KR100722528B1 - Electrostatic precipitator - Google Patents

Abstract

The present invention relates to an electrostatic precipitator used in a thermal power plant. More specifically, the present invention relates to an electrostatic precipitator capable of collecting dust by operating the remaining section even if the discharge plate is mixed with the electrostatic precipitator.

The present invention is a plurality of discharge plate 20 for discharging; A plurality of dust collecting plates 30 disposed between the plurality of discharge plates 20 to collect dust; A rectifier transformer 40 for supplying boosted electricity to the plurality of discharge plates 20; Four bus ducts (50) installed at one side of the rectifier transformer (40) for supplying booster electric power of the rectifier transformer (40) by dividing into four zones in the plurality of discharge plates (20); Accommodation holes 61 and 63 formed at ends of each of the two copper wires 51 and 53 spaced apart from each other at predetermined intervals in the bus duct 50; A power cut-off bar (69) formed between the two copper wires (51) and (53), the coupling holes (65) (67) formed at both ends thereof to coincide with the receiving holes (61) (63); The fastening member 70 is fitted into the receiving holes 61 and 63 and the coupling holes 65 and 67 so that the power blocking bar 69 is fixed between the two copper wires 51 and 53. It includes a power blocking means (60) consisting of, and is installed in the bus duct 50 is characterized in that the power applied to the discharge plate 20 set to the one zone to cut off and apply .

According to the present invention, even if the discharge plate contact of the electrostatic precipitator is generated in part, the remaining sections can be operated and collected. Therefore, there is an advantage of minimizing the trouble interval and contributing to the reduction of dust emissions.

Thermal power generation, dust, dust collection, rectifier transformer, bus duct, discharge plate, dust collection plate, mixed

Description

Electrostatic Precipitator {Electrostatic Precipitator}

1 is a schematic configuration diagram of a conventional electrostatic precipitator,

2 is a circuit diagram schematically showing the electrostatic precipitator of the present invention;

3 is a view schematically showing an installation state of the discharge plate and the dust collecting plate of FIG.

Figure 4 is a perspective view showing a bus duct equipped with a viewing window of the present invention,

5 is a perspective view showing the bus duct of the perspective window of Figure 4 is separated.

      <Explanation of Signs of Major Parts of Drawings>

20-Discharge Plate 30-Dust Collector

40-rectifier transformer 50-bus duct

60-power disconnect means

The present invention relates to an electrostatic precipitator used in a thermal power plant. More specifically, the present invention relates to an electrostatic precipitator capable of conducting electrostatic precipitating while the remaining section is operated even if the discharge plate is mixed with the electrostatic precipitator.

In general, an electric dust collector receives a combustion gas in the form of particles such as dust discharged from a coal-fired power plant and uses a high voltage to form an electric field with a discharge plate (-pole) to perform a charging operation. The duct and enlargement part of the basic structure to collect and remove the charged particulate combustion gas from the dust collecting plate having a polarity opposite to the discharge plate, to induce the combustion gas (dust-containing) flowing into the electric dust collector after boiler combustion; The discharge part and high voltage generator which energizes the incoming particle, the dust collecting part which collects the charged particles, and removes the dust from the dust collecting plate and vibrate the discharge plate to remove the attached dust to maintain the continuous efficiency Consists of a RAPPING device that plays a role, and charges dust in the electric dust collector All.

Description of the electrostatic precipitator used for dust collection in a thermal power plant and an industrial dust discharge plant as a conventional technology of the present invention is as follows.

1 is a schematic configuration diagram of a conventional electrostatic precipitator.

As shown in FIG. 1, a main body 1 is basically provided to receive a combustion gas containing dust and collect particulate dust contained therein, and on one side of the main body 1, particulate dust is present. Inlet port (3) for receiving the gas contained in the plurality is formed. The other side of the inlet is formed with an outlet 4 for discharging the gas from which the particulate dust is removed to the outside in the opposite direction of the inlet 3, the power supply device 2 and An electrically connected discharge plate support 7 is provided. The discharge plate 9 is vertically provided with an edge discharge plate 9 having a unit having a predetermined width, thereby inducing high voltage to the introduced combustion gas to charge particulate dust, and discharge plate 9 in the main body. ), A dust collecting plate 5 having a polarity opposite to that of the charged dust in the form of particles is provided in parallel thereto. Referring to the configuration of the discharge plate 9 according to the prior art in detail, the discharge plate lower frame 7 spaced apart from the discharge plate upper frame 11 at a predetermined interval is supported by the discharge plate vertical frame 8 is installed A plurality of conventional discharge plates 9 having a predetermined width of a certain thickness are fixed between the discharge plate upper frame 11 and the discharge plate lower frame 7 while being fixed, and the discharge plate 9 facilitates discharge. It is installed with an emitting edge structure that can be used.

However, the conventional dust collector is connected to one bus duct of the rectifier transformer for the electrostatic precipitator which is supplied to collect the dust of the gas discharged from the boiler to the atmosphere. If the gap between pole plates becomes narrower than the design interval due to mixing between pole plates, etc., dust discharge amount increases due to deterioration of electrostatic precipitator due to spark or tripping of the corresponding rectifier transformer. There was a problem that must be shut down.

The present invention has been made to overcome the problems of the prior art, the object of the present invention is to prevent the deterioration of the performance of the electrostatic precipitator used in the thermal power plant, even if the discharge plate mixing occurs in some of the remaining section is dust The present invention provides an electrostatic precipitator capable of collecting dust.

The present invention for achieving the above object is a dust collecting device for collecting dust, a plurality of discharge plate for discharging; A plurality of dust collecting plates disposed between the plurality of discharge plates to collect dust; A rectifier transformer for supplying boosting electricity to the plurality of discharge plates; Four bus ducts installed at one side of the rectifier transformer and supplying boosted electric power of the rectifier transformer by dividing the plurality of discharge plates into four zones; Accommodation holes formed at ends of each of the two copper wires which are spaced apart from each other at predetermined intervals in the bus duct; A power cut-off bar positioned between the two copper wires and formed at both ends of coupling holes corresponding to the receiving holes; And a power shut-off means composed of a fastening member fitted to the accommodation holes and coupling holes so that the power cut-off bar is fixed between the two copper wires, and installed in the bus duct. It is applied to the discharge plates set to be characterized in that the power is cut off and applied.

The bus duct may further include a viewing window formed outside the bus duct so that the state of the power cut-off means can be visually confirmed.

The power cutoff means is characterized in that it comprises a. Here, the fastening member is preferably any one of a bolt and nut, rivets, iron wire, band.

Hereinafter, with reference to the accompanying drawings an embodiment of the present invention will be described in detail.

Figure 2 is a schematic circuit diagram showing the electrostatic precipitator of the present invention, Figure 3 is a schematic view showing the installation state of the discharge plate and the dust collecting plate of Figure 2, Figure 4 shows a bus duct with a see-through window of the present invention FIG. 5 is a perspective view illustrating a bus duct and a power cut-off means installed in the bus duct in a state where the viewing window of FIG. 4 is separated.

FIG. 1 is a circuit diagram schematically showing the present invention, and FIG. 2 is a diagram schematically showing a state in which a plurality of discharge plates 20 and a plurality of dust collecting plates 30 are applied to one zone of the present invention. As shown, the electrostatic precipitator for collecting dust of the present invention is provided with a plurality of discharge plates 20 for discharging, between the plurality of discharge plates 20 a plurality of dust collecting plates 30 for collecting dust The plurality of discharge plates 20 are provided with a rectifier transformer 40 for supplying boosted electricity. One side of the rectifier transformer 40 is provided with four bus ducts 50 for dividing the plurality of discharge plates 20 into four zones and supplying boosted electricity of the rectifier transformer 40, and four bus ducts 50. Inside the four power cutoff means 60 for blocking and applying the power applied to the discharge plate 20 set in each one zone is provided.

Here, the discharge plate (-pole) 20 is applied to the high voltage (80kV DC) at the secondary side of the rectifier transformer generates a corona current, the dust mixed in the exhaust gas passing between the discharge plate 20 and the dust collecting plate 30 Charge the (DUST) so that it can be collected on the collecting plate. The dust collecting plate (+ pole) 30 collects dust floating in the dust collecting chamber by the corona current generated in the discharge plate 20. The rectifier transformer 40 boosts AC480V to 80 kV by the rectifier transformer 40 to apply a high voltage to the discharge plate 20. The bus duct 50 electrically insulates the bare copper wire connected to the discharge plate 20 from the rectifier transformer 40 from the outside.

Here, 92 discharge plates 20 in one zone are installed and 24 dust collector plates 30 in one zone are installed. Therefore, there are 368 discharge plates 20 in four zones and 96 collector plates 30.

In addition, the rectifier transformer 40 reduces the AC current of 480V to a DC current of 80kV and distributes the discharge plates 20 to each of the four zones through the four bus ducts 50. At this time, when dust is generated in the dust collecting plate 30 by the discharge of the discharge plate 20, the collected dust is collected in the hopper of the dust collecting chamber provided in the lower discharge plate 20 and the dust collecting plate 30 and then a certain amount When it is gathered, it is processed.

In addition, the bus duct 50 is provided with a high tension bar 51 and 53 for supplying currents transmitted from the rectifier transformer 40 to the plurality of discharge plates 20. At this time, the copper wires 51 and 53 are installed to be disposed at the center of the bus duct 50 so as to be spaced apart from the inner wall of the bus duct 50 by a predetermined interval because high pressure flows.

On the other hand, Figures 3 and 4 is a perspective view showing a see-through window and the power cut-off means 60 is installed in the bus duct (50). As shown, the sight glass 80 is formed on the outside of the bus duct 50 so that the state of the power cut-off means 60 can be visually confirmed.

Here, the viewing window 80 is formed on the outside of the bus duct 50, and may be arbitrarily selected at a position that is easy for the user to check with the naked eye.
4 and 5, the see-through window 80 forms a see-through hole 81 on the outside of the bus duct 50, and forms a step 83 on the outside of the see-through hole 81. After placing the transparent member 85 on the stepped portion 83 of the see-through hole 81, the fastening member 70 is fastened. At this time, the outer side of the transparent member 85 may further be disposed to combine the finishing member 87 to protect the outer surface of the transparent member (85). The fastening member 70 is preferably a bolt and nut.

Since the power cut-off means 60 is disposed in the bus duct 50 provided with the see-through window 80, the transparent member 85 of the see-through window 80 is removed, and then the inside of the bus duct 50 is disposed. The power cutoff means 60 can be operated according to the user's discretion.

Here, the power cut-off means 60 has accommodation holes 61 and 63 formed at ends of each of the two copper wires 51 and 53 which are spaced apart from each other at predetermined intervals in the bus duct 50. Between the two copper wires 51 and 53, a power cutoff bar 69 formed at both ends of coupling holes 65 and 67 corresponding to the receiving holes 61 and 63 is positioned. The fastening member 70 is inserted into the accommodation holes 61 and 63 and the coupling holes 65 and 67 between the two copper wires 51 and 53 so that the power cutoff bar 69 is fixed. Combined. Here, the fastening member 70 is preferably any one of bolts and nuts, rivets, iron wires, bands.

According to the present invention configured as described above, when an abnormality occurs in any one of four sections, that is, internal internal contact occurs due to vibration from a dust collector or hot gas flowing into the dust collector and dust, the power cut-off means for this section. The power cut-off bar 69 of 60 may be separated to stop dust collection in a section where a failure occurs, and dust may be collected using the remaining three sections.

Although the preferred embodiments of the present invention have been described in detail above, those of ordinary skill in the art to which the present invention pertains may implement the present invention by various modifications or design changes without departing from the scope of the claims. In case it is regarded as the scope of the present invention.

According to the present invention, even if the discharge plate contact of the electrostatic precipitator is generated in any one of the four sections, the remaining three sections can be operated and electrostatic precipitating, thereby minimizing the failure section and contributing to the reduction of dust emissions. have.

In addition, the present invention has the advantage that by using the power cut-off means installed in each section of the electrostatic precipitator when the discharge plate contact occurs, the electricity supply is stopped only in the corresponding failure section and the remaining three sections can continue to operate.

In addition, the present invention has the advantage that can be visually confirmed the separation state in the power cut-off means disposed in the bus duct by installing a see-through window in the bus duct.

Claims (3)

In the dust collector which collects dust, A plurality of discharge plates 20 for discharging; A plurality of dust collecting plates 30 disposed between the plurality of discharge plates 20 to collect dust; A rectifier transformer 40 for supplying boosted electricity to the plurality of discharge plates 20; Four bus ducts (50) installed at one side of the rectifier transformer (40) for supplying booster electric power of the rectifier transformer (40) by dividing into four zones in the plurality of discharge plates (20); Accommodation holes 61 and 63 formed at ends of each of the two copper wires 51 and 53 spaced apart from each other at predetermined intervals in the bus duct 50; A power cut-off bar (69) formed between the two copper wires (51) and (53), the coupling holes (65) (67) formed at both ends thereof to coincide with the receiving holes (61) (63); The fastening member 70 is fitted into the receiving holes 61 and 63 and the coupling holes 65 and 67 so that the power blocking bar 69 is fixed between the two copper wires 51 and 53. It is configured to include a power interruption means (60) consisting of, Electrostatic precipitator, characterized in that the power is installed in the bus duct (50) is cut off and applied to the discharge plates (20) set to the one zone. The method of claim 1, wherein the bus duct 50 further comprises a see-through window 80 formed on the outside of the bus duct 50 so as to visually check the state of the power cut-off means 60. Electrostatic precipitator. delete

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