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A high efficiency passive neutralizer system
Journal of Electrostatics, 10 (1981) 2 1 7 - - 2 2 2
217
Elsevier ~¢cientific Publishing Company, Amsterdam -- Printed in The Netherlands
A HIGH EFFICIENCY PASSIVE NEUTRALIZER
SYSTE~'I
D. I~ITCI{LL ~ AND P.E. SECHER+ School of Electronic
Engineering
Science, University College of Norsh Wales, Bangor,
United I(ingdom.
ABSTRACT An e;~erimental
study wss made of the improved neu
could be obtained from a f~ne wire passive neutralizer by heating it. ment re~ulted from a decrease
This improve-
in the critical field for onset of corona at the hot
wire due to the locally reduced ambient air density. It was possible
neutralLry for a significant
range of operating conditions.
INTRODUCTIOH The industrial use of passive neutralizers significantly
in recent years.
driven neutralizers, simple,
- grounded points or wires - has grown
Compared with radioactive bars, or electrically
operating at high voltage,
passive devices are seductively
of relatively low cost and appear to be ir~herently safer.
Comparisons
of
(L) radioactive,
electrically powered,
neutralizing
ability of the three classes of device is not greatly different,
radioactive
and passive neutralizers
bars can give a slightly lower residual
suggest
~hat the
surface charge density.
although
(2)
If the surface charge density on a web before and after it passes under a passive neutralizer
(3) plotted
is measured,
a characteristic
of the form shown in figure i can be
Three distinct operating zones can be distinguished.
In zone A, the
neutralLzer has no effect since the field set up by
This threshold
is just exceeded at conditions
field
corresponding
to
the boundary between zones A and B. In zone B the corona current builds up rapidly with increasing charge
Jensi~y and progressively more efficient neutralization
zone C, corresponding ing occurs,
to high input surface charge densities,
giving rise to the phenomenon k n o ~
* Now at i~otorola,
East Kilbride.
0304-3886/81/0000--0000/$02.50
+
input surface
is observed.
~or
limited reverse charg-
as overcompensation.
This is
Now, at Royal Doulton Tableware Limited, Stoke-on-Trent.
© 1981 Elsevier Scientific Publishing Company
218
+~ Residual surface charge density - ;0I Figure I.
!./
:
Zone C
M ~~Input
surface charg~
TypLcal performance characteristic of passive neutralizer.
observed when strong corona current generation results in neutralization significantly upstream of the corona source.
Reverse web charging below the neutraliz!r-{{
device results from the effect of the emission-associated electric wind from [on trajectories following field lines which cross the web surface. f= has been found (4,5) that when a corona source f
This enhancement
hea~ed source. devices,
is heated,
arid that for a given f[eld~heat!ng
(i)
and
(8)
t.he <-lectr[c field Lncreases the corona
is due to the local decrease in air density around Lh{'
With the aim of improving the performance of passive neutralizing
the authors have explolted the healing effect to reduce bo~,h the maximum
residual surface charge density (corresponding
co point }) in figurx~ i) &~s well a~
(6) ~he overcompensatLon effect.
The system which has been ew31ved
appears
to out-
perform existing neutralizers and to offer a satisfactory solution to many moving web static problems
in tnduszry.
E)G)ERIIvLENTAI, TEST ARRANGEIv~ENTS The corona source used
[n the series of experimenEs reported here consisted of a
small diameter taut wire mounted at the required height over the charged moving surface Co be neutralLzed. variable DC power supply. of a wattmeter
Incorporation
[n the corona wire circuit enabled Che power input ~o the wire (les~
than 20W) to be monitored. was possible
The two ends of the corona wire were connected to a One end of the corona wire was grounded.
From resistance measurements and simple calculations
i!,
to correlate wire temperature with power input.
14easuremen= of neutralizing performance was effected using a moving insulatingsurface test rig (7) consisting of a metre disc of perspex 2 cm ~hick, mounted horizon~ally on the shaft of a variable speed motor.
The :',urfacc of the disc could
be charged by means of a corona source coupled to a high voltage unipolar power supply (I .D.B. model 320) which was remotely controllable.
The neutralizing devi{:(:
219 under test was positioned above the disc diametrically
opposite
the charging source.
Surface charge density upstream and downstream of the neutralizing monitored as the associated quasi-~lifonn Rotating vane field mills field,
device was
electric field above the disc surface.
(I.D.B. model iO7 Mk II) were used to measure electric
the measured values being output both as analogue readings on the instruments
display meters,
and digitized fop subsequent data processing.
An AIM 65 microcomputer was employed
to control
conduct of the tests, and the data logging.
the experimental
Specifically
speed and initial surface charge density could be automatically increments and the resultant ored.
residual surface charge density
Digitized values of rotor speed,
field were recorded on cassette data was subsequently
EXPERimENTAL
fc~' tunes.
the
increased in defined
(electric field) monit-
initial electric field and residual electric
tape, under microprocessor
control.
The recorded
analysed on a Systime model 5000 minicomputer.
RESULTS
a par,ge of corona-wire
residual
parameters,
in a given test, the rotor
to charged-surface
spacings,
characteristic
cupves of
field as a function of input field were recorded for different wire temperaFrom these characteristics
(E oUt)max, in figure i.
corresponding
were deduced the maximum values of residual field,
to the maximum residual
surface charge density - point R
The (E oUt)ma x values ape shown in figure 2 plotted as a function of
wipe temperature.
It will be seen that at most wire temperatures
above ambient,
fop
x105j,.81,t--Wire height above, surface-- mm. o positive web 1"4 t "-.%. / t,.. 6 " , . "-.--~-* ..... negative web 1"2 Figure 2.
$
k
I 1.0 X
"5 o
I..d
0.8
o. j I
0
,oo 260
I
4oo 560
Temperature of wire
°C
V a l u e s o f (E o u t ) max plotted as a function of wire ~empepature f o p p o s i t i v e and negative webs. Mean web speed i0 m/s. Wire diameter O.05mm.
220 a given wire to surface spacing
(E out) is lower for a positively charged surmax charged surface. This is in accord wi~h the prev[ou~
face than for a negatively (4)
observations of
bomperature
as
compared Effects
with due
[n.~:ignifi('ant In z o n e
a negative
a poe] rive
line
characterize
the
source
charged
surfacE,
the
threshold
field
field-creai:ing
wLth
charged
k~crcas:~ surI"a¢o~
~.u.
error
were
from
exceeding
the neutralizer performance
found
t{) I)e r ~ l a t . L v e l y
Ln t h J . s p a p e r .
characteristic
boundaries,
~[thout
corona
speed
further
neutralizer
zone
of
(positive
source.
be d~.scussed
Lhe p a s s i v e
between
by a straight
of
not
decrease
corona corona
to variation arid will
1~ o f
Lhe c u r v e
a greater
ind±cat':ng
for
(fLgure
points
])
it
b~ f ( ) u n d
]~ t o ~i, c<]n b e
a few percent.
]:
is
in Lermr of the 'gradient'--
tha
represEFltud
convenient ::o A (~ out)
A
(E in)
~'-. Wire height Q'~---~... " above surface ~ ' ~ ""'~-.~. - - mm. 0"5
~,isure
is
Oe,
o
p
,3. ~ r a d k . n r ,
- A(E
ouu)
A ( Z in )
itive web
as a fLlncLion tem[)( r a t u r e .
"~
o f v,'iP~
.... -~. . . . . . negative web
Gradient
/
50
. . . . ~---~'_ ~
-'e
81 0
'
0
i
100
200
I
I
I
300
400
500
Temperature '['he in
'gradient.' the
spacings
was measured
curves the
be exp<('ted migrat:on A] r h e a t i n g
for
sho%~] i n f : . g u r e var!azion in
thaL once
behavleur by
of
of wire
a range
3.
the
rather
b h e w:_re i s
of wire
I~ can
gradient
with
incideni3
°C
be
seen
that,
bemperatupe fLeld
exceeds
thaz] ion
generatfon
a purely
lo(;al
except
is the
corona
such
spacings
ab ;rnali
relat:.vely
deter~nines
phenomenon
surface
w[r(
~:mall. onse~
for
the
~,~{
t o s t ] r ' i ' ~ ,'
This
threshold,
neuzral[zation thaz
r~uit.
i! :.',r~
~I'fLol(~r~ y . larger
w! r(.
221 to surface spacings the ions are moving through air at quasi-ambient
temperature
for the major part of their trajectories. Figures 4(a) and 4(b) generated from the data used to plot figures 2 and 3 show the variation of (E oUt)ma x and gradient respectively separation.
Clearly minimization
surface spacings while attainment possible
of minimum gradien: to put off to Lhe highes~
input fields the onset of overcompensation
ate at large wire-surface
as a function of wire-surface
of (E oUt)ma x dictates operation at minimum wire-
indicates a requirement
~o oper-
spacings.
xlC~ . . . . empirical 1.4 characteristic _/ .derived from/f ref (8)//,/~20o 1.2
.,
0'5 l! + ~'~i
C')¢~
pos.web neg.web
,'
(EoUt)max
I.0
/
v/m
//.
,,Y ,y./.Yooo
,/e
/
(>(
;'/ Z / 7"
Figur~ 4(a) Figure 4(b)
Yi
i
I
I
~ 0.2
~
Q
E 0.1
~--,
"~
i
20 40 60 80 Wire height- mm.
0
I
I
I
20 40 60 ~0 Wire height -- mm.
Variation of (E out) max as a function of w~re-surface Variation of gradient values averaged over temperature function of wire-surface separation.
separation range, as a
Implementation
It seemed possible
that an optimized practical passLve neutralizer
realized by combining an essentially distance
I
L
-e- pos.web .... neg.web
'J 0
IN
/;/'_/
o.,
Practical
, /
conventional
system could be
passive device separated some
from The web, %'ith a downstream heated wire placed close to the web.
5 shows the physical disposition characteristics
of the two neutralizers
Figure
and the measured performance
of ~he individual and combined neutralizers.
If boLh neutralLzers upstream of the other, of the first uniT.
are, in use simultaneously,
with the wide-separation
unit
the close-spaced unit merely operaLes on the residual field
With no heating of the wire of the second neutralizer
reduction of Lhe residual field is relatively small. gives a very low final residual
Lhe further
Heating of the wire, however,
fLeld over a major part of the input field range.
222
xlO 5
primary neutralizer
}0"5 (Eout)
7
O
-primary -,,..
"~&.primary neutralizer}o 08 ~ + heated secondary "
ne r i er
~,nhe=~,~
neutralizer] ~ -;1[-- ~ (heatedwi~,,1 . . mm. . . ~. _mm. _ ~ ~ [v-4_.t12 4(J
Figure 5.
V/m
(lSW)
secondary IOF~1-~--~ ~
-" movement
5 x 105V/m. I( E: in)'*"
~
~o~nn,4=~, ............. ~ "-.<.~-" n e u t r a l i z e r alone
hea te d secondaw ,~ ~neutralizer alone (15W)
of web
Performance characteristics and when combined.
for tm,o passive neutralizers
individually,
CONC] .US IONS It is clear that the principal problem asset Lated w:, ~h passive neutralizers, the significant heating
threshold field for corona onset,
the corona source.
The resulting worsening of ~he overcompensat[on
ca~l be countered by mounting a conventional web upstream of the heated uni~. neutralizer
is not dissimilar
The combination
c~lq be partially allieviated
The overall per±'or~nance of the
use of the combination passive neutralizer,
bar
par~sLve
(2)
cheaper" than a combination
the urlfounded but very real disqui~ t
often associated with the latter t~rpe of device.
e×ception of situations where ar~ inflammable
specified where previously
'combination'
to that of a combination passive/radioactive
bar and would not generate
among operating porsonn(l
effect
passive neutralizer well spaced from Lh{~
passive bar should be signif[cangly
passive/radioactive
n&mt(ly by
With th~
vapour atrnosphere~or' space prohibit
th~
zhe system might wiuh advantage be
a combination passive/radioactive
bar would have been zhc
normal choice. R e f e r e e ' s note:
In a d d i t i o n clouds.
there m a y be h a z a r d in the p r e s e n c e
of f l a m m a b l e d u s t
REFERENCES
~. 2. 3. 4. 5. 6. 7. 8.
P.E. Socket (Ed), 'Static Elec~rification; Fundamental Concepts, Hazards and Applications', University College of North Wales, 1976. The Radiochemical Centre, 'Eliminate Static', 1980. K.G. Lovstrand, inst. Phys, Conf. Sop. No. 2'7, (1975), 246-255. lJ.i~. Awad and G.S.P. Castle, Prec. 1973 Annual lqeeting of I.A.S., lJ[lwaukee, (1973), 3 7 3 - 3 8 0 . B. ~ a k i n a n d I . I . Inculer, Lbid, 381-389. British Patent Appl:ieatton filed. P.E. Secker, Inst. Phys. Conf. Set. No. 48 (1979), 115-123. M. Kawasaki and T. Adach[, Prec. Abstracts 1977 Annual Lieet[ng of the ]nst]tute of Electrostatics 3apan, (]977) 3a.
217
Elsevier ~¢cientific Publishing Company, Amsterdam -- Printed in The Netherlands
A HIGH EFFICIENCY PASSIVE NEUTRALIZER
SYSTE~'I
D. I~ITCI{LL ~ AND P.E. SECHER+ School of Electronic
Engineering
Science, University College of Norsh Wales, Bangor,
United I(ingdom.
ABSTRACT An e;~erimental
study wss made of the improved neu
could be obtained from a f~ne wire passive neutralizer by heating it. ment re~ulted from a decrease
This improve-
in the critical field for onset of corona at the hot
wire due to the locally reduced ambient air density. It was possible
neutralLry for a significant
range of operating conditions.
INTRODUCTIOH The industrial use of passive neutralizers significantly
in recent years.
driven neutralizers, simple,
- grounded points or wires - has grown
Compared with radioactive bars, or electrically
operating at high voltage,
passive devices are seductively
of relatively low cost and appear to be ir~herently safer.
Comparisons
of
(L) radioactive,
electrically powered,
neutralizing
ability of the three classes of device is not greatly different,
radioactive
and passive neutralizers
bars can give a slightly lower residual
suggest
~hat the
surface charge density.
although
(2)
If the surface charge density on a web before and after it passes under a passive neutralizer
(3) plotted
is measured,
a characteristic
of the form shown in figure i can be
Three distinct operating zones can be distinguished.
In zone A, the
neutralLzer has no effect since the field set up by
This threshold
is just exceeded at conditions
field
corresponding
to
the boundary between zones A and B. In zone B the corona current builds up rapidly with increasing charge
Jensi~y and progressively more efficient neutralization
zone C, corresponding ing occurs,
to high input surface charge densities,
giving rise to the phenomenon k n o ~
* Now at i~otorola,
East Kilbride.
0304-3886/81/0000--0000/$02.50
+
input surface
is observed.
~or
limited reverse charg-
as overcompensation.
This is
Now, at Royal Doulton Tableware Limited, Stoke-on-Trent.
© 1981 Elsevier Scientific Publishing Company
218
+~ Residual surface charge density - ;0I Figure I.
!./
:
Zone C
M ~~Input
surface charg~
TypLcal performance characteristic of passive neutralizer.
observed when strong corona current generation results in neutralization significantly upstream of the corona source.
Reverse web charging below the neutraliz!r-{{
device results from the effect of the emission-associated electric wind from [on trajectories following field lines which cross the web surface. f= has been found (4,5) that when a corona source f
This enhancement
hea~ed source. devices,
is heated,
arid that for a given f[eld~heat!ng
(i)
and
(8)
t.he <-lectr[c field Lncreases the corona
is due to the local decrease in air density around Lh{'
With the aim of improving the performance of passive neutralizing
the authors have explolted the healing effect to reduce bo~,h the maximum
residual surface charge density (corresponding
co point }) in figurx~ i) &~s well a~
(6) ~he overcompensatLon effect.
The system which has been ew31ved
appears
to out-
perform existing neutralizers and to offer a satisfactory solution to many moving web static problems
in tnduszry.
E)G)ERIIvLENTAI, TEST ARRANGEIv~ENTS The corona source used
[n the series of experimenEs reported here consisted of a
small diameter taut wire mounted at the required height over the charged moving surface Co be neutralLzed. variable DC power supply. of a wattmeter
Incorporation
[n the corona wire circuit enabled Che power input ~o the wire (les~
than 20W) to be monitored. was possible
The two ends of the corona wire were connected to a One end of the corona wire was grounded.
From resistance measurements and simple calculations
i!,
to correlate wire temperature with power input.
14easuremen= of neutralizing performance was effected using a moving insulatingsurface test rig (7) consisting of a metre disc of perspex 2 cm ~hick, mounted horizon~ally on the shaft of a variable speed motor.
The :',urfacc of the disc could
be charged by means of a corona source coupled to a high voltage unipolar power supply (I .D.B. model 320) which was remotely controllable.
The neutralizing devi{:(:
219 under test was positioned above the disc diametrically
opposite
the charging source.
Surface charge density upstream and downstream of the neutralizing monitored as the associated quasi-~lifonn Rotating vane field mills field,
device was
electric field above the disc surface.
(I.D.B. model iO7 Mk II) were used to measure electric
the measured values being output both as analogue readings on the instruments
display meters,
and digitized fop subsequent data processing.
An AIM 65 microcomputer was employed
to control
conduct of the tests, and the data logging.
the experimental
Specifically
speed and initial surface charge density could be automatically increments and the resultant ored.
residual surface charge density
Digitized values of rotor speed,
field were recorded on cassette data was subsequently
EXPERimENTAL
fc~' tunes.
the
increased in defined
(electric field) monit-
initial electric field and residual electric
tape, under microprocessor
control.
The recorded
analysed on a Systime model 5000 minicomputer.
RESULTS
a par,ge of corona-wire
residual
parameters,
in a given test, the rotor
to charged-surface
spacings,
characteristic
cupves of
field as a function of input field were recorded for different wire temperaFrom these characteristics
(E oUt)max, in figure i.
corresponding
were deduced the maximum values of residual field,
to the maximum residual
surface charge density - point R
The (E oUt)ma x values ape shown in figure 2 plotted as a function of
wipe temperature.
It will be seen that at most wire temperatures
above ambient,
fop
x105j,.81,t--Wire height above, surface-- mm. o positive web 1"4 t "-.%. / t,.. 6 " , . "-.--~-* ..... negative web 1"2 Figure 2.
$
k
I 1.0 X
"5 o
I..d
0.8
o. j I
0
,oo 260
I
4oo 560
Temperature of wire
°C
V a l u e s o f (E o u t ) max plotted as a function of wire ~empepature f o p p o s i t i v e and negative webs. Mean web speed i0 m/s. Wire diameter O.05mm.
220 a given wire to surface spacing
(E out) is lower for a positively charged surmax charged surface. This is in accord wi~h the prev[ou~
face than for a negatively (4)
observations of
bomperature
as
compared Effects
with due
[n.~:ignifi('ant In z o n e
a negative
a poe] rive
line
characterize
the
source
charged
surfacE,
the
threshold
field
field-creai:ing
wLth
charged
k~crcas:~ surI"a¢o~
~.u.
error
were
from
exceeding
the neutralizer performance
found
t{) I)e r ~ l a t . L v e l y
Ln t h J . s p a p e r .
characteristic
boundaries,
~[thout
corona
speed
further
neutralizer
zone
of
(positive
source.
be d~.scussed
Lhe p a s s i v e
between
by a straight
of
not
decrease
corona corona
to variation arid will
1~ o f
Lhe c u r v e
a greater
ind±cat':ng
for
(fLgure
points
])
it
b~ f ( ) u n d
]~ t o ~i, c<]n b e
a few percent.
]:
is
in Lermr of the 'gradient'--
tha
represEFltud
convenient ::o A (~ out)
A
(E in)
~'-. Wire height Q'~---~... " above surface ~ ' ~ ""'~-.~. - - mm. 0"5
~,isure
is
Oe,
o
p
,3. ~ r a d k . n r ,
- A(E
ouu)
A ( Z in )
itive web
as a fLlncLion tem[)( r a t u r e .
"~
o f v,'iP~
.... -~. . . . . . negative web
Gradient
/
50
. . . . ~---~'_ ~
-'e
81 0
'
0
i
100
200
I
I
I
300
400
500
Temperature '['he in
'gradient.' the
spacings
was measured
curves the
be exp<('ted migrat:on A] r h e a t i n g
for
sho%~] i n f : . g u r e var!azion in
thaL once
behavleur by
of
of wire
a range
3.
the
rather
b h e w:_re i s
of wire
I~ can
gradient
with
incideni3
°C
be
seen
that,
bemperatupe fLeld
exceeds
thaz] ion
generatfon
a purely
lo(;al
except
is the
corona
such
spacings
ab ;rnali
relat:.vely
deter~nines
phenomenon
surface
w[r(
~:mall. onse~
for
the
~,~{
t o s t ] r ' i ' ~ ,'
This
threshold,
neuzral[zation thaz
r~uit.
i! :.',r~
~I'fLol(~r~ y . larger
w! r(.
221 to surface spacings the ions are moving through air at quasi-ambient
temperature
for the major part of their trajectories. Figures 4(a) and 4(b) generated from the data used to plot figures 2 and 3 show the variation of (E oUt)ma x and gradient respectively separation.
Clearly minimization
surface spacings while attainment possible
of minimum gradien: to put off to Lhe highes~
input fields the onset of overcompensation
ate at large wire-surface
as a function of wire-surface
of (E oUt)ma x dictates operation at minimum wire-
indicates a requirement
~o oper-
spacings.
xlC~ . . . . empirical 1.4 characteristic _/ .derived from/f ref (8)//,/~20o 1.2
.,
0'5 l! + ~'~i
C')¢~
pos.web neg.web
,'
(EoUt)max
I.0
/
v/m
//.
,,Y ,y./.Yooo
,/e
/
(>(
;'/ Z / 7"
Figur~ 4(a) Figure 4(b)
Yi
i
I
I
~ 0.2
~
Q
E 0.1
~--,
"~
i
20 40 60 80 Wire height- mm.
0
I
I
I
20 40 60 ~0 Wire height -- mm.
Variation of (E out) max as a function of w~re-surface Variation of gradient values averaged over temperature function of wire-surface separation.
separation range, as a
Implementation
It seemed possible
that an optimized practical passLve neutralizer
realized by combining an essentially distance
I
L
-e- pos.web .... neg.web
'J 0
IN
/;/'_/
o.,
Practical
, /
conventional
system could be
passive device separated some
from The web, %'ith a downstream heated wire placed close to the web.
5 shows the physical disposition characteristics
of the two neutralizers
Figure
and the measured performance
of ~he individual and combined neutralizers.
If boLh neutralLzers upstream of the other, of the first uniT.
are, in use simultaneously,
with the wide-separation
unit
the close-spaced unit merely operaLes on the residual field
With no heating of the wire of the second neutralizer
reduction of Lhe residual field is relatively small. gives a very low final residual
Lhe further
Heating of the wire, however,
fLeld over a major part of the input field range.
222
xlO 5
primary neutralizer
}0"5 (Eout)
7
O
-primary -,,..
"~&.primary neutralizer}o 08 ~ + heated secondary "
ne r i er
~,nhe=~,~
neutralizer] ~ -;1[-- ~ (heatedwi~,,1 . . mm. . . ~. _mm. _ ~ ~ [v-4_.t12 4(J
Figure 5.
V/m
(lSW)
secondary IOF~1-~--~ ~
-" movement
5 x 105V/m. I( E: in)'*"
~
~o~nn,4=~, ............. ~ "-.<.~-" n e u t r a l i z e r alone
hea te d secondaw ,~ ~neutralizer alone (15W)
of web
Performance characteristics and when combined.
for tm,o passive neutralizers
individually,
CONC] .US IONS It is clear that the principal problem asset Lated w:, ~h passive neutralizers, the significant heating
threshold field for corona onset,
the corona source.
The resulting worsening of ~he overcompensat[on
ca~l be countered by mounting a conventional web upstream of the heated uni~. neutralizer
is not dissimilar
The combination
c~lq be partially allieviated
The overall per±'or~nance of the
use of the combination passive neutralizer,
bar
par~sLve
(2)
cheaper" than a combination
the urlfounded but very real disqui~ t
often associated with the latter t~rpe of device.
e×ception of situations where ar~ inflammable
specified where previously
'combination'
to that of a combination passive/radioactive
bar and would not generate
among operating porsonn(l
effect
passive neutralizer well spaced from Lh{~
passive bar should be signif[cangly
passive/radioactive
n&mt(ly by
With th~
vapour atrnosphere~or' space prohibit
th~
zhe system might wiuh advantage be
a combination passive/radioactive
bar would have been zhc
normal choice. R e f e r e e ' s note:
In a d d i t i o n clouds.
there m a y be h a z a r d in the p r e s e n c e
of f l a m m a b l e d u s t
REFERENCES
~. 2. 3. 4. 5. 6. 7. 8.
P.E. Socket (Ed), 'Static Elec~rification; Fundamental Concepts, Hazards and Applications', University College of North Wales, 1976. The Radiochemical Centre, 'Eliminate Static', 1980. K.G. Lovstrand, inst. Phys, Conf. Sop. No. 2'7, (1975), 246-255. lJ.i~. Awad and G.S.P. Castle, Prec. 1973 Annual lqeeting of I.A.S., lJ[lwaukee, (1973), 3 7 3 - 3 8 0 . B. ~ a k i n a n d I . I . Inculer, Lbid, 381-389. British Patent Appl:ieatton filed. P.E. Secker, Inst. Phys. Conf. Set. No. 48 (1979), 115-123. M. Kawasaki and T. Adach[, Prec. Abstracts 1977 Annual Lieet[ng of the ]nst]tute of Electrostatics 3apan, (]977) 3a.