BACKGROUND OF THE INVENTION
[0001] This invention relates to an electrostatic dust collector and, more particularly,
to an electrostatic dust collector in which extremely small particles of dust can
be collected efficiently with an easily replaceable filter, and wherein a short-circuit
discharge caused by the application of a high voltage does not occur.
[0002] The worsening of municipal air pollution caused by the growth of industry and the
overcrowding of cities is a hindrance to productivity in the industrial sector and
has a deleterious effect in terms of environment and health in residential areas.
Accordingly, pollution preventing measures such as controlling the source of pollutants
have been studied and put into effect. The purification of air in limited spaces is
also an important consideration in many sophisticated and diverse fields. In particular,
air purifiers which includes means for dealing with dust, smoke (especially tobacco
smoke), ticks and pollen are essential to raise the yield at which such products as
VLSIs (very large-scale integrated circuits) of a very high precision are produced
through ultra-fine, precise machining in the semiconductor industry. They are also
absolutely necessary in operating and aseptic rooms, in bacteriological experiments,
for furthering biotechnological research in food processing, and for improving the
environmental hygiene in the home, working place and recreational facilities. The
high-performance filters required are steadily being improved to deal with free-floating
particles having a diameter of at least 0.3 micron, and is some cases 0.1 micron.
Good results are gradually being obtained.
[0003] The dust collecting mechanisms employed in conventional air purifiers are classified
roughly as being of the mechanical dust collecting or electrical dust collecting type,
depending upon the operating principle. Generally speaking, the mechanical dust collecting
systems are capable of trapping particles of a large diameter only and involve many
difficulties in terms of installation and handling. These days the electrical dust
collectors are the most commonly employed.
[0004] Electrical dust collecting systems include electrostatic dust collectors in which
dust is trapped electrostatically upon being ionized by a corona discharge, and electrostatic
induction-type air purifiers in which an electric field is applied across an inductor
and dust is passed through the inductor to be trapped electrostatically. Let us first
discribe a conventional example of the former, namely the electrostatic dust collector,
with reference to Figs. 1 and 2.
[0005] Fig. 1 is useful in describing the dust collecting principle of the electrostatic
dust collector. Floating particles contained in polluted air 1 pass through a filter
2 and are positively charged in a charging section 3 having a discharging wire 4 for
effecting a corona discharge. The positively charged particles enter a collecting
section 5 where they are repelled by high-voltage electrode plates 6 and trapped by
grounded electrode plates 7. The apparatus thus provides purified air 8 from which
the floating particles have been removed.
[0006] Fig. 2 is a sectional view illustrating an example of an electrostatic dust collector
that employs the foregoing dust collecting principle. The dust collector includes
a unit in which are assembled a discharge wire 10 and a discharge electrode plate
11, both having a positive potential, and a dust collecting electrode plate 12 having
a negative potential. The unit is contained in a holder section 13 having a front
side in which a front filter 14 is set, and a rear side in which a rear filter 15
and an activated carbon filter 16 for odor removal are installed. The unit with the
attached filters is installed in a casing 17 through an intake port covered by a grill
18. A fan 19 and an outflow port 20 for the exiting air are provided in the rear portion
of the casing 17.
[0007] Floating particles contained in polluted air are drawn in from the intake port by
the fan 19, pass through the front filter 14 and are positively charged by the corona
discharge wire 10. The positively charged particles are repelled by the discharge
electrode plate 11, the potential whereof is positive, and are trapped by the dust
collecting electrode plate 12, whose potential is negative. A stream of air so purified
is blown out of the outflow port 20 upon passing through the rear filter 15 and activated
carbon filter 16.
[0008] The latter air purifier of electrostatic induction type has already been disclosed
in the specification of Japanese Patent Application Laid-Open No. 59-19564, filed
by the inventor whose invention is described in the present application. This air
purifier will now be discussed in detail with reference to Figs. 3, 4, 5(a) and 5(b).
[0009] Let us first describe the dust collecting principle with reference to Fig. 3. The
electrostatic induction-type air purifier includes an air-permeable, porous inductor
30 on which opposing electrodes 31, 32 are disposed and across which a high DC voltage
is impressed to produce a strong electric field in the inductor 30, thereby trapping
floating particles which attempt to pass through the pores in the inductor.
[0010] In terms of structure, the air purifier includes a filter element 41 arranged in
the center of a case 40. Air containing pollutant particles is drawn into the case
40 from an inflow port 43 by a fan 42. To prevent the filter element 41 from becoming
clogged, a filter bag 44 is disposed within the case 40 for trapping coarser dust
particles. As shown in Fig. 5(a), the filter element 41 includes a filter member obtained
by providing a thin film 48 of a metal such as aluminum comprising a first electrode
on one side surface of a porous induction member 47 made of urethane foam or the like,
and forming a metallic thin film 49 as a second electrode so that the induction member
47 is embraced by the electrodes. As shown in Fig. 5(b), a plurality of these filter
members are wound into a cylindrical shape and a high voltage from a DC high-voltage
power supply 45 (Fig. 4) is applied across the adjacent electrodes 48, 49 via terminals
48a, 49b. Numeral 47a denotes a screen for supporting the filter element 41.
[0011] In operation, floating particles drawn in from the intake port 43 are physically
trapped in the air-permeable pores of the filter members. At the same time, a strong
electrostatic field is generated by the inductors arranged between the positive and
negative electrodes, thereby charging the floating particles. The particles so charged
are trapped in the walls of the pores constituting the porous inductors.
[0012] The conventional electrostatic dust collector shown in Figs. 1 and 2 has a number
of drawbacks, which will now be set forth.
(1) Cleaning and maintenance are difficult.
Since the dust collecting effect diminishes when a large quantity of dust becomes
attached to the dust collecting plates, a cleaning solution is prepared by dissolving
a weakly alkaline cleaning agent in warm water at a temperature of about 60°C. The
dust collecting unit is extracted from the opening of the grill 18 and the electrostatic
collecting section, from which the front filter 14, rear filter 15 and activated carbon
filter 16 have been detached, is immersed in the cleaning solution, usually for a
period of about three hours, depending on the extent of contamination. The electrostatic
collecting section is then shaken back and forth and from side to side while still
immersed in the solution in order to dislodge the contaminants. This must done without
touching the fine discharge wires 10. Any deposits on the dust collecting electrode
plates 12 from smoke such as tobacco smoke are difficult to remove. If a brush or
the like is used, care must be taken not to scrape the collecting plates.
(2) The trapped particles tend to re-scatter.
To trap particles with greater efficiency, either the applied voltage is raised or
the portions to which the voltage is applied are increased in length. In either case,
however, the trapped particles are re-scattered by a discharge which occurs due to
concentration of the electric field at portions where the accumulated dust forms raised
deposits on the collecting electrode plates.
(3) There is a tendency to produce radio wave interference.
When the corona discharge is generated, a high-frequency current flows into the ionized
space, thus causing noisy radio reception.
(4) Ozone is produced.
The corona discharge is accompanied by the production of ozone, which can irritate
or cause damage to mucous membranes.
[0013] The electrostatic induction-type air purifier illustrated in Figs. 3, 5(a) and 5(b)
also has a number of disadvantages.
(1) The purifier is uneconomical since the filter element is discarded with the strip-like
electrode attached thereto when no longer usable.
(2) The apparatus cannot be made compact in size.
(3) The apparatus cannot be improved to withstand use in environments where the temperature
and humidity are high.
SUMMARY OF THE INVENTION
[0014] An object of the present invention is to provide an electrostatic dust collector
capable of collecting very fine dust efficiently without a short-circuit discharge
caused by the application of a high voltage.
[0015] Another object of the present invention is to provide an electrostatic dust collector
having an inexpensive filter element capable of being readily replaced.
[0016] A further object of the present invention is to provide an electrostatic dust collector
which is low in cost and inexpensive to maintain.
[0017] According to the present invention, the foregoing objects are attained by providing
an electrostatic dust collector comprising an electrode unit including first and second
electrodes arranged to oppose each other across a solid insulator and having positive
and negative potentials respectively applied thereto, the second electrode being so
disposed that a leading edge portion thereof is located at a position inwardly of
a leading edge portion of the first electrode; a gas passageway formed on a side of
the second electrode opposite the first electrode; an electrically conductive filter
element arranged in the gas passageway in contact with the second electrode; and forcible
gas passing means for forcibly passing a gas to be purified through the gas passageway.
[0018] Other features and advantages of the present invention will be apparent from the
following description taken in conjunction with the accompanying drawings, in which
like reference characters designate the same or similar parts throughout the figures
thereof.
BRIEF DESCRIPTION OF THE DRAWINGS
[0019]
Fig. 1 is a view for describing the dust collecting principle of a conventional electrostatic
dust collector;
Fig. 2 is a sectional view illustrating an example of an electrostatic dust collector
employing the dust collecting principle of Fig. 1;
Fig. 3 is a view for describing the dust collecting principle of an electrostatic
induction-type air purifier;
Fig. 4 is a sectional view illustrating an electrostatic induction-type dust collector
employing the dust collecting principle of Fig. 3;
Fig. 5(a) is a view showing the construction of an electrode section of a filter element;
Fig. 5(b) is a perspective view of the filter element shown in Fig. 5(a);
Fig. 6 is a view showing the construction of a principal portion of a dust collector
according to the present invention;
Fig. 7 is a perspective view illustrating an embodiment of an electrostatic dust collector
according to the present invention;
Fig. 8 is a perspective view, partially broken away, of a dust collecting section
in the dust collector of Fig. 7;
Fig. 9(a) is a perspective view of a filter element shown in Fig. 8;
Fig. 9(b) is a perspective view of another filter element of this type;
Fig. 10 is a sectional view of the electrostatic dust collector according to the present
invention;
Fig. 11 is an exploded perspective view of the electrostatic dust collector shown
in Fig. 10;
Fig. 12 is a perspective view of a filter element shown in Fig. 11;
Fig. 13 is a sectional view illustrating another embodiment of an electrostatic dust
collector according to the present invention;
Fig. 14 is a perspective view of the dust collector shown in Fig. 13; and
Fig. 15 is a sectional view illustrating a further embodiment of an electrostatic
dust collector according to the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0020] Preferred embodiments of the invention will now be described with reference to the
drawings.
[0021] The construction of a principal portion of an electrostatic dust collector according
to the invention will be described with reference to Fig. 6.
[0022] A ceramic 56 serving as a solid insulator is provided about a first electrode 50
to which a positive DC high voltage is applied. A second electrode 52 to which a negative
potential is applied is so provided as to sandwich the ceramic 56 between itself and
the first electrode 50. The first electrode 50, second electrode 52 and ceramic 56
thus arranged constitute an electrode unit. The leading edge portion of the second
electrode 52, namely the edge on the intake side of the apparatus, is located inwardly
of the leading edge portion of the first electrode 50 so that the two edge portions
do not overlap. The reason for this arrangement is to produce an edge effect on the
intake side. The edge effect sets up an electric field at this portion of the apparatus
to guide floating particles into a filter element, described below.
[0023] A gas passageway 60 for a gas to be purified, such as air, is defined between two
electrode units constructed as set forth above. Arranged in the passageway 60 is a
filter element 61, which comprises a metal wool consisting of extremely fine fibers
of steel, aluminum, copper or the like, by way of example.
[0024] When air containing floating particles enters the passageway 60, the particles are
guided to the filter element 61 by the electric field produced at the leading edge
portion of the above-described electrode unit. When the floating particles reach the
filter element 61, those positively charged are acted upon by Coulomb's force and
are trapped by the fine fibers constituting the filter element 61. This is the result
of an electrostatic induction effect among the numerous fibers that present a large
surface area in the filter element 61, which is held at a negative potential owing
to its contact with second electrode 52 having the negative potential applied thereto.
In addition, the influx of floating particles is constricted when passing through
the narrow voids formed by the fine pores in the mesh-like filter element, which is
held at the negative potential, and the particles are caused to repeatedly collide
with and contact one another, during which time they are charged. The particles eventually
are trapped on the metal fibers of the filter element 61 by Coulomb's force. The trapped
particles are held affixed by an electric charge supplied by the second electrode
52.
[0025] In a preferred embodiment of the electrostatic dust collector shown in Figs. 7 and
8, numeral 50 denotes the first electrode supplied with the positive DC high voltage,
and numeral 56 designates the ceramic 56 molded to enclose the first electrode 50.
Arranged on both sides of the ceramic 56 are the second electrodes 52, to which a
negative voltage is applied. These elements construct a first electrode unit U₁. The
leading edge portions of the second electrodes 52 are located inwardly of the leading
edge portion of first electrode 50 so that an electric field is produced at these
edge portions. A second electrode unit U₂ is provided with the first electrode 50
supplied with a positive high voltage, the second electrode 52 supplied with a negative
voltage, and the ceramic 56 embraced by these electrodes. The first and second electrode
units U₁, U₂ are assembled with a certain distance between them to form the passageway
60.
[0026] Provided between mutually adjacent ones of plural electrode units assembled as described
above are partition plates 57, a lower spacer plate 58 and an upper spacer plate 59,
whereby a plurality of passageways are formed. The electrodes 50, 52 are respectively
provided with terminals 51, 53, and the terminals of like electrodes of the plural
electrode units are interconnected by a conductor 54. Though a minimum of one passageway
60 will suffice, the dust collector can be designed to have a number of passageways
suited to its capacity and application. Further, as shown in Fig. 9(a), the filter
element 61 is shaped beforehand so as to conform to the configuration of the passageway
60. It is also possible to employ a filter element of the kind depicted in Fig. 9(b).
Here the metal fibers of the filter element, designated by numeral 62, are distributed
coarsely at the leading edge portion, which is on the intake side of the passageway,
but the distribution becomes gradually denser as the outflow side is approached. This
makes it possible to collect a uniform amount of dust across the entirety of the filter
element 62.
[0027] An electrostatic dust collector embodying the present invention will now be described
in detail with reference to Figs. 10 and 11.
[0028] In Figs. 10 and 11, numeral 70 denotes the first electrode to which the positive
DC high voltage is applied, 71 the second electrode to which the negative voltage
is applied, and 72 the ceramic serving as the solid insulator enclosing the first
electrode 70. The electrodes 70, 71 and the ceramic 72 construct an electrode unit.
The leading edge portion of the second electrode 71 in the electrode unit is arranged
at a position inwardly of the leading edge portion of the first electrode 70. Numeral
73 denotes a side plate, 74 a gas passageway, 75 a filter element installed in the
passageway 74, 76 a prefilter for trapping coarse dust particles in order to prevent
clogging of the filter element 75, 77 a rear filter, which serves also as a holder
for an activated carbon filter 78, 79 a case body, 80 a stopper, 81 a grill, 82 a
fan, and 83 an outflow port.
[0029] Air and any other gas containing floating particles is drawn in through the grill
81 at the intake port by the fan 82 and reaches the dust collecting unit via the prefilter
76. The dust collecting unit accommodates the filter element 75, which comprises a
metal wool of steel, aluminum, copper or the like, or a sponge consisting of an electrically
conductive plastic. As shown in Fig. 12, the filter element 75 is shaped beforehand
to conform to the configuration of the passageway 74 to facilitate its insertion into
the passageway. The assembled dust collecting unit inclusive of the filter element
75 is installed in the case body 79 by being pushed in from the intake port of grill
81 until it abuts against the stopper 80 located within the case body. The fan 82
and the outflow port 83 for the purified air are provided in the rear portion of the
case body 79 in back of the filter 78.
[0030] In operation, air or any other gas containing floating particles is drawn in through
the grill 81 at the intake port by the fan 82. The coarse particles are trapped by
the prefilter 76. The finer particles that pass through prefilter 76 are acted upon
by the electric field at the leading edge portions of the electrodes 70, 71 to be
guided into the filter element 75, which is held at the negative potential. As a result,
the entrant particles are subjected to the above-described dust collecting action
and, hence, are trapped by the multiplicity of filter element fibers, which present
a large surface area. Air thus purified is deodorized by the activated carbon filter
78 before being blown out of the outflow port 83.
[0031] Another embodiment of the electrostatic dust collector of the present invention will
now be described in detail with reference to Figs. 13 and 14.
[0032] Here a first electrode 90 has a cylindrical configuration. Disposed on the inner
surface of the first electrode 90 in coaxial relation with the first electrode is
a cylindrical ceramic 92. A second electrode 91 is formed on the inner surface of
the ceramic 92 and has a cylindrical configuration, the second electrode being in
coaxial relation with the ceramic 92. Thus, the first and second electrodes 90, 91
are of cylindrical form and are disposed in coaxial relation with the cylindrical
ceramic, which is sandwiched between them. The leading edge portion of the second
electrode 91 is located inwardly of the leading edge portion of the first electrode
91. Defined within the cylindrical second electrode 91 is a space serving as a gas
passageway 95, in which a filter element 96 shaped beforehand into a cylindrical configuration
is arranged. The first and second electrodes 90, 91 have terminals 93, 94, across
which a high-voltage DC power supply 97 is connected. A motor-driven fan 98 is arranged
at the trailing ends of the electrodes. Operation is the same as that set forth above.
[0033] In the embodiment of Figs. 13 and 14, only one electrode unit is shown. However,
it is possible to adopt an arrangement in which a plurality of electrode units are
disposed coaxially. For example, as illustrated in Fig. 15, it is possible to adopt
an arrangement having a centrally located cylindrical first electrode 100, a cylindrical
ceramic 102 formed to enclose the first electrode 100, a second electrode 101 arranged
on the inner circumferential surface of the ceramic 102, a second electrode 103 arranged
on the outer circumferential surface of the ceramic 102, a cylindrical first electrode
104 provided on the outer side of the second electrodes 101, 103, a cylindrical ceramic
106 provided on the inner side of the first electrode 104, a cylindrical second electrode
105 provided on the inner side of the ceramic 106, a filter element 109 arranged in
a central gas passageway 107 defined within the first electrode 100, and a filter
element 110 arranged in a gas passageway 108 encircling the gas passageway 107 and
coaxial therewith. Numeral 111 denotes a motor-driven fan. A multiple filtration system
of this type is effective for use as an emergency dust collector in nuclear reactors,
fuel storage facilities and the like.
[0034] If steel wool is used as the filter element material, the filter will act to chemically
adsorb such compounds as SO₂ and NO
x to achieve a greater degree of purification of the gas that passes through the filter
element. In addition, using steel wool allows the filter element to be employed in
a high-temperature environment.
[0035] Furthermore, the magnitude and distribution of the electric field generated at the
leading edge portion of the above-described electrode unit is dependent upon the voltage
applied across the electrodes or the density of the fibers at the leading edge portion
of the filter element.
[0036] Though the solid insulator has been described as being a ceramic, any material which
exhibits a high insulation breakdown resistance and mechanical strength can be used.
One example is epoxy resin. If the latter is adopted, a slender electrode unit can
be readily fabricated by forming an electrode comprising a thin metal film on the
surface of a plate or sheet of the epoxy resin.
[0037] As many apparently widely different embodiments of the present invention can be made
without departing from the spirit and scope thereof, it is to be understood that the
invention is not limited to the specific embodiments thereof except as defined in
the appended claims.
[0038] The present invention, described in detail hereinabove, has a number of important
advantages.
(1) A material such as the ceramic or epoxy resin interposed between the electrodes
exhibits a high degree of insulation, and dust removed from the entrant gas does not
form a deposit on both electrodes. Therefore, despite the fact that a high DC voltage
is applied across the electrodes, a short-circuit discharge can be prevented and both
radio wave interference and the generation of ozone can be reduced.
(2) The filter element in contact with the dust collecting electrode is held at the
same potential as this electrode and presents a very large surface area, so that floating
particles contained in the air passing through the filter element are trapped by electrostatic
induction. Accordingly, the particles are collected very efficiently both by the physical
filtering action of the filter element itself and by electrostatic induction.
(3) Particles trapped by the filter element are held affixed by the electric charge
from the electrode unit.
(4) The electrode unit having the electrodes which oppose each other across the solid
insulator is of a simple and rigid structure and low in cost.
(5) Since the materials constituting the dust collector exhibit a high resistance
to heat, the dust collector can fully withstand use in high-temperature environments.
(6) The overall apparatus can be made compact in size.
(7) The filter element is extracted from the gas passageway before its dust collecting
efficiency declines and is replaced merely by inserting a new filter element in the
passageway. Accordingly, the filter element is readily replaceable.
(8) The dust collector can be restored to its original performance merely by replacing
the filter element.
(9) A metal wool such as of steel, aluminum or copper can be used as the filter element.
Such a filter element is low in price and makes it possible to reduce maintenance
costs. In particular, these metal wools provide a large surface area in the gas passageway
to provide a high dust collecting efficiency.
(10) If steel wool is adopted at the filter element material, compounds such as SO₂
and NOx are chemically adsorbed to further purify the gas that passes through the filter.
(11) If steel wool is used as the filter element, a used filter element can be discarded
without fear of pollution since the steel wool will rapidly oxidize and break down
in a natural manner due to oxygen and water contained in the air.
1. An electrostatic dust collector for removing particles from a gas to be purified,
comprising:
an electrode unit (U₁, U₂) including a first electrode (50; 70; 90; 100, 104) a second
electrode (52; 71; 91; 101, 103, 105) and a solid insulator (56; 72; 92; 102, 106)
said first and second electrodes being arranged to oppose each other other across
said solid insulator and having positive and negative potentials respectively applied
thereto, said seconde electrode being so disposed that a leading edge portion thereof
is located at a position inwardly of a leading edge portion of said first electrode;
a gas passageway (60; 74; 95; 107, 108) formed on a side of said second electrode
which is opposite said first electrode; an electrically conductive filter element
(61, 62; 75; 96; 109, 110) arranged in said gas passageway so as to be in contact
with said second electrode; and forcible gas passing means (82; 98; 111) for forcibly
passing the gas to be purified through said gas passageway.
2. The electrostatic dust collector according to claim 1, wherein a plurality of dust
collecting units are juxtaposed in parallel, each dust collecting unit comprising
said electrode unit (U₁, U₂), said gas passageway (60; 74; 95; 107, 108) and said
filter element (61, 62; 75; 96; 109, 110).
3. The electrostatic dust collector according to claim 2, wherein said plurality of
dust collecting units juxtaposed in parallel includes a dust collecting unit disposed
on an inner side thereof, the first electrode (100) of said last-mentioned dust collecting
unit being enclosed within said solid insulator (102), and the second electrode (102,
103) being arranged on both sides of said solid insulator (102).
4. The electrostatic dust collector according to claim 1 or 2, wherein said first
(50; 70) and second electrodes (52; 71) are flat plates arranged to lie parallel to
each other.
5. The electrostatic dust collector according to claim 1 or 3 wherein said first (90;
100, 104) and second electrodes (91; 101, 103, 105) are cylinders arranged in coaxial
relation.
6. The electrostatic dust collector according to any of claims 1 to 5, wherein said
filter element (61, 62; 75; 96; 109, 110) is shaped in advance so as to conform to
the shape of said gas passageway (60; 74; 95; 107, 108).
7. The electrostatic dust collector according to any of claims 1 to 6, wherein said
filter element comprises metallic wool prefereably made of steel.
8. The electrostatic dust collector according to any of claims 1 to 7 wherein said
forcible air passing means (82; 98; 111) is a motor driven fan provided at a rearmost
portion of said gas passageway (60; 74; 95; 107, 108).
9. The electrostatic dust collector according to any of claims 1 to 8 further comprising
a prefilter (76) provided at a forward portion of said gas passageway (74) and/or
an activated carbon filter (78) provided at a rearward portion of said gas passageway
(76).
10. The electrostatic dust collector according to any of claims 1 to 9, wherein said
solid insulator (57; 72; 92; 102, 106) comprises a ceramic or an epoxy resin.
11. The electrostatic dust collector according to any of claims 1 to 10, wherein a
leading edge portion of the second electrode (52; 71; 91) 101, 103, 105) is located
at a portion inwardly of a leading edge portion of the first electrode (50; 70; 90;
100, 102)