36 at the time of passage of air to prevent the solid particles stored in the end storage portion 30 from being discharged to the outside.

The intermediate air suction opening 22 may be interposed with an intermediate filter 26 for filtering solid particles.

In addition, the final vent 11 is interposed with a final filter 16 for filtering the solid particles introduced into the final storage unit 10 and the air to pass through.

In addition, in the final storage unit 10, a final discharge line 19 for discharging the solid particles to the outside is connected to the discharge side of the final rotary valve 13.

A valve V is interposed at the downstream end of the final discharge line 19.

In this embodiment, when the final and intermediate storage (10, 20) is a cyclone-shaped portion, the final and intermediate solid particle intake (14, 24) on one side of the upper end of the final and intermediate storage (10, 20) And the final vent 11 and the intermediate air inlet 22 are respectively connected to the top centers of the final and intermediate reservoirs 10 and 20, respectively, the final and intermediate solid particle intakes 14, The solid particles introduced through 24 are dropped into the first and second rotary valves 13 and 23 by the self-weight and the centrifugal force in the final and intermediate storage parts 10 and 20, and thus the final and intermediate filters ( It is preferable from the viewpoint of reducing the load of the 16 and 26, in which case the final and intermediate filters 16 and 26 interposed in the final vent and the intermediate air suction openings 11 and 22 may be excluded.

In addition, in the embodiment, the inner shape of the final and intermediate storage (10, 20) may be a hopper shape, a long cylindrical shape in the horizontal direction, or a hexahedral shape, in this case, the final and intermediate storage (10, The underside of 20 should have the same area as the inlets of the final and intermediate rotary valves 13 and 23.

Further, in the above embodiment, instead of the last, middle and end rotary valves 13, 23, 33, the suction side and the discharge side may be opening and closing means in which airtightness is maintained with respect to each other at the time of opening and closing.

In addition, in the above embodiment, the negative pressure source generator (F) may be a known blower (fan).

Also, in the above embodiment, when the second final storage unit 10-1 is disposed farther from the intermediate storage unit 20 than the final storage unit 10 is illustrated in FIG. 2. As described above, the second final storage unit 10-1 is configured in the same manner as the final storage unit 10, but the second discharge line 25-1 is interposed with the second sound pressure source generator F-1. One end of the final storage unit 10 is connected to the final vent 11 on the way, and the second discharge line 25 is connected to the second final solid particle suction opening 14-1 provided in the second final storage unit 10-1. When the other end of -1) is connected, the solid particles stored in the plurality of terminal storage parts 30 can be easily transferred to the second final storage part 10-1.

 The second final storage unit 10-1, like the final storage unit 10, has a second final cylinder 11-1 and a second final solid particle suction port 14-1 provided at an upper end thereof, and a lower end thereof. The second final rotary valve 13-1 through which solid particles are discharged is provided, and has a hopper shape as a whole.

In addition, the second final cylinder (11-1) of the second final storage unit (10-1) is filtered through the solid particles introduced into the second final storage unit (10-1) and the air passing through the outside The second final filter 16-1 is interposed, and the second final storage unit 10-1 includes a second final discharge line 19-1 for discharging the solid particles to the outside. It is connected to the discharge side of 13-1).

A valve V is interposed at the downstream end of the second final discharge line 19-1, and a middle of the second discharge line 25-1 is connected in the middle of the final discharge line 19.

In the solid particle transport apparatus of the present embodiment, the third final storage unit is connected to the second final storage unit 10-1 in a manner that the second final storage unit 10-1 is connected to the final storage unit 10. The fifth final storage unit can be connected in series to the final storage unit.

The solid particle transfer device 100 configured as described above may be operated as follows.

First, when the solid particles are stored in the end storage portion 30 through the input portion 34, and then the negative pressure source generator (F) is operated while the valve (V) interposed in the input portion 34 is closed. The outside air introduced into the intermediate storage unit 20 via the negative pressure line 35 is introduced into the final storage unit 10 via the discharge line 25 and then discharged to the outside through the final vent 11. When the intermediate storage unit 20 becomes negative pressure, and then the intermediate and terminal rotary valves 23 and 33 are operated, a certain amount of the solid particles stored in the terminal storage unit 30 is the terminal rotary valve 33 and the negative pressure. Through the line 35 is introduced into the intermediate storage unit 20, the solid particles introduced into the intermediate storage unit 20 is introduced into the discharge line 25 through the intermediate rotary valve 23 is a negative pressure source With the discharge side positive pressure air of the generator (F) is introduced into the final storage unit 10, the air is discharged to the final vent (11) , The solid particles are to be stored in the last storage section 10.

The solid particles stored in the final storage unit 10 are supplied to the transport vehicle, the conveyor, the processing station, the collection table of the solid particles via the discharge line 19 as the final rotary valve 13 is operated.

When the solid particles stored in the plurality of terminal storage parts 30 are transferred to the second final storage part 10-1, the solid particles stored in the plurality of terminal storage parts 30 are transferred to the final storage part 10. While performing the transfer operation, the second negative pressure source generator (F-1) and the final rotary valve 13 is operated to discharge the solid particles stored in the final storage unit 10 through the final rotary valve 13 for the second discharge. Flows into the line 25-1 and flows into the second final storage section 10-1 together with the discharge side positive pressure air of the second negative pressure source generator F-1, so that the air flows into the second final cylinder 11-1. ), And the solid particles are stored in the second final storage unit 10-1.

The solid particles stored in the second final storage unit 10 are conveyed by the second discharge line 19-1 through the second discharge line 19-1 as the second rotary valve 13-1 moves, a conveyor, a processing place, It will be supplied to a collection stand or the like.

The solid particle transport apparatus of the present embodiment constructed and operated as described above makes non-contact solid particles with a pressure source generator that provides a transfer force of the solid particles, so as not to damage the sound pressure generator or the solid particles, and at the same time, one sound pressure source. The generator makes it possible to transfer the solid particles from the end reservoir to the final reservoir, and to control the amount of solid particles transferred by the number of revolutions of the intermediate and terminal rotary valves, without increasing the diameter of the transfer tube and It is possible to transfer solid particles to the final storage arranged at a long distance without increasing the negative pressure source generator.

In addition, in the solid particle transport apparatus of the present embodiment, even if the second, third, and fourth final storage portions disposed farther than the final storage portion are added, the negative pressure source generator only needs to connect them through the discharge line interposed therebetween. Since the solid particles can be transferred to the desired second, third, and fourth final reservoirs, the design change of the equipments provided at the upstream end of the final storage part including the final storage part according to the increment of the conveying length of the solid particles is excluded. Thus, the conveying length of the solid particles can be easily and inexpensively increased.

In addition, if the terminal storage of the solid particle transport apparatus of the present embodiment is dealt with the storage room disclosed in the Korean Patent Registration No. 10-1201295 filed and registered by the present invention, it is discharged for each generation of apartments such as apartments It is preferable in view of the fact that the household waste can be collected in the terminal storage and automatically discharged to the final storage via the intermediate storage, and can be discharged while maintaining the cleanness around the apartment.

10; Final storage, 20; Intermediate storage 30; Terminal storage

Claims (12)

A final storage unit 10 provided with a final vent 11 and a final solid particle inlet 14 at the upper end, and a final opening and closing means for maintaining airtightness between the entrance and the exit when the solid particles are discharged at the bottom;
An intermediate storage unit 20 having an intermediate solid particle suction opening 24 and an intermediate air suction opening 22 formed at an upper end thereof, and an intermediate opening and closing means for maintaining airtightness between entrances and exits when the solid particles are discharged at the lower end;
The downstream end is connected to the final solid particle suction opening 14, the discharge side of the intermediate opening and closing means is connected on the way, the negative pressure source generator F is interposed on the upstream side, and the upstream end is connected to the intermediate air suction opening 22. A discharge line 25; And
The downstream end is connected to the intermediate solid particle suction opening 24, and the discharge side of the end opening and closing means for maintaining airtightness between the entrance and exit openings and closings provided at the lower end of each of the plurality of end storage portions 30 is connected in the middle. It includes a sound pressure line 35 is ventilated,
The intermediate air suction opening 22 may be interposed with an intermediate filter 26 for filtering solid particles,
The final vent (11) is a solid particle transfer device, characterized in that the final filter (16) for filtering the solid particles flowing into the final storage unit 10 is passed through the outside. A final storage unit 10 having a final vent 11 and a final solid particle inlet 14 provided at an upper end thereof, and having a final opening and closing means for maintaining airtightness between the entrance and the exit when the solid particles are discharged at the lower end thereof;
A cyclone-shaped intermediate storage unit 20 having an intermediate solid particle suction opening 24 and an intermediate air suction opening 22 provided at an upper end thereof, and an intermediate opening and closing means for maintaining airtightness between entrances and exits when the solid particles are discharged at the lower end thereof;
The downstream end is connected to the final solid particle suction opening 14, the discharge side of the intermediate opening and closing means is connected on the way, the negative pressure source generator F is interposed on the upstream side, and the upstream end is connected to the intermediate air suction opening 22. Discharge line 25, and
The downstream end is connected to the intermediate solid particle suction opening 24, and the discharge side of the end opening and closing means for maintaining airtightness between the opening and closing openings and exits provided at the lower end of each of the plurality of hopper shaped terminal storage portions 30 is connected to the upstream end. A sound pressure line 35 ventilated with the atmosphere,
The final vent 11 is interposed with a final filter 16 for filtering the solid particles flowing into the final storage unit 10 and the air to pass through,
Final and intermediate solid particle intakes (14, 24) are disposed on the upper end side of the final and intermediate storage (10, 20), respectively, the final vent 11 and the intermediate air intake (22) is the final and intermediate storage Solid particle transfer device characterized in that connected to the center of the upper end of the portion (10, 20), respectively. 3. The method according to claim 1 or 2,
The distance from the intermediate storage unit 20 further includes a second cyclone-like second final storage unit 10-1 disposed farther than the final storage unit 10,
The second final storage unit 10-1 is provided with a second final cylinder 11-1 and a second final solid particle suction opening 14-1 at the upper end, and the second final opening and closing of the solid particles at the lower end thereof. Sudan has a
One end of the second discharge line 25-1 having the second sound pressure source generator F-1 is connected to the final vent 11 of the final storage portion 10 on the way.
The other end of the second discharge line 25-1 is connected to the second final solid particle suction opening 14-1 provided in the second final storage unit 10-1,
The second final filter 11-1 of the second final storage unit 10-1 filters the solid particles introduced into the second final storage unit 10-1 and passes the air through the second final filter ( 16-1), characterized in that the solid particle transfer device. 3. The method according to claim 1 or 2,
And a final discharge line (19) for discharging the solid particles to the final storage portion (10) is connected to the discharge side of the final opening and closing means. The method of claim 3, wherein
And a final discharge line (19) for discharging the solid particles to the final storage portion (10) is connected to the discharge side of the final opening and closing means. 6. The method of claim 5,
In the second final storage section 10-1, a second final discharge line 19-1 for discharging the solid particles to the outside is connected to the discharge side of the second final opening and closing means,
The middle part of the 2nd discharge line 25-1 is connected in the middle of the last discharge line 19, The solid particle transfer apparatus characterized by the above-mentioned. The method of claim 1,
The bottom of each of the final storage unit 10, the intermediate storage unit 20 and the plurality of end storage unit 30 has the same area as the inlet of each of the last opening and closing means, the intermediate opening and closing means and the plurality of end opening and closing means Solid particle transfer device characterized in that. 8. The method of claim 7,
The internal storage of the final storage unit 10, the intermediate storage unit 20 and the plurality of terminal storage unit 30 is a hopper shape, a horizontal cylindrical elongated cylindrical shape, characterized in that the hexahedral shape. The method of claim 3, wherein
And said final opening and closing means, said intermediate opening and closing means and said plurality of end opening and closing means are rotary valves. The method of claim 3, wherein
Each of the plurality of terminal reservoirs 30, the upper end includes a terminal vent 31 for venting the inside and the outside,
The end vent 31 is a solid particle transfer device, characterized in that the end filter 36 is interposed during the passage of air to prevent the solid particles stored in the end storage portion 30 is discharged to the outside. The method of claim 3, wherein
Sound pressure source generator (F, F-1) is a solid particle transport apparatus, characterized in that the blower. delete

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