KR0157512B1 - Dust collection equipment - Google Patents

Abstract

The present invention relates to a dust collector, wherein a rotary dust collector having a zigzag or serrated wide surface area is rotatably installed on a shaft rotating by a driving force at an inner central portion of the chamber, and a gap portion is provided at an outer side of the rotary dust collector. The auxiliary dust collector is formed to be formed, and the auxiliary dust collector has a large surface area in a zigzag or serrated shape, and a gas inlet of one side of the hopper installed at the lower side is installed so that noxious gas is introduced into the gap portion. In this configuration, the surface area of the rotary dust collector and the auxiliary dust collector is widened to maximize dust collection efficiency.

Description

Dust collector

1 is a cross-sectional view from the side according to the present invention.

2 is a cross-sectional view from the front according to the present invention.

3 is a cross-sectional view in plan view according to the present invention.

4 is an enlarged cross-sectional view of the excerpts according to the present invention

(A), (b) of FIG. 5 is another embodiment of the rotary dust collector according to the present invention. (a) is a front view, (b) is a side view.

(A) and (b) of FIG. 6 show a mesh covered by the rotary dust collector according to the present invention, where (a) is a front view and (b) is a side view.

* Explanation of symbols for main parts of the drawings

1: chamber 2: rotating current collector

3: shaft 4: fixture

5: Spacing part 6, 6a: auxiliary dust collector

7: space part 8, 8a: auxiliary outlet

9: main outlet 10: hopper

11 gas inlet 12 inlet

13: outlet 14: lower outlet

15: rotary valve 16: support

17: mesh 18, 20: pulley

19: belt 21: motor

22, 23a: bearing 23: grand packing

24: vibration device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dust collector, and more particularly, to a dust collector that separates and collects fine particles (dust) suspended in combustion gas generated in an incinerator such as a waste incinerator, a thermal power plant, or an ironworks plant.

Existing dust collectors include a multi-tub collector, a cloth screen dust collector, a reverse jet system collector, a pulse air collector, a backflow vibratory bag filter for dust collection, but they are backfiltered with high pressure air by vibrating and solenoid valves. Although the device was used to separate and remove dust by spraying on the surface, the bag filter's surface area was not enough, and the collection efficiency was unsatisfactory, and the composition was also complicated and unnecessary space, resulting in expensive maintenance and maintenance costs due to the increase in production cost and electricity and fuel costs. I heard a lot.

Accordingly, an object of the present invention is to invent the above-mentioned conventional powdering point, fine particles suspended in the fuel gas generated in the incineration apparatus by increasing the surface area of the rotary dust collector and the auxiliary dust collector is constituted in the chamber It efficiently separates and collects, reduces unnecessary space, miniaturizes the dust collector, thereby reducing the facility cost and management operation cost, and also provides a dust collector such as extending the life.

As a means for achieving the object of the present invention, when the harmful gas generated in the incinerator, etc. enters from the lower end of the chamber and reaches at a distance between the rotary dust collector and the auxiliary dust collector, the flow of the introduced gas flows in the direction of rotation of the rotary dust collector. Clear gas passing through the gap between the rotary dust collector and the auxiliary dust collector by installing the auxiliary dust collector with less damage on the back filter surface of the dust collector due to the collision and having discharge ports on both sides of the rotary dust collector. Since the rotary dust collector and the auxiliary dust collector are discharged through each of the same time, the negative pressure generated in the gap with the auxiliary dust collector by the rotation of the rotary dust collector is eliminated, so that the flow passing through the gap is smoothly neutralized. Dust flow has a suitable orbital angle to collide with the dust collector, resulting in high separation efficiency and consequently As the flow and atomization are eliminated, clean gas and dust are separated perfectly.

In addition, in order to prevent the dust from adhering to the auxiliary dust collector, the auxiliary dust collector is vibrated by the force of vibration, and the inside of the chamber is rotated by using a gland packing sealing method so that the unpurified gas in the chamber does not leak to the outside. In the gap between the dust collector and the secondary dust collector, the clear gas is discharged to the outlet, and the dust falls to the lower side while forming an orbital angle due to centrifugal force and inertia collision. At this time, dust and fresh air are discharged simultaneously.

Thus, the present invention is provided as a more perfect dust collector in terms of operation and management.

When described in detail by the accompanying drawings shown as an embodiment as follows.

First, a description will be given with reference to FIGS. 1 to 3.

Rotating dust collector 2 having a zig-zag-type wide surface area in the center of the chamber 1 is fixed to the shaft 3 so as to be rotatable. Fixing the fixing stand (4) is installed to be fixed to the shaft (3).

Auxiliary dust collectors 6 and 6a having an increased surface area are formed while forming constant spacing portions 5 on both outer surfaces of the rotary dust collector 2, but the auxiliary dust collectors 6 and 6a and the chamber are provided. (1) The space portion 7 is formed between the inner walls, and the discharge ports 8 and 8a are formed at one end of the space portion 7 so as to communicate with the main discharge port 9.

The hopper 10 is installed at the lower side of the chamber 1, but the gas inlet 11 is installed at one side of the hopper 10. The gas inlet 11 includes an inlet 12 and an outlet 13, and the outlet 13 is a gap 5 formed between the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a. The outlet 13 is formed long in the longitudinal direction as shown in FIG.

The rotary valve 15 is installed at the lower outlet 14 of the hopper 10, and a support 16 supporting the chamber 1 is installed. The outer surface of the rotary dust collector 2 is fixed to cover the mesh 17 as shown in (a) and (b) of FIG.

As shown in FIG. 2, the shaft 3 is provided with a drive pulley 20 and a motor 21, which are connected to the pulley 18 at one end of the shaft and connected as a belt 19, and on both sides of the shaft 3, respectively. The bearings 22 and 22a are attached to the part. Then, the gland packing 23 is inserted into the outer wall of the shaft 3 and the chamber 1, and the vibrator 24 is provided outside the auxiliary dust collectors 6 and 6a.

As the first embodiment, the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a have a zigzag shape or a sawtooth shape in the longitudinal direction as shown in FIGS. 2 and 3 as the first embodiment.

The rotary dust collector 2 and the auxiliary dust collectors 6, 6a are formed in the transverse direction with the sawtooth shape as shown in Figs. 5A and 5B as the second embodiment.

In the third embodiment, the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a have a serrated shape in the longitudinal direction of the dust collector 2, and the auxiliary dust collectors 6 and 6a are transverse. In the direction.

In the fourth embodiment, the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a have a sawtooth-shaped shape as the rotary dust collector 2 in the transverse direction, and the auxiliary dust collectors 6 and 6a. Forms in the longitudinal direction.

In the fifth embodiment, the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a have a sawtooth-shaped shape as the rotary dust collector 2 in the longitudinal direction, and the auxiliary dust collectors 6 and 6a. Omits the sawtooth shape.

In the sixth embodiment, the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a have a sawtooth-shaped shape and the rotary dust collector 2 is in the transverse direction, and the auxiliary dust collectors 6 and 6a. Omits the sawtooth shape.

The rotary dust collector 2 and the auxiliary dust collectors 6 and 6a have a serrated shape in the seventh embodiment, and the auxiliary dust collectors 6 and 6a are in the longitudinal direction, and the rotary dust collector 2 is The sawtooth shape is omitted.

In the eighth embodiment, the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a have a serrated shape, and the auxiliary dust collectors 6 and 6a are in the transverse direction and the rotary dust collector 2 is The sawtooth shape is omitted.

When the driving force is transmitted to the shaft 3 through the pulleys 18, 20 and the belt 19 by driving the motor 21, the shaft 3 has a bearing 22, 22a. ) Is rotated to support and rotates the rotating assembly (2). And the harmful gas (gas containing fine particles) generated in the incinerator, etc., through the inlet 12 and the outlet 13 of the gas inlet 11, the rotary dust collector 2 and the auxiliary dust collector (6), (6a) When flowing in and out below the space | interval part 5 in between, the particulate matter contained in toxic gas is separated and dropped by the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a which rotate at high speed.

That is, at the interval 5 between the rotating rotary dust collector 2 and the secondary dust collectors 6 and 6a, clean gas is discharged through the main outlet 9, and at the same time, the dust (particulate particles) is subjected to centrifugal force and inertia collision. Falling to the lower hopper 10 while forming an orbit angle.

The introduced harmful gas has a low back wheel surface damage due to the collision because the flow of gas is the same as the rotation direction of the rotary dust collector 2, and the gap between the rotary dust collector 2 and the secondary dust collectors 6 and 6a. Since the clear gas passing through the section 5 passes through the rotary dust collector 2 and the auxiliary dust collectors 6 and 6a at the same time, respectively, the auxiliary dust collector 6 is rotated by the rotation of the rotary dust collector 2. , The flow passing through the gap portion 5 is smoothly neutralized while the negative pressure generated in the gap portion 5 from the gap portion 6a is reduced, and the dust flow is the rotary dust collector 2 and the auxiliary dust collector ( 6), (6a) has a suitable orbital angle to impinge the separation efficiency is high, as a result of the backflow and atomization is eliminated, the clear gas and dust separation is perfect.

In order to prevent dust from being attached to the auxiliary dust collectors 6 and 6a, the auxiliary dust collectors 6 and 6a are vibrated by the vibration device 24, and the unpurified gas in the chamber 1 The gland packing 23 prevents leakage to the outside.

After the dust suspended in the harmful gas is separated and dropped, the dropped dust is discharged through the rotary valve 15.

The rotary dust collector 2 installed in the chamber 1 is made of glass fiber or ceramic. The rotary dust collector 2 is used to cover the net body 17 to prevent the rotary dust collector 2 from being separated, changed or damaged by centrifugal force during high speed rotation. Can be.

When the rotary dust collector 2, the auxiliary dust collectors 6, and 6a installed in the dust collector of the present invention are used as a demister, it can also be used as a wet scrubber.

The rotary dust collector 2 and the auxiliary dust collectors 6, 6a are formed in a zigzag or serrated shape as illustrated in the first to eighth embodiments, but are mixed in the longitudinal and transverse directions. As it forms, the surface area is increased to maximize dust collection efficiency.

As described above, the present invention can maximize the dust collection efficiency and downsize the conventional one by widening the surface area of the rotary dust collector and the back filter, which is an auxiliary dust collector, to reduce the manufacturing and facility costs and the management and operating costs. In addition, the present invention is not only due to the performance and efficiency value of the dust collector itself due to the increase of the surface of the back filter, but also to obtain a higher dust collection efficiency than the conventional dust collector, thereby improving the combustion efficiency of the entire incineration plant, It can bring dramatic effects such as economic benefits.

Claims (7)

A rotary dust collector having a large surface area of zigzag or serrated shape is fixedly installed on the shaft rotating by a driving force in the inner central portion of the chamber, and an auxiliary dust collector is installed to form a gap portion of the outer portion of the rotary current collector. The auxiliary dust collector has a large surface area in the shape of a jig-zag or sawtooth, and a gas inlet is provided on one side of the hopper installed in the lower side to allow harmful gas to flow into the gap portion. The dust collecting device according to claim 1, wherein the zigzag or serrated shapes formed on the surfaces of the rotary dust collector and the auxiliary dust collector are longitudinal. The dust collecting apparatus according to claim 1, wherein the zigzag or serrated shapes formed on the surfaces of the rotary dust collector and the auxiliary dust collector are in the transverse direction. The dust collecting device according to claim 1, wherein the shape of the jig-zag or the serrated form formed on the surface of the rotary dust collector is longitudinal, and the shape of the jig-zag or serrated form formed on the surface of the auxiliary dust collecting body is transverse. . The dust collecting device according to claim 1, wherein the shape of the jig-zag or the tooth formed on the surface of the rotary dust collector is transverse, and the shape of the jig-zag or serrated on the surface of the auxiliary dust collecting body is the longitudinal direction. . The dust collecting apparatus according to claim 1, wherein the rotary dust collector and the back filter, which is the auxiliary dust collecting body, can be replaced with a dam and used as a wet cleaner. The dust collecting device according to claim 1, wherein the dust collecting device can be used by covering the surface of the rotary dust collecting body.