KR102552413B1 - Electrostatic precipitator with radial shape precipitation needle - Google Patents

Abstract

In the present invention, very excellent discharge and dust collection efficiency is possible through a structure for applying electricity to (+) poles and (-) poles that do not interfere with each other and radial dust collection needles in which discharge is doubled on both the outside and inside sides. It is an electric dust collector equipped with radial dust collection needles with greatly improved dust collection capacity.

Description

Electrostatic precipitator with radial shape precipitation needle}

The present invention relates to an electric precipitator equipped with radial dust collection needles, comprising: a housing (100); and an inlet (200) formed inside the housing (100) through which air containing harmful substances such as flux is introduced. ; And, the first connection pipe 310 formed inside the housing 100 and connected to the inlet 200, and the air containing harmful substances introduced through the first connection pipe 310 into 1 A first dust collection pipe 320 for collecting primary dust, a first electricity applying unit 330 formed inside the dust collection pipe 320 and supplied with (+) polarity electricity supplied from the outside, and the dust collection pipe ( 320) formed inside the first electricity application unit 330 and to which (-) polarity electricity supplied from the outside is applied, and the first electricity application unit 330 A first electric dust collecting unit 300 in which a plurality of radial dust collecting needles 600 and a second connection pipe 350 are formed in a star-shaped shape with a through hole in the center; And an outlet 500 formed inside the housing 100 and connected to the second connection pipe 350 to discharge the purified air after dust collection is completed; electric dust collector equipped with radial dust collection needles, characterized in that composed of. It's about the device.

In general, an electrostatic precipitator is a device that applies an electric field to a gas, particularly dust suspended in the air, to make it electrified, and collects particles with an electrostatic force to clean the gas. Depending on the method of removing dust collected in the dust collector, there are wet and dry types, and there are vertical and horizontal ones according to the flow of gas.

The principle of this electrostatic precipitator is to set a cylindrical dust collection electrode as positive, apply negative DC high voltage to a discharge line suspended in the center of the cylinder, and then dust inside the cylinder. When air containing is sent from the bottom, the dust becomes negatively charged and adheres to the inner surface of the cylinder, and the air flowing out to the top of the cylinder becomes clean. Dust accumulated in the cylinder is generally removed by washing with water or applying mechanical shock to the cylinder.

The former is called wet dust collector and the latter is called dry dust collector. There are horizontal and vertical gas flows. The former is suitable for cleaning a large amount of gas, and the latter has the advantage of efficiently collecting dust and having a small installation area. To create direct current high voltage, 40,000 to 70,000 volts are made using a voltage regulator, special high-voltage transformer, and rectifier using 50 or 60 Hz AC power. High-voltage rectifier tubes or silicon rectifiers are used as rectifiers. Regardless of which one is used, the method of limiting the overcurrent when the DC high-voltage side is short-circuited must be considered.

On the other hand, these electric precipitators have been disclosed through various embodiments, and among them, “two-stage charged electric precipitator (Republic of Korea Utility Model Registration No. 20-0302935)” of Patent Document 1 is posted.

The "two-stage charge-type electric precipitator" of Patent Document 1 is provided with a space of a certain size inside, a normal ventilation fan (2) is installed, and an inlet (3) through which air is introduced and an outlet (4) through which air is discharged. It is provided on the side of the body (5) and the inlet (3) of the space of the body (5) and collects harmful substances of large particles contained in the air containing harmful substances that are introduced and moved by the ventilation fan (2). A pre-filter member (6) that removes and moves in an even distribution, a discharge member (7) that positively charges incoming foreign substances to positively charge pollutants, and a negative charge for harmful substances discharged from the discharge member (7) Dust collection formed by a dust collecting member 9 that collects and purifies dust by an electrode plate 16 having an even distribution of air purified by the dust collecting member 9 and an after filter member 10 that prevents re-dispersion of contaminants It is characterized by means (11), as well as harmful substances of large particles such as dust, as well as various harmful substances in the air at industrial sites such as restaurants, homes, offices and factories (eg; oil smoke at restaurants, generated during welding welding gas containing heavy metals, smoke generated during heat treatment, soldering fumes, plasticizer fumes such as oil mist, fume, DOP, harmful dust accompanied by odors, and other air pollutants) containing heavy metals. It had the advantage of being able to remove harmful substances.

However, the "two-stage charge-type electric precipitator" of Patent Document 1 has a problem in that the discharge and dust collection efficiency is low because the discharge member of the general structure is used, and the dust collection capacity is low.

Patent Document 1: Korean Utility Model Registration No. 20-0302935

The present invention has been made to solve the above problems, and an object of the present invention is to provide an electric dust collector equipped with radial dust collecting needles with greatly improved dust collecting ability through excellent discharge and dust collection efficiency.

Another object of the present invention is to provide an advantage of showing a pulse of 5 times the implied force compared to the waveform of a normal needle nozzle without using a separate high voltage pulse device.

Another object of the present invention is to provide an electric precipitator equipped with radial dust collecting needles having a peak current waveform superior to that of a normal needle nozzle.

Another object of the present invention is to provide an electric precipitator equipped with radial dust collection needles, which has a high ionization value and low power consumption, and has an energy saving effect.

In order to solve the above problems, an electrostatic precipitator having radial dust collecting needles according to the present invention includes a housing 100; formed inside the housing 100 and containing harmful substances such as flux. An inlet 200 through which air is introduced; and a first connection pipe 310 formed inside the housing 100 and connected to the inlet 200, and the air introduced through the first connection pipe 310. A first dust collection pipe 320 in which air containing harmful substances is primarily collected, and a first dust collection pipe 320 formed inside from the upper side of the dust collection pipe 320 and supplied with (+) polarity electricity supplied from the outside. The electricity applying unit 330 and the dust collecting pipe 320 are formed from the lower side to the inside and do not interfere with the first electricity applying unit 330, and the (-) polarity electricity separately supplied from the outside is applied. 2 electricity application unit 340, a plurality of star-shaped dust collection needles 600 having a through-hole in the center coupled to the first electricity application unit 330 in a spaced apart state, and a second connector 350 The first electric precipitator 300 is formed; and an outlet 500 formed inside the housing 100 and connected to the second connection pipe 350 to discharge the purified air after dust collection is completed.

In addition, a housing 100; and an inlet 200 formed inside the housing 100 through which air containing harmful substances such as flux is introduced; and formed inside the housing 100, A first connection pipe 310 connected to the inlet 200, and a first dust collection pipe 320 for primary dust collection of air containing harmful substances introduced through the first connection pipe 310; A first electricity application unit 330 formed from the upper side of the dust collector 320 to the inside and applied with (+) pole electricity supplied from the outside, and formed from the lower side of the dust collector 320 to the inside. The second electricity application unit 340 to which electricity of the (-) polarity supplied from the outside is separately applied without interfering with the first electricity application unit 330, and a plurality of second electricity application units 340 to the first electricity application unit 330. A first electric dust collecting part 300 in which star-shaped radial dust collecting needles 600 and a second connection pipe 350 are formed that are coupled in a spaced apart state; and formed inside the housing 100 Doe, the third connection pipe 410 connected to the second connection pipe 350, and the second dust collection pipe 420 in which the secondary dust collection of the air primarily collected through the third connection pipe 410 is performed And, a third electricity application unit 430 formed from the upper side of the second dust collector 420 to the inside and applied with (+) pole electricity supplied from the outside, and the second dust collector 420 A fourth electric application unit 440 formed from the lower side to the inside and to which electricity of the (-) pole supplied from the outside is separately applied without interfering with the third electricity application unit 430, and the third electricity application unit A second electrostatic precipitator 400 in which a plurality of star-shaped dust collecting needles 600 and a fourth connection pipe 450 are formed in the star shape with a through hole in the center coupled to the 430 in a spaced apart state; and an outlet 500 formed inside the housing 100 and connected to the fourth connection pipe 450 to discharge the purified air after dust collection is completed.

In addition, the radial dust collecting needle 600 is formed by continuously connecting the first triangular discharge portion 610 of a triangular shape in an outward direction on the outer surface, and a through hole 620 is perforated at the inner center, It is characterized in that the triangular second triangular discharge portion 630 is continuously connected to the inner surface of the through hole 620 in an inward direction.

In addition, the first triangular discharge unit 610 and the second triangular discharge unit 630 are each formed in an isosceles triangle shape.

In addition, the base angle G1 of the first triangle discharge part 610 is formed larger than the base angle G2 of the second triangle discharge part 630 .

In addition, curved surface radial projections 611 and 631 formed of curved surfaces are formed at the vertices of the first triangular discharge unit 610 and the second triangular discharge unit 630, respectively.

In addition, the first electricity application unit 330 includes a first transmission shaft 331 provided on the upper side of the first dust collection pipe 320 and transmitting electricity of a (+) pole, and the first dust collection pipe A transmission disk 332 located inside the 320 and formed in a disk shape coupled to the lower portion of the first transmission shaft 331, and a plurality of second transmission plates having an upper portion coupled to the transmission disk 332 It is formed as a shaft 333, and the radial dust collecting needle 600 is coupled to the second transmission shaft 333.

In addition, the second electricity applying unit 340 is coupled to a support plate 341 provided on the lower side of the first dust collection pipe 320 and the center of the support plate 341, and the first dust collection pipe ( 320) passing through the center of the radial dust collecting needles 600 located inside the radial dust collecting needles 600 and being spaced apart from the third transmission shaft 342 through which electricity of the (-) pole is transmitted. characterized by

In addition, a plurality of coupling holes 601 are formed in the radial dust collecting needles 600 through holes so that the radial dust collecting needles 600 can be inserted into and coupled to the second transmission shaft 333, and the second transmission shaft 333 A spacing pin 700 is formed between the plurality of radial dust collecting needles 600 inserted into the shaft 333 so as to be inserted through the second transmission shaft 333 so that the radial dust collecting needles 600 are spaced apart. characterized by

In addition, a sealing cover 810 made of an insulating material coupled to the first transmission shaft 331 is formed on the upper side of the first dust collecting pipe 320, and the second dust collecting pipe 320 has a lower side of the second dust collecting pipe 320. An insulating pedestal 820 coupled to the transmission shaft 333 is formed, the pedestal 820 and the support plate 341 are spaced apart by a predetermined distance, and the third transmission is at the center of the pedestal 820. It is characterized in that the through hole 821 is perforated so that the shaft 342 passes through.

In addition, the third electricity applying unit 430 is characterized by having the same structure as the first electricity applying unit 330 .

In addition, the fourth electricity applying unit 440 is characterized in that it has the same structure as the second electricity applying unit 340 .

In addition, a plurality of cooling fans 900 for cooling the first electric dust collecting part 300 or the second electric dust collecting part 400 are formed on the side surface of the housing 100 .

In addition, the flux installed on the upper part of the first electric dust collecting part 300 or the second electric dust collecting part 400 and fixed to the inner surface of the first electric dust collecting part 300 or the second electric dust collecting part 400 ) It is characterized in that the cleaning equipment 1000 for spraying and desorbing the washing liquid is further provided.

In addition, the flux installed inside the first electric dust collecting part 300 or the second electric dust collecting part 400 and adhered to the inner surface of the first electric dust collecting part 300 or the second electric dust collecting part 400 ) It is characterized in that the scraper equipment 1100 for scraping and desorption is further provided.

As described above, according to the present invention, there is an advantage in that discharge and dust collection efficiency is greatly improved through the radial dust collecting needles in which discharge is doubled from the outside and the inside.

In addition, according to the present invention, there is an advantage of showing a pulse of 5 times the implied force for a time of 1/18 to 1/4 compared to the waveform of the general needle nozzle.

In addition, according to the present invention, there is an advantage of having a peak current value with superior power content compared to the waveform of the general acicular nozzle.

In addition, according to the present invention, the actual power consumption is very small, and there is an energy saving effect.

1 is a perspective view showing an overall appearance of an electric dust collector equipped with radial dust collection needles according to a preferred embodiment of the present invention.
2 is a side view showing a side view of an electric dust collector equipped with radial dust collecting needles according to a preferred embodiment of the present invention.
3 is a perspective view showing a first electric dust collecting unit among configurations of an electric dust collecting device equipped with radial dust collecting needles according to a preferred embodiment of the present invention;
4 is a cross-sectional perspective view showing a first electric dust collecting unit among configurations of an electric dust collecting device equipped with radial dust collecting needles according to a preferred embodiment of the present invention.
5 is an exploded perspective view showing an exploded state of a first electric dust collecting unit among configurations of an electric dust collecting device equipped with radial dust collecting needles according to a preferred embodiment of the present invention.
6 is a perspective view and a plan view showing the appearance of radial dust collecting needles among the configuration of an electric dust collector equipped with radial dust collecting needles according to a preferred embodiment of the present invention.
7 is a cross-sectional view showing a cross-sectional view of a first electric dust collecting unit among the configurations of an electric dust collecting device equipped with radial dust collecting needles according to a preferred embodiment of the present invention.
8 is a cross-sectional view of a second electric dust collecting unit among configurations of an electric dust collecting device equipped with radial dust collecting needles according to a preferred embodiment of the present invention.
9 is a cross-sectional view showing a state in which washing equipment is coupled to a first electric dust collecting part among the configuration of an electric dust collecting device equipped with radial dust collecting needles according to a preferred embodiment of the present invention.
10 is a cross-sectional view showing a state in which a scraper device is coupled to a first electric dust collecting part among the configuration of an electric dust collecting device equipped with radial dust collecting needles according to a preferred embodiment of the present invention.
11 is a view showing the movement of the (+) pole and the (-) pole in the first electric dust collecting unit among the configurations of an electric dust collecting device equipped with radial dust collecting needles according to a preferred embodiment of the present invention and the resistance (R of each radial dust collecting needle) ) cross section showing the range
12 is a diagram explaining a DPP current measurement picture of a supply voltage of 17.5KDC and 10us (100Khz).
13 is a diagram explaining time off and time on photos of DPP.
14 is a diagram illustrating a current value when power is dissipated.
15 is a diagram explaining the power pulse generation time as the implied force divergence time.
16 is a diagram showing a low state power value actually consumed in a high output state.
17 and 18 are diagrams showing corona current waveforms and pulses of the normal needle nozzle according to the strength of the electric field.

Hereinafter, with reference to the accompanying drawings, an electric dust collector 1 equipped with radial dust collecting needles according to an embodiment of the present invention will be described in detail. First of all, it should be noted that among the drawings, the same components or parts are indicated by the same reference numerals as much as possible. In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the gist of the present invention.

Referring to FIG. 1 or 2, the electric dust collector 1 equipped with radial dust collection needles according to an embodiment of the present invention includes a housing 100, an inlet 200, a first electric dust collection part 300, a first It consists of 2 electric dust collecting parts 400, outlets 500 and radial dust collecting needles 600.

Prior to the description, the electric dust collector 1 equipped with radial dust collection needles according to an embodiment of the present invention includes a fan, a motor, a PCB, a power supply device, and interlocking driving elements so that the operation can be performed smoothly. Since the principle of configuring and operating the driving elements corresponds to a level of technology widely known in the field to which the present invention belongs, a detailed description thereof will be omitted.

In addition, it should be noted that some components of the present invention are omitted in some drawings for detailed and clear description of the present invention.

In addition, since the present invention consists of two dust collecting units (the first electric dust collecting part 300 and the second electric dust collecting part 400) having the same structure in one embodiment, the detailed description is based on the first electric dust collecting part 300. It should be noted that explanations are made.

First, the housing 100 will be described. As shown in FIG. 1 or 2, the housing 100 is a kind of frame in which the components of the present invention are provided, and a PCB, a power supply, and the like are further installed.

Next, the inlet 200 will be described. As shown in FIG. 2, the inlet 200 is a kind of pipe formed inside the housing 100, connected to an external soldering facility, and connected to a first electrostatic precipitator 300 to be described later, and welded. flux, welding gas containing heavy metals, smoke generated during heat treatment, soldering fumes, plasticizer fumes such as oil mist, fumes, DOP, etc., harmful dust accompanied by odors, and other air pollutants. It serves to move air containing harmful substances such as heavy metal-containing particulates to the first electrostatic precipitator 300.

Next, the first electric precipitator 300 will be described. As shown in FIG. 1, FIG. 2 or FIG. 3, the first electrostatic precipitator 300 is a component that electrostatically collects air containing harmful substances, and is provided in the housing 100 through the inlet port. 200, it is connected to the second electric dust collecting unit 400 to be described later when the secondary dust collection treatment is performed, and it is possible to be connected to the outlet 500 to be described later when the primary dust collection treatment is performed.

As shown in FIG. 4, FIG. 5, FIG. 6 or 7, the first electric dust collecting unit 300 includes a first connection pipe 310, a first dust collecting pipe 320, and a first electric application unit ( 330), a second electricity application unit 340 and a second connection pipe 350, and the radial dust collecting needle 600 is provided separately.

As shown in FIG. 2, the first connection pipe 310 is formed in a tubular shape at a portion where the first electrostatic precipitator 300 and the housing 100 are coupled and is connected to the inlet 200. By doing so, it is possible to move the air containing harmful substances introduced through the inlet 200 to the first dust collection pipe 320 to be described later.

As shown in FIG. 3 or 4, the first dust collection pipe 320 is formed in a cylindrical shape, has open tops and bottoms, and is a kind of cylindrical pipe made of a space inside. 320, the first and second electricity application units 330 and 340 and the radial dust collection needles 600 are provided so that dust collection treatment is performed inside.

As shown in FIG. 4 or 5, the first electricity applying unit 330 is a component formed from the upper side of the dust collector 320 to the inside and supplied from the outside with (+) polarity electricity flowing, It consists of a first transmission shaft 331, a transmission disc 332, and a second transmission shaft 333.

As shown in FIG. 4 or 7, the first transmission shaft 331 is provided on the upper side of the first dust collection pipe 320 and is directly supplied with (+) polarity electricity from the outside. The first transmission shaft 331 is fixed to the sealing cover 810 by penetrating the sealing cover 810 made of an insulating material detachably coupled to the upper side of the first dust collecting pipe 320 for sealing. desirable.

At this time, fixing nuts may be provided on the upper and lower sides of the first transmission shaft 331 so that the first transmission shaft 331 may be closely fixed to the sealing cover 810 and fastened thereto.

As shown in FIG. 4 or 5, the transmission disk 332 is a component coupled to the lower part of the first transmission shaft 331 in a state located on the inner upper side of the first dust collection pipe 320, Electricity of the (+) pole flows, and a plurality of second transmission shafts 333 to be described later are coupled to guide the flow of electricity of the (+) pole to the second transmission shaft 330.

On the other hand, the transfer disc 332 is formed in a disc shape having the same concentricity as the first dust collector 320, so that the second transfer shaft 333 is on the inner side of the first dust collector 320. It enables them to be arranged at regular intervals.

As shown in FIG. 4 or 5, a plurality of second transmission shafts 333 are coupled at regular intervals along the outer circumferential surface of the transmission disc 332 (expressed as four installed in one embodiment in the present invention) .) As a component through which electricity of the (+) pole transmitted through the transmission disc 332 flows, the upper part of the second transmission shaft 333 is coupled to the transmission disc 332, and the second transmission shaft The lower part of the 330 is coupled to the pedestal 820 made of an insulating material fixed to the inner lower part of the first dust collecting pipe 320, and electricity of the (+) pole flowing through the second transmission shaft 330 It prevents flow to the dust collection pipe 320.

At this time, a through hole 821 is perforated at the center of the pedestal 820 so that a third transmission shaft 342 to be described later through which electricity of the (-) pole flows passes.

On the other hand, as shown in FIG. 4, FIG. 5 or 7, the present invention receives electricity of the (+) pole from the second transmission shaft 333 to the plurality of second transmission shafts 333 and collects electric dust. It is characterized in that a plurality of the radial dust collection needles 600, which are one of the components that cause discharge, are installed at regular intervals in the vertical direction, and the radial dust collection needles 600 are large, It consists of a first triangular discharge unit 610, a through hole 620, and a second triangular discharge unit 630.

As shown in FIG. 6, the coupling holes 601 are formed on the surface of the radial dust collecting needles 600 at the same position and in the same number as the second transmission shaft 333, so that the second transmission shaft 333 Allows insertion and bonding.

As shown in FIG. 6, the first triangular discharge unit 610 is a component forming a radial shape by continuously connecting to the outer surface of the radial dust collecting needle 600 in a triangular shape in an outward direction. Condensed (+) polarity electricity is radiated from the corner of the triangular discharge unit 610 .

As shown in FIG. 6, the through-hole 620 is a component perforated at the inner center of the radial dust collecting needle 600, and a second triangular discharge part 630 to be described later is formed, and the first collector The third transmission shaft 342 formed from the lower part of the tube 320 to the inside passes through, and electricity of the (-) pole is radiated from the inside of the radial dust collecting needle 600 to the inside of the radial dust collecting needle 600. Discharge is also generated, enabling the dust collection operation to be performed.

As shown in FIG. 6, the second triangular portion 630 is a component forming a radial shape by being connected to the inner surface of the through hole 620 in a triangular shape in an inward direction. Condensed positive (+) pole electricity is radiated from the edge of the front (630).

Through this configuration, the radial dust collecting needles 600 have the effect of greatly increasing the dust collection efficiency by performing a double dust collection operation on the outside and inside of the while enabling the capacitor function.

On the other hand, as shown in FIG. 6, in the radial dust collecting needle 600, the first triangular discharge part 610 and the second triangular discharge part 630 are each formed in the form of an isosceles triangle, and the first triangular chamber When the base angle (G1) of the front part 610 is larger than the base angle (G2) of the second triangular discharge part 630, experimental data values to be described later can be obtained, and the best dust collection ability can be demonstrated through the present invention. .

On the other hand, since curved surface radiation protrusions 611 and 631 made of curved surfaces are formed at the vertices of the first triangle discharge part 610 and the second triangle discharge part 630, respectively, it is possible to widen the radiation range and collect dust. It becomes possible to further increase the efficiency.

On the other hand, a spacing pin 700 is installed between the radial dust collection needles 600 to space each of the radial dust collection needles 600 inserted into the second transmission shaft 333 vertically at a predetermined distance.

As shown in FIG. 4 or 5, the second electricity applying unit 340 is formed from the lower side of the dust collector 320 to the inside so as not to interfere with the first electricity applying unit 330 and separately from the outside. As a component to which electricity of the (-) pole is applied, it consists of a support plate 341 and a third transmission shaft 342.

The support plate 341 is provided on the lower side of the first dust collector 320 and serves to support the third transmission shaft 342 .

At this time, it is preferable that the pedestal 820 and the support plate 341 are positioned apart from each other by a predetermined distance.

The third transmission shaft 342 is coupled to the center of the support plate 341 and passes through the through hole 620 of the radial dust collecting needle 600 located inside the first dust collecting pipe 320. As a component through which electricity of the (-) pole is transmitted while being spaced apart from the radial dust collecting needles 600, the inside of the radial dust collecting needles 600 and the first dust collection pipe are transmitted due to the third transmission shaft 342. It is possible for (-) pole electricity to be radiated to the inner surface of (320).

Depending on the structure, the second connection pipe 350 is connected to the outlet 500 to send the purified air from the first electric dust collecting unit 300 back to a facility such as an external soldering facility or the like, which will be described later. It is a kind of pipe that is connected to the third connection pipe 410 and guides the movement of air after the first dust collection operation to enable the second dust collection operation to be performed.

Despite the structure of the first electric dust collecting unit 300 and the radial dust collecting needles 600 having a layered coupling structure, through the structure and coupling relationship of the present invention, each of the radial dust collecting needles 600 The resistance values (R1, R2, R3, R4, R5, ...) become the same.

That is, as shown in Equation 1 below, since the same voltage (V) is supplied from the outside and the resistance (R) is the same, the current (I) of the radial dust collecting needles 600 at all positions is uniformly the same, so that the uppermost layer A short circuit or the like does not occur at the radial dust collecting needle 600 portion of the airtight cover 810 to prevent it from being deformed or damaged.

[Electrical formula 1]

Next, the second electric precipitator 400 will be described. As shown in FIGS. 1, 2 or 8, the second electrostatic precipitator 400 has the same configuration and operation as the first electrostatic precipitator 300, and is formed inside the housing 100. A third connection pipe 410 connected to the second connection pipe 350 as a component in which a secondary dust collection operation is performed through which purified air flows in after the first dust collection operation is completed from the first electric dust collecting unit 300; A second dust collection pipe 420 that secondarily collects the air primarily collected through the third connection pipe 410, and formed from the upper side of the second dust collection pipe 420 to the inside and supplied from the outside ( The third electricity application unit 430 to which electricity of +) polarity is applied and the second dust collector 420 are formed inside from the lower side so as not to interfere with the third electricity application unit 430 and separately from the outside. The fourth electricity application unit 440 to which electricity of the negative (-) pole is supplied and a star-shaped dust collector having a central hole through which a plurality of units are coupled to the third electricity application unit 430 while being spaced apart from each other A fourth connection pipe 450 connected to the needle 600 and the outlet 500 is formed.

Next, the outlet 500 will be described. As shown in FIG. 2, the outlet 500 is formed inside the housing 100 and is connected to the second connection pipe 350 or the fourth connection pipe 450 so that primary or secondary dust collection is performed. It is a kind of pipe that discharges the finished purified air and moves it back to an external facility such as a soldering facility.

On the other hand, in the present invention, it is characterized in that a plurality of cooling fans 900 for cooling the first electric dust collecting part 300 or the second electric dust collecting part 400 are formed on the side surface of the housing 100, usually Air containing harmful substances generated from facilities such as external soldering facilities has a temperature of 110° C. when introduced into the inlet 200. At this time, when the cooling fan 900 is driven to cool the first electric dust collecting part 300 or the second electric dust collecting part 400, the first electric dust collecting part 300 or the second electric dust collecting part 400 ) Evaporation occurs inside and the condensation temperature is lowered to 70 ℃ ~ 80 ℃, making it easy for harmful particles in the air to become heavy and stick to the inner surface of the first dust collection pipe 320 or the second dust collection pipe 420 This makes it possible to increase the dust collection efficiency through air cooling.

On the other hand, in order to remove harmful substances such as flux adhered to the inner surface of the first dust collection pipe 320 or the second dust collection pipe 420, as shown in FIG. 9 in one embodiment, the washing liquid is stored. The cleaning solution is sprayed through the cleaning equipment 1000 including the cleaning solution reservoir 1010 and the spray nozzle 1020 through which the cleaning solution is sprayed to remove harmful substances such as flux. As shown, a driving unit 1110 such as a motor, a rotating shaft 1120 connected to the driving unit 1110, and connected to the rotating shaft 1120, the first dust collecting pipe 320 or the second dust collecting pipe 420 ) Scrape the inner surface of the first dust collection pipe 320 or the second dust collection pipe 420 through the scraper equipment 1100 including the scraper bar 1130 in close contact with the inner surface of the flux. material can be released.

At this time, a drain pipe 830 connected to the first electric dust collecting part 300 or the second electric dust collecting part 400 is connected to the lower part of the housing 100 to extract harmful substances such as flux to the outside. It is desirable to form

Hereinafter, FIGS. 12 to 16 measure the current used in the electric precipitator through an oscilloscope to explain the power consumed, the implied power, and the like, and explain the technical effects of the present invention through this.

First, FIG. 12 is a diagram illustrating a picture of measuring dc pulse power (DPP) current of a supply voltage of 17.5k DC and 10us (100Khz).

As shown in FIG. 12, a power pulse of 17,500v may be supplied in the form of direct current to the electric precipitator.

Pulse power of 17,500v supplied in the form of direct current can be output in a form in which force condensation and power dissipation for a certain period are periodically repeated in the electric precipitator.

This is disclosed through FIG. 13 .

13 is a diagram for explaining time off and time on pictures of DPP (dc pulse power).

As shown in FIG. 13, the measurement signal displayed on the oscilloscope shows a form in which a section of time off, which is a section in which force is implied for a certain period of time, and a section of time on, which is a section in which implied power is diverged, are periodically repeated. .

As shown on the oscilloscope, the period in which the force is implied appears as a time-off period of 7.40us for the entire period of 10.0us, and the period in which the implied force is dissipated is measured as a time-on period of 2.60us during the current period of 10.0us. do.

This means a pattern in which force is dissipated only in about 1/4 of the entire cycle and force is implied in the remaining 3/4, indicating that efficient power use is possible through this pattern.

14 is a diagram illustrating a current value when power is dissipated.

The current dissipated during the actual time on section can be calculated through [Equation 2] below.

[Electrical formula 2]

Current value when pulse power is emitted (time on) = pulse measurement voltage/resistance

Looking more specifically, the current value dissipated in the time on section measured by the oscilloscope is 2.7v, and the resistance used at this time is measured as 100 ohm. Therefore, the current value obtained by dividing 2.7v by 100 ohms can be calculated as 27mA.

In general, in the case of a simple needle-shaped nozzle, a current of 10 to 100 uA is output, whereas the current value measured by the electric precipitator according to the present invention is 27 mA, which is 500 times or more of the above value.

As a result, the present invention can significantly improve dust collection efficiency.

15 is a diagram explaining pulse power generation time as implied force divergence time.

As shown in FIG. 15, as a result of precisely measuring the implied force divergence time of the power pulse measured from the waveform generated by adjusting the vertical cursor of the oscilloscope, it can be confirmed that it is measured for approximately 2.6 us, not less than 2 us.

16 is a diagram showing expected power and actually consumed power in normal conditions.

The required power can be calculated as [Equation 3] below.

[Electric formula 3]

P=EI (Where P is required power, E is pressure voltage, and I is required current)

More specifically, according to the previous measurement, a power of 470 watts should be consumed through a voltage of 17,500v and a current consumption of 27mA.

However, in reality, since power is consumed only when the power is dissipated in the time on section, not in the time off section in which power is implied, it can be confirmed that only 86w is consumed, as shown in the electricity rate meter of FIG. 16.

Therefore, while the total power actually used through the present invention is 86 watts, the instantaneous output must be 470 watts. Therefore, the desired power cannot be generated using the existing domestic 18KDC, 7.5mA power supply, so the existing power supply cannot discharge. can solve the problem That is, it proves that this device is a pulse power.

FIG. 17 is a diagram showing a general needle-like corona current waveform and a time interval between pulses according to the strength of an electric field.

As shown in FIG. 17, the time of time on and time off of the waveform pattern of the existing general acicular nozzle is quite long.

The waveform shown in FIG. 17 is a waveform of a conventional needle-type corona current, and shows that the pulse does not bounce in the middle, but the peak current is very low at most of 10mA.

In addition, the corona current is a conventional simple needle-shaped nozzle, which generally appears in the range of 10 to 100us, and the present invention has a current voltage with power inclusion of 27 to 35mA, as shown in the above experimental data.

On the other hand, as shown in FIG. 18, the time interval of the corona pulse of the existing general acicular nozzle is in the range of about 38 to 180 us.

That is, the waveform time of the conventional needle-type nozzle is 38 to 180 us, but the time of the present invention is 10 us, which has a pulse of 5 times the power.

As a result, the use of the present invention has the advantage of showing a pulse of 5 times the implied force for 1/18 to 1/4 of the time compared to the waveform of the normal needle nozzle, and the current with superior power content compared to the waveform of the normal needle nozzle voltage can be displayed.

Therefore, when the present invention is used, power cost reduction and dust collection capability can be significantly improved compared to conventional electric dust collectors.

Optimal embodiments have been disclosed in the drawings and specifications. Although specific terms have been used herein, they are only used for the purpose of describing the present invention and are not used to limit the scope of the present invention described in the claims or defining the meaning. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

1: Electric dust collector equipped with radial dust collection needles
100: housing
200: inlet
300: first electric dust collector
310: first connector 320: first dust collector
330: first electricity application unit 331: first transmission shaft
332: transmission disc 333: second transmission shaft
340: second electricity application unit 341: support plate
342: third transmission shaft
350: second connector
400: second electric dust collector
410: third connector 420: second dust collector
430: third electricity application unit 431: first transmission shaft
432: transmission disc 433: second transmission shaft
440: fourth electricity application unit 441: support plate
450: fourth connector
500: outlet
600: radial dust collection needle 601: coupling hole
610: first triangular discharge unit 611, 631: curved radial projection
620: through hole 630: second triangular discharge unit
700: spacing pin
810: sealing cover
820: pedestal 821: through hole
830: drain pipe
900: cooling fan
1000: washing equipment 1010: washing liquid reservoir
1020: injection nozzle
1100: scraper equipment 1110: driving unit
1120: rotation axis 1130: scraper bar

Claims (15)

housing 100;
An inlet 200 formed inside the housing 100 and through which air containing harmful substances such as flux is introduced;
The first connection pipe 310 formed inside the housing 100 and connected to the inlet 200 and the primary dust collection of air containing harmful substances introduced through the first connection pipe 310 A first dust collecting pipe 320 formed inside the dust collecting pipe 320, and a first electricity application unit 330 to which electricity of the (+) pole supplied from the outside is applied, and the dust collecting pipe A second electric application unit 340 formed from the lower side of the 320 to the inside and to which electricity of the (-) polarity supplied from the outside is separately applied without interfering with the first electricity application unit 330; 1 first electrostatic precipitator 300 in which a plurality of star-shaped dust collecting needles 600 and a second connection pipe 350 are formed in a star-shaped form with a hole through the center coupled to the electricity applying unit 330 in a spaced apart state; and
An outlet 500 formed inside the housing 100 and connected to the second connection pipe 350 to discharge purified air after dust collection is completed;
The radial dust collection needles 600,
The first triangular discharge portion 610 in a triangular shape is continuously connected to the outer surface in an outward direction,
A through hole 620 is perforated at the center of the inside,
An electric dust collector (1) equipped with radial dust collecting needles, characterized in that formed by continuously connecting the second triangular discharge portion 630 in a triangular shape in an inward direction to the inner surface of the through hole 620. housing 100;
An inlet 200 formed inside the housing 100 and through which air containing harmful substances such as flux is introduced;
The first connection pipe 310 formed inside the housing 100 and connected to the inlet 200 and the primary dust collection of air containing harmful substances introduced through the first connection pipe 310 A first dust collecting pipe 320 formed inside the dust collecting pipe 320, and a first electricity application unit 330 to which electricity of the (+) pole supplied from the outside is applied, and the dust collecting pipe A second electric application unit 340 formed from the lower side of the 320 to the inside and to which electricity of the (-) polarity supplied from the outside is separately applied without interfering with the first electricity application unit 330; 1 first electrostatic precipitator 300 in which a plurality of star-shaped dust collecting needles 600 and a second connection pipe 350 are formed in a star-shaped form with a hole through the center coupled to the electricity applying unit 330 in a spaced apart state;
The third connection pipe 410 formed inside the housing 100 and connected to the second connection pipe 350, and the secondary dust collection of the air primarily collected through the third connection pipe 410 A second dust collection pipe 420 formed from the upper side of the second dust collection pipe 420 to the inside and a third electricity application unit 430 to which electricity of the (+) pole supplied from the outside is applied, A fourth electric application unit 440 formed from the lower side of the second dust collector 420 to the inside and applied with (-) polarity electricity separately supplied from the outside without interfering with the third electricity application unit 430 And, a star-shaped radial dust collecting needle 600 with a central hole coupled to the third electricity applying part 430 in a spaced apart state and a fourth connection pipe 450 are formed. A second electric dust collecting unit (400); and
An outlet 500 formed inside the housing 100 and connected to the fourth connection pipe 450 to discharge purified air after dust collection is completed;
The radial dust collection needles 600,
The first triangular discharge portion 610 in a triangular shape is continuously connected to the outer surface in an outward direction,
A through hole 620 is perforated at the center of the inside,
An electric dust collector (1) equipped with radial dust collecting needles, characterized in that formed by continuously connecting the second triangular discharge portion 630 in a triangular shape in an inward direction to the inner surface of the through hole 620. delete According to any one of claims 1 or 2,
The first triangular discharge unit 610 and the second triangular discharge unit 630 are each formed in an isosceles triangle shape. According to claim 4,
The electric dust collector (1) equipped with radial dust collecting needles, characterized in that the basic angle (G1) of the first triangular discharge part (610) is formed larger than the basic angle (G2) of the second triangular discharge part (630). According to any one of claims 1 or 2,
An electric dust collector equipped with radial dust collecting needles, characterized in that curved surface radial projections 611 and 631 formed of curved surfaces are formed at the vertices of the first triangular discharge part 610 and the second triangular discharge part 630, respectively ( One). According to any one of claims 1 or 2,
The first electricity applying unit 330,
A first transmission shaft 331 provided on the upper side of the first dust collection pipe 320 and through which electricity of a (+) pole is transmitted;
A transmission disk 332 located inside the first dust collection pipe 320 and formed in a disk shape and coupled to the lower portion of the first transmission shaft 331;
The upper portion is formed of a plurality of second transmission shafts 333 coupled to the transmission disc 332,
An electric dust collecting device (1) equipped with radial dust collecting needles, characterized in that the radial dust collecting needles (600) are coupled to the second transmission shaft (333). According to claim 7,
The second electricity applying unit 340,
A support plate 341 provided on the lower side of the first dust collection pipe 320,
In a state of being coupled to the center of the support plate 341 and spaced apart from the radial dust collection needles 600 through the center of the radial dust collection needles 600 located inside the first dust collection pipe 320 (- ) Electrostatic precipitator (1) equipped with radial dust collecting needles, characterized in that formed by the third transmission shaft 342 through which the electricity of the pole is transmitted. According to claim 7,
In the radial dust collection needles 600,
A plurality of coupling holes 601 are formed through holes so that the radial dust collecting needles 600 can be inserted into and coupled to the second transmission shaft 333,
A space holding pin ( 700) is provided with radial dust collecting needles characterized in that the electric dust collector (1). According to claim 8
An airtight cover 810 made of an insulating material coupled to the first transmission shaft 331 is formed on the upper side of the first dust collection pipe 320,
A pedestal 820 made of an insulating material coupled to the second transmission shaft 333 is formed on the lower side of the first dust collection pipe 320,
The pedestal 820 and the support plate 341 are spaced apart by a predetermined distance,
Electrostatic precipitator (1) equipped with radial dust collecting needles, characterized in that a through hole 821 is formed in the center of the pedestal 820 so that the third transmission shaft 342 passes through. According to claim 7,
The third electric dust collector (1) with radial dust collecting needles, characterized in that the third electricity applying unit 430 is made of the same structure as the first electricity applying unit 330. According to claim 8,
The fourth electric dust collector (1) with radial dust collecting needles, characterized in that the fourth electricity applying unit 440 is made of the same structure as the second electricity applying unit 340. According to any one of claims 1 or 2,
An electric dust collector (1) with radial dust collectors, characterized in that a plurality of cooling fans (900) for cooling the first electric dust collector (300) are formed on the side surface of the housing (100). According to any one of claims 1 or 2,
It is installed on the upper part of the first electrostatic precipitator 300 and the cleaning equipment 1000 is further provided to spray and desorb the flux adhered to the inner surface of the first electrostatic precipitator 300 by spraying a washing liquid. An electric dust collector (1) equipped with radial dust collection needles. According to any one of claims 1 or 2,
Radial dust collection characterized in that the scraper equipment 1100 installed inside the first electric dust collector 300 to scrape and desorb the flux adhered to the inner surface of the first electric dust collector 300 is further provided Electrostatic precipitator (1) equipped with a needle.

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