CN1274422C - Electric dusting equipment - Google Patents

Abstract

Provided is a rectangular wave electric dust collector whose dust collecting rate is kept high even when the frequency of the voltage to be impressed onto a dust collecting part of this collector is made low, namely, the capacitance of a power source is made small. The rectangular wave electric dust collector comprises an electrifying part(40) and a dust collecting part(50). The electrifying part(40) has a pair of plate-shaped grounded electrodes(21,22) and a wire-shaped high-voltage electrode(23) for generating a corona discharge. The part(50) has a parallel plate-shaped electrode structure, namely, a pair of plate-shaped grounded electrodes(31,32) and one plate-shaped high-voltage electrode(33). Rectangular-wave high voltage is impressed between the high-voltage electrodes(23,33) from a rectangular-wave high-voltage power source(60). As a result, an electrostatic field is generated in the part(50), a suspended particle-containing gas stream passing through the part(50) is charged and the suspended particles are collected on the electrodes(31,32) by the electrostatic field in the part(50).

Description

Electric dust collector

Technical field

The present invention relates to a kind of high pressure generating unit of using air in the square waveform ac high-voltage cleaning tunnel.

Background technology

As everyone knows, when the pernicious gas in the automobile exhaust and cigarette charcoal and running car the wearing and tearing of tire or pavement asphalt cause the floating dust of submicron order, the air of vehicular traffic lane in the tunnel is polluted in the capital, thereby for airborne these flue dust of pollution abatement, will use a kind of air cleaner equipment, this equipment has been used a kind of twin-stage type electric dust collector, comprises live part and dust collecting port.

Figure 20 illustrates the structure of common twin-stage type electric dust collector.Electric dust collector 100 among Figure 20 comprises charging part 1 and dust collecting port 2.Charging part 1 is equipped with a kind of " straight line 4 and plate electrode 3a, 3b " structure, adds high direct voltage between electrode, just produces corona discharge.Dust collecting port 2 is equipped with a kind of parallel plate electrode structure 5a, and 5b and 6 adds high direct voltage between parallel plate electrode, form an electrostatic field.In the conventional twin-stage type electric dust collector of said structure, grit charges with unipolarity in charging part 1, and is captured on dust suction electrode 5a and the 5b by the electrostatic field of dust collecting port 2.

Twin-stage type electric dust collector has also been equipped high dust-absorbing rate, the flow velocity that suitable treatment is big to nanometer (sub-micron) grit.

But when contained low resistance carbon granules etc. becomes the main floating grain composition of vehicular traffic lane in the tunnel, just have such a case, the grit that wherein captures on the dust suction electrode scatters again, and discharges in electric dust collector with air-flow.This phenomenon is called the phenomenon of scattering again.When occurring scattering phenomenon again, owing to obviously reduced the dust-absorbing rate of coarsegrain grit, so the phenomenon of scattering has again proposed a major issue that haves much room for improvement.

The key diagram of Figure 21 shows the mechanism of the above-mentioned phenomenon of scattering again.With single negative polarity charging, the phenomenon mechanism of scattering again of this moment is as follows in charging part for grit.

At first shown in Figure 21 (A), be captured on the dust collecting port earth electrode 8 at the grit 9 of charging part with the negative polarity charging, carbon granules 9 on the grounding electrode plate that is hunted down 8 loses electric charge immediately, and its polarity is the same with earth electrode, thereby near the electric field of catching on the earth electrode 8 grit is strengthened.Shown in Figure 21 (B), when being drawn onto on the earth electrode 8 with the grit of negative polarity charging in the air-flow, it with earth electrode 8 on grit 10 flocculations, utilize the moniliform grit of Coulomb force formation rose urceolus along the negative polarity electrode direction by electric field.Along with this moniliform grit flocculates block (seeing Figure 21 (c)), the peeling force of fluid resistance and Coulomb force is enhanced, and when these power became greater than the adhesion between earth electrode and moniliform grit, grit just scattered again.

Method as a kind of phenomenon that extremely effectively prevents to scatter again once proposed a kind of electric dust collector of using the ac high-voltage of rectangle.

Figure 22 illustrates the brief configuration of the electric dust collector of using the square waveform alternating voltage.This equipment comprises charging part 40 and dust collecting port 50, and the former constitutes straight line to the plate electrode structure, comprises as the earth electrode 21 of pair of plates and 22 and form rectilinear high-field electrode 23.High voltage source 20 applies high direct voltage between earth electrode 21 and 22 is with high-field electrode 23, produce corona discharge in charging part 40.The polarity of high direct voltage or plus or minus, this high pressure can be pulse voltages.

Dust collecting port 50 constitutes the parallel plate electrode structures, comprises as the earth electrode 31 of pair of plates and 32 and as the high-field electrode 33 of one flat plate.Ac high voltage source 30 applies the ac high-voltage of square waveform between earth electrode 31 and 32 is with high-field electrode 33.If without ac high voltage source 30, can use the ac high voltage source that produces the sinusoidal waveform ac high-voltage.

The voltage range of this class ac voltage power supply, every 1mm is spaced apart and is equal to or less than 3kv between electrode, is generally the about 0.9kV of every 1mm.In addition, the frequency range that applies voltage is several HZ～several KHZ.But problem is that frequency is high more, and the power supply capacity of requirement is big more.Otherwise, when frequency is turned down, then have the problem of scattering again and the coarsegrain grit being reduced dust-absorbing rate that produces.

Summary of the invention

The present invention can solve above-mentioned all problems, thereby an object of the present invention is to provide a kind of electric dust collector, even reduced the frequency of the ac high-voltage that is added to dust collecting port, in other words, even reduced power supply capacity, this equipment also can keep high dust-absorbing rate.

And the electric dust collector that another purpose of the present invention is provided, can be when using the ac high-voltage of square waveform, can realize high dust-absorbing rate, have the dv/dt voltage change ratio value (lifting that is square waveform is tilted) of essential minimum again, can also simplify power-supply device and cable.

The electric dust collector that is provided of another purpose of the present invention scatters by preventing effectively again, can realize high dust-absorbing rate with low cost.

For realizing these purposes, the electric dust collector that first aspect of the present invention proposes comprises: be configured to the corona discharge type charging part to aerial floating dust charging; Be positioned at the dust collecting port that the charging part downstream is configured to absorb charged grit, wherein the corona discharge type charging part comprises a direct current high pressure generating unit, be configured to grit be charged to applying high direct voltage between its electrode, and dust collecting port wherein comprises an ac high-voltage generating unit, and the square waveform ac high-voltage that is configured to apply frequency and is 0.1HZ～2HZ between its electrode is realized dust suction.

The electric dust collector that second aspect present invention provided comprises: be configured to the corona discharge type charging part to aerial floating dust charging; Be positioned at the dust collecting port that the charging part downstream is configured to absorb charged grit, wherein charging part comprises a direct current high pressure generating unit, be configured between its electrode, apply high direct voltage and grit is charged, and dust collecting port wherein comprises an ac high-voltage generating unit, is configured to apply the square waveform ac high-voltage of voltage change ratio dv/dt in 50～2000V/msec to realize dust suction between its electrode.

The electric dust collector that third aspect of the present invention provided comprises: be configured to the corona discharge type charging part to aerial floating dust charging; Be positioned at the dust collecting port that the charging part downstream absorbs charged grit, wherein charging part comprises an ac high-voltage generating unit, be configured between its electrode, apply ac high-voltage and grit is charged, and dust collecting port wherein comprises an ac high-voltage generating unit, is configured to apply ac high-voltage between its electrode and realizes dust suction.

Description of drawings

By detailed description below in conjunction with accompanying drawing, can more fully understand all purposes of the present invention and advantage,

Wherein:

Fig. 1 is the cutaway view of the electric dust collector of first embodiment of the invention.

Fig. 2 is illustrated in and catches charged grit in the dust collecting port shown in Figure 1 and prevent the model that it scatters again.

Fig. 3 illustrates the HT waveform that is added to dust collecting port.

Fig. 4 illustrates the frequency characteristic (add straight line (DC), add the frequency of 0.001HZ～1HZ) that the dust-absorbing rate that provides is provided.

Fig. 5 illustrates the frequency characteristic (add straight line (DC), add the frequency of 0.01HZ～1HZ) of the dust-absorbing rate that this experiment provides.

Fig. 6 illustrates the frequency characteristic of the dust-absorbing rate that another test provides, and (frequency is 0.1HZ～10HZ).

The frequency characteristic of the dust-absorbing rate when Fig. 7 illustrates dust collecting port added the sinusoidal waveform ac high-voltage.

Fig. 8 illustrates the grit mode under each frequency.

Fig. 9 is the sectional structure of the electric dust collector of second embodiment of the invention.

Figure 10 illustrates the voltage waveform that is added to dust collecting port shown in Figure 9.

Figure 11 is illustrated in direct current drive dust collection equipment and the square waveform AC electrical dust collection equipment, the relation between dust-absorbing rate and the dv/dt tolerance Dh.

Figure 12 is the block diagram of the employed equipment of experiment.

Figure 13 illustrates the electrode structure of electric dust collector among second embodiment.

Figure 14 illustrates ducted electrode configuration.

Figure 15 illustrates the influence of dv/dt to the dust-absorbing rate particle property.

Figure 16 is the sectional structure that the electric dust collector of third embodiment of the invention is shown.

Figure 17 is the sectional structure chart that the electric dust collector of fourth embodiment of the invention is shown.

Figure 18 illustrates the various electrode structures of charging part.

Figure 19 illustrates various general electrode shapes.

Figure 20 illustrates the general known structure of ambipolar electric dust collector.

Figure 21 shows the mechanism of the bright phenomenon of scattering again.

Figure 22 illustrates the brief configuration of the electric dust collector of using the square waveform alternating voltage.

The specific embodiment

Referring now to accompanying drawing in detail all preferred embodiments of the present invention are described in detail.

First embodiment

Fig. 1 is the sectional structure of the electric dust collector of first embodiment of the invention.

This electric dust collector comprises charging part 40 and dust collecting port 50.Charging part 40 has a straight line to the plate electrode structure, comprises as the earth electrode 21 of pair of plates and 22 and linear high-field electrode 23.High voltage source 20 applies high direct voltage between earth electrode 21 and 22 is with high-tension electricity 23, produce corona discharge in charging part 40.The polarity of high direct voltage or plus or minus, voltage can be pulse voltages.

Dust collecting port 50 has the parallel plate electrode structure, comprises as the earth electrode 31 of pair of plates and 32 and as the high-field electrode 33 of one flat plate.Ac high voltage source 60 applies ac high-voltage between earth electrode 31 and 32 is with high-field electrode 33 (frequency is 0.1～2HZ), produces the ac high-voltage of square waveform.Apply this high pressure, produce electrostatic field at dust collecting port 50.Contain the floating dust air communication and overcharge portion 40 and charged, floating dust is captured on the dust suction electrode by the electrostatic field of dust collecting port 50.

Prevent the mechanism of scattering again when then dust collecting port 50 being applied ac high-voltage with reference to Fig. 2 and Fig. 3 explanation.Fig. 2 illustrates dust collecting port 50 and absorbs charged grit and prevent the model that it scatters again.Here, charging part 40 (see figure 1)s are added with negative direct current high voltage, and grit is electronegative.Fig. 3 illustrates the ac high-voltage waveform that is added to dust collecting port 50.

Among Fig. 3, the voltage that is added to dust collecting port 50 is divided into three sections, the A section is the zone that dust collecting port 50 is added positive high voltage, and the B section is to be added to the voltage of dust collecting port 50 by just becoming negative transition zone (several milliseconds), and the C section is the zone that dust collecting port 50 is added negative high voltage.In the A section, the negative electricity grit of charging part 40 is captured on the positive polarity high pressure dust-absorbing battery lead plate (sees Fig. 2 (a)), and dust suction just is charged as immediately, forms the beads grit of rose urceolus.Afterwards in the B section, polarity of voltage negative by becoming just rapidly (seeing Fig. 2 (b)).Because dust suction battery lead plate polarity, is flocculated into the rose urceolus by becoming negative just rapidly on the battery lead plate grit is subjected to the influence of electrostatic force along dust suction battery lead plate direction, becomes spherical flocculation grit.Like this, by becoming spherical flocculation grit, reduced to play the wind-force or the electrostatic force of peeling force effect, (seeing Fig. 2 (c)) can not occur scattering again.

First experiment

The frequency characteristic (add straight line (DC), add the square waveform voltage of 0.001～1HZ frequently) of first dust-absorbing rate that provide of experiment is provided Figure 4 and 5.As experiment condition, wind speed is made as 5m/s, and dust collecting port 50 length are 206mm, and charging voltage is 11kv, and dust suction voltage is ± the 5kV square wave that the interelectrode distance of dust collecting port 50 is 6mm.Granularity is that first result of experiment of 0.3 μ m～0.5 μ m is shown in Fig. 4 (A), granularity is that first result of experiment of 0.5 μ m～1 μ m is shown in Fig. 4 (B), granularity is that first result of experiment of 1 μ m～2 μ m is shown in Fig. 5 (A), and granularity is that first result of experiment of 2 μ m～5 μ m is shown in Fig. 5 (B).

According to experimental result, under any granularity, frequency is high more, and dust-absorbing rate increases many more, especially demonstrates the highest dust-absorbing rate under 0.1～1HZ frequency.

Second experiment

The frequency characteristic (when the square waveform frequency is 0.1～10HZ) of second dust-absorbing rate that provide of experiment is provided Fig. 6.As experiment condition, wind speed is 7m/s, temperature is 13 ℃, and humidity is 25%, and atmospheric pressure is 1031hpa, charging part is made up of 1 unit, dust collecting port is made up of 2 unit of 206mm, and charging voltage is 11kv, and dust suction voltage is ± the 7.5kV square wave, the interelectrode distance of dust collecting port 50 is 9mm, and the time cycle of operation dust collecting port is 30 minutes.

According to experimental result, under any frequency, it is maximum that dust-absorbing rate is tending towards when granularity is 0.5 μ m～2 μ m.When frequency is 0.1HZ and 1HZ, form high dust-absorbing rate when comparable 4HZ and 10HZ in addition.

As mentioned above, so to say that the optimum frequency scope of this electric dust collector is 0.1～2HZ.

With reference to experiment

As reference, the frequency characteristic of the dust-absorbing rate when Fig. 7 illustrates dust collecting port 50 applied the sinusoidal waveform ac high-voltage.Among Fig. 7, Fig. 7 (A) illustrates the situation that granularity is 0.3 μ m～0.5 μ m, and Fig. 7 (B) illustrates the situation that granularity is 2 μ m～5 μ m.As experiment condition, wind speed is 5m/s, dust collecting port 50 long 206mm, and charging voltage is direct current 11kv, and dust suction voltage is 5kVrms, and sinusoidal waveform exchanges, and frequency range is 25～100HZ, the interelectrode distance of dust collecting port is 6mm.According to experimental result, frequency is high more, and dust-absorbing rate is low more.Its reason is (the grit mode under each frequency) as shown in Figure 8, because the frequency height, the space of charged grit between electrode of inflow dust collecting port 50 is captured and discharges, and is not captured on the dust suction electrode.

As mentioned above, according to the electric dust collector of first embodiment,, can realize high dust-absorbing rate by preventing from effectively to scatter again with little power supply capacity.In other words, can select for use optimum frequency to keep high dust-absorbing rate under the low frequency (small power supply capacity).

Second embodiment

Can infer, big more corresponding to the voltage change ratio dv/dt of the variation voltage ramp of B section among Fig. 3 in rectangular voltage waveform, then can limit more and scatter again, and keep higher dust-absorbing rate.But problem is, voltage change ratio dv/dt is high more, and the induced electricity flow valuve just increases manyly more, thereby requires to increase the electric current resistance of inner certain parts of high-voltage power-supply unit, and for same reason, also proposed the problem that cable dimension thickens.When selecting the voltage change ratio dv/dt value of optimizing, become important practical problem.

In this respect, will describe the electric dust collector of second embodiment of the invention below, this equipment had both been realized high dust-absorbing rate when using the square waveform ac high-voltage, have essential minimum voltage rate of change dv/dt value again, can also simplify power-supply device and cable.

Fig. 9 is the sectional structure of the electric dust collector of second embodiment of the invention.

The electric dust collector of second embodiment comprises charging part 40 and dust collecting port 50, and the former has straight line to the plate electrode structure, comprises as the earth electrode 21 of pair of plates and 22 and linear high-field electrode 23.High voltage source 20 applies high direct voltage between earth electrode 21 and 22 is with high-field electrode 23, produce corona discharge in charging part 40.The polarity of high direct voltage or plus or minus, voltage can be pulse voltages.

Dust collecting port 50 has parallel plate structure, comprises as the earth electrode 31 of pair of plates and 32 and the high-field electrode 33 of one flat plate form.Ac high voltage source 70 applies ac high-voltage (trapezoidal waveform high pressure) between earth electrode 31 and 32 is with high-field electrode 33, produce the ac high-voltage of square waveform.

The frequency of this ac high-voltage (trapezoidal waveform high pressure) is equal to or less than several KHZ, and the rate of change dv/dt of last lower edge is 50～2000V/msec.Contain the floating dust air communication and overcharge portion 40 and charged, floating dust is captured to the earth electrode 31 of dust collecting port 50 on 32 (dust suction electrodes).

Theoretical research

The following describes the theoretical dust-absorbing rate of the electric dust collector of second embodiment.

Formula is so-called " Deutscn equation ", is the dust-absorbing rate computing formula of this routine electric dust collector:

η _t={ 1-exp (α V _D) * 100[%] (formula 1)

Here, V parameter _DRefer to be added to the straight line voltage (V) of dust collecting port, parameter a refers to proportionality coefficient.Work as parameter N _iDensity of dust [grit/the m that refers to the electric dust collector inlet ³] time, then the density of dust No of its outlet is provided by formula (2):

N _o=N _iExp (α V _D) [grit/m ³] (formula 2)

When the alternating voltage waveform that is added to dust collecting port is defined as when shown in Figure 10, then the electric dust collector outlet side is at the density of dust N of moment t1 _Ot1As shown in Equation (3):

N _Ot1=N _iExp (α V) [grit/m ³] (formula 3)

Simultaneously, the electric dust collector outlet side is at the average density of dust N of moment t2 _Ot2As shown in Equation (4):

(formula 4)

Therefore, the electric dust collector outlet side is at the average density of dust N of moment t _OtShown in formula (S):

(formula 5)

Like this, the dust-absorbing rate η of electric dust collector _AAs shown in Equation (6):

${\mathrm{\η}}_A=\{1-\frac{t_1}{t}\exp (-\mathrm{\αV})-\frac{t_2}{t}\exp (-\mathrm{\α}\frac{V}{2})\}\×100[\%]$ (formula 6)

So, the dust-absorbing rate η when adding direct current _DDust-absorbing rate η when adding the square waveform ac high-voltage _ADifference Δ η as shown in Equation (7):

$\mathrm{\Δ\η}={\mathrm{\η}}_D-{\mathrm{\η}}_A$

$=\frac{t_2}{t}\{\exp (-\mathrm{\αV})+\exp (-\mathrm{\α}\frac{V}{2})\}\×100[\%]$ (formula 7)

Supposed DC voltage V above _DEqual the absolute value of square waveform ac high-voltage | V|.

Relation between dv/dt and the t2/t is as shown in Equation (8):

$\frac{\mathrm{dV}}{\mathrm{dt}}=\frac{2V}{t}\frac{t}{t_2}$ (formula 8)

Draw following formula (formula (9)) by formula (7) and (8):

$\frac{\mathrm{dV}}{\mathrm{dt}}=\frac{2\mathrm{<figure-callout\; id="1"\; label="V\; t"\; filenames="C0315300500151.png,C0315300500161.png"\; state="\{\{state\}\}">V</figure-callout>}}{t}\frac{1}{\mathrm{\&Delta;\&eta;}}\{\exp (-\mathrm{\&alpha;V})+\exp (-\mathrm{\&alpha;}\frac{V}{2})\}\&times;100[\%]$ (formula 9)

Utilize formula (9), can calculate the dust-absorbing rate η of direct current drive dust collection equipment in theory _DDust-absorbing rate η with the AC electrical dust collection equipment _AThe necessary dv/dt of tolerance Δ η.

Figure 11 has gone out the tolerance Δ η that calculated by formula (9) and the relation of dv/dt in addition.According to result of calculation, make tolerance Δ η drop on the interior necessary dv/dt of 1%～15% scope and list in table 1, generally become about 50～2000v/msec.

Table 1

The direct current dust-absorbing rate	The dV/dt that ac square wave is essential
		70	167

80	129
		90	83
95	55

The dV/dt value that tolerance Δ η＜15% is required

Figure 12 is the block diagram of experimental facilities.In the experiment, as by the grit of the sample of holding concurrently, used diesel engine exhaust to pick up with arm 71 after, mix with atmosphere and dilute 72 li of mixing channels, the gas of dilution is sent into pipeline by air blast 73, again the atmospheric dilution that has sucked with air inlet.Gas is handled by ESP (electrostatic precipitator) 74 and is passed through outside induced-draught fan 75 discharge lines.Utilize the revolution of induced-draught fan 75 that the flow velocity in the pipeline is set at 7m/s.In the pipeline of electric dust collector equipment between air blast 73 and ESP74 of second embodiment, at this moment, all interelectrode flow velocitys of dust collecting port become about 9m/s.

Figure 13 illustrates the charging part of above-mentioned test use and the concise and to the point electrode structure of dust collecting port.The board joint ground electrode of charging part (shown in Figure 13 (A)) is made of aluminum, and the lead electrode diameter is that the aluminum of 0.26mm is done, and is used to apply high pressure.In charging part, line up 5 grade and 3 grade of serial parallel by the charging space of pair of electrodes configuration, thereby it there are 15 charging spaces with air-flow.As dust collecting port (shown in Figure 13 (B)), the plate electrode of ground connection and apply plate electrode that high pressure does with unidimensional aluminum with the alternately arrangement of 9mm spacing.

Figure 14 illustrates the arrangement of each electrode in the pipeline.As shown in the figure, charging part 40 and dust collecting port 50 are settled along the airflow direction serial.Dust collecting port 50 is positioned at the downstream of charging part 40.The added voltage of charging part is negative polarity direct current 11kV, and the added voltage of dust collecting port is square waveform interchange ± 7.5kV.The frequency of square waveform (trapezoidal waveform) ac high-voltage is 1HZ, and dv/dt is 46～646V/msec.In other words, charging part 40 is by negative corona discharge and electronegative grit is drawn onto on earth electrode and the high-voltage flat plate electrode by the square waveform AC field of dust collecting port 50.

Figure 15 illustrates the dependence of dv/dt to the dust-absorbing rate particle property.As experiment condition, wind speed is 7m/s, and temperature is 15.5 ℃, and humidity is 35%, atmospheric pressure is 1032hpa, charging part is made of 1 unit, and dust collecting port is made of 4 unit, the long 208mm in each unit, charging voltage is 11kV, dust suction voltage is ± the 7.5kV square waveform, and dust collecting port 50 interelectrode distances are 9mm, and the time cycle of operation dust collecting port is 20 minutes.

For making comparisons, also show the result's (add-the 7.5kV DC voltage, dust-absorbing rate is about 70%) who dust collecting port is added high direct voltage among the figure.When granularity was 0.3 μ m～1 μ m, for dust-absorbing rate, dv/dt was big more, and dust-absorbing rate increases manyly more.As dv/dt=433V/msec or when higher, dust-absorbing rate is equivalent to add the situation of direct current basically.Simultaneously, granularity is 1 μ m or when bigger, compares with adding the direct current situation, and dust-absorbing rate all has high value under any dv/dt.

The experimental result of Figure 15 does not conform to the result of calculation of Figure 11, because when any granularity, the dust-absorbing rate that adds direct current has been reduced by the phenomenon of scattering again.

According to The above results, the dv/dt of ac high-voltage waveform can be said to be and be equal to or higher than 50V/msec in the electric dust collector.Moreover, when dv/dt is equal to or higher than about 400V/msec, can realize being equal to or higher than the dust-absorbing rate that adds direct current.Therefore, when the dv/dt of the ac high-voltage of square waveform drops in 50～2000V/msec scope, just can realize it being enough high dust-absorbing rate.

As mentioned above, according to this example, by necessary minimum voltage rate of change dv/dt value is set, on behalf of the lifting of rectangle, it tilt, and just can realize high function.According to this example,, can simplify power-supply device and reduce cable thickness in addition with the viewpoint of operation.

The 3rd embodiment

Figure 16 illustrates the electric dust collector of third embodiment of the invention.

The electrode structure of charging part 40 and dust collecting port 50 and Fig. 1's is similar, so no longer describe in detail.

In Figure 16 situation, the voltage that is added to charging part 40 is formed (ac high-voltage that is sinusoidal waveform or rectangle) by ac high-voltage.

Ac high-voltage is added between the linear electric motors 23 and plate electrode 21 and 22 of charging part 40.As ac high-voltage, not only can use sine-shaped ac high-voltage, also can use the ac high-voltage of square waveform.Therefore according to this example, can select the output waveform of ac high voltage source 80 arbitrarily.Equally, not only can select sine-shaped ac high-voltage for use, also can select the ac high-voltage of square waveform for use the output waveform of the ac high voltage source 90 of dust collecting port 50.

The 4th embodiment

Figure 17 illustrates the electric dust collector of fourth embodiment of the invention.According to this example, ac high voltage source 80 is that charging part 40 and dust collecting port 50 are shared, but applies the same simpler system of ac high-voltage body plan.

Also can select the output waveform of ac high voltage source 80 shown in Figure 17 arbitrarily for use,, can use ac high-voltages such as square wave, sine wave promptly as ac high-voltage.

According to the embodiment of Figure 16 and 17, charging part 40 is added ac high-voltage, thereby alternately produce positive negative corona discharge.Therefore, utilize the AC corona discharge, also alternately be with positive negative electricity by the grit of charging part 40, and neutralized effectively at dust collecting port 50.

Especially behind the double electronic desorption system of receiving Figure 17, scattering again of charging part 40 is suppressed, and charging part 40 and the required separately high-pressure generation equipment of dust collecting port 50 are saved, and dust can absorb with single high-pressure generation equipment.

Figure 18 has enumerated the various electrode structures of charging part (quoting from " Theory and practice of removingdust and collecting dust " by Chotaro Ono Ohm-sha, 1978).As shown in the figure, can use any electrode structure, not add restriction.And Figure 19 illustrates various sparking electrode shapes commonly used (quoting from the K.R.Parker work: " Applied Electrostatic Precipitation ", Blackie Academic and Professional).Can use any sparking electrode shape, not add restriction.

As mentioned above, third and fourth embodiment according to the present invention can prevent from effectively to scatter again, and realize high dust-absorbing rate with low cost.

Especially according to the 4th embodiment, by charging part and dust collecting port are added same ac high-voltage, energy simplification system also prevents to scatter again.

The all preferred embodiments of the invention described above are used for example and explanation, but are not the precise form of do not have omitting or limiting the invention to disclose, according in above perhaps by enforcement of the present invention, can make various modifications and change.Selecting for use and describe these embodiment, be intended to illustrate principle of the present invention and practical application thereof, is that those skilled in the art can use the present invention in various embodiments, and makes various modifications be fit to the application-specific of anticipation.Therefore, scope of the present invention is limited by appended claim and equivalent file thereof.

Claims (3)

1. an electric dust collector is characterized in that, comprising:

Be configured to corona discharge type charging part to aerial floating dust charging; With

Be positioned at the dust collecting port that the charging part downstream is configured to absorb charged grit,

Wherein the corona discharge type charging part comprise be configured between its electrode, to add high direct voltage with to the high direct voltage generating unit of grit charging and

Dust collecting port comprises and is configured to apply rectangle wave mode ac high-voltage that frequency is 0.1～2HZ so that the ac high-voltage generating unit of dust suction between its electrode.

2. electric dust collector as claimed in claim 1 is characterized in that, the charging part electrode comprises the structure of a kind of straight line to parallel plate electrode, and

The dust collecting port electrode comprises a kind of parallel plate electrode structure.

3. electric dust collector as claimed in claim 1 is characterized in that, described ac high-voltage generating unit applies the ac high-voltage that voltage change ratio dv/dt is 50～2000V/msec, and described voltage change ratio is meant the rate of change of the last lower edge of ac high-voltage.

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