Apparatus and method for cleaning a filter assembly

Disclosed is an apparatus which has the capability of cleaning a waste or used filter assembly with a broad spectrum of chemical agents in an automated fashion. The cleaning apparatus comprises a cleaner vessel for accommodating the filter assembly to carry out triethylene glycol cleaning, sodium hydroxide cleaning, nitric acid cleaning and water washing in a predetermined cleaning sequence. First to fourth reservoirs communicate with the cleaner vessel through their corresponding pipelines to feed such chemical detergent liquids as triethylene glycol solution, sodium hydroxide solution, nitric acid solution and pure water into the vessel. The detergent liquids will circulate within the cleaning vessel by means of a stream generator, whereby the filter assembly can be cleaned to a higher degree of detergency.

FIELD OF THE INVENTION 
The present invention pertains to an apparatus and method for cleaning a 
filter assembly with chemical agents to remove contaminants or allen 
matters stuck thereto. 
DESCRIPTION OF THE PRIOR ART 
As is well-known in the art, polymeric films used as a video or audio tape 
may be produced by way of melting solid polymeric material usually 
referred to as "polymer chips" and then stretching the molten polymer to a 
desired width and thickness. This holds true for the polymeric yarns that 
have been extensively employed in the textile industry. 
The molten polymer has a tendency to contain various foreign matters or 
unwanted contaminants whose removal is essential to enhance the quality of 
the obtained polymeric films. It is the industry's practice to remove or 
screen the foreign matters present in the molten polymer through the use 
of a generally cylindrical filter assembly. Such a filter assembly 
consists of an elongate stem with an axial flow path defined therealong 
and a plurality of finely perforated disk-like filter elements stacked one 
above the other along the length of the elongate stem. When the filter 
assembly is in use, the individual filter elements gradually become 
clogged by the contaminants over time and sooner or later become no longer 
usable. 
Since the filter elements are extremely expensive, it is more desirable to 
regenerate the used filter assembly through certain cleaning operation 
than to simply replace it with a new one. To this end, a great deal of 
efforts has been made to develop an improved technique of cleaning the 
used filter assembly in an efficient manner. In a known cleaning method, 
it is typical to first clean the filter assembly with such chemical agents 
as triethylene glycol, sodium hydroxide and nitric acid. Subsequently, the 
chemically cleaned filter assembly is subject to a physical treatment, 
e.g., ultrasonic cleaning. 
To carry out the chemical cleaning process, a used filter assembly is 
placed into a first cleaning vessel in which triethylene glycol cleaning 
proceeds for a given period of time. The filter assembly is taken out of 
the first cleaning vessel and then disassembled into individual filter 
elements for the subsequent water washing. At the completion of the water 
washing, the filter elements are re-assembled and transferred to a second 
cleaning vessel in which sodium hydroxide cleaning is performed. The 
filter assembly is again broken down into individual filter elements for 
second water washing. Finally, nitric acid cleaning and third water 
washing are performed in the same manner as stated above to complete the 
chemical cleaning process. 
The physical cleaning process is needed to remove those alien matters or 
particles which may remain adhered to the filter elements even after the 
chemical cleaning process has been over. U.S. Pat. No. 5,151,186 issued to 
Taek J. Yoo et al on Sep. 29, 1992 discloses a filter cleaning system for 
ultrasonically removing contaminants from the filter disk without having 
to resort to the operator's manual operation. The system comprises a 
turntable for holding the filter disks in a stacked condition, a first 
ultrasonic cleaner for applying an ultrasonic field to one side of the 
filter disk, a second ultrasonic cleaner for applying an ultrasonic field 
to the other side of the filter disk, a water injection cleaner for 
removing residual contaminants from the ultrasonically cleaned filter 
disk, a robotic carrier for transporting the filter disk from a particular 
station to another and a controller for governing the overall operation of 
the filter cleaning system. 
While the prior art physical cleaning process has been efficiently 
performed by a specially designed cleaning device, such is not the case 
for the chemical process. In other words, the filter assembly has to be 
manually transferred from one cleaning vessel to another in order to treat 
it with mutually uncompatible chemical agents, which manual operation is 
labor-intensive and time-consuming. Another disadvantage of the prior art 
chemical cleaning lies in that reaction gases are allowed to freely leak 
from the cleaning vessel, which leads to an environmental pollution and 
even to a health hazard. Furthermore, it is very cumbersome and laborious 
to disassemble the filter assembly each time the water wasting begins. 
SUMMARY OF THE INVENTION 
Accordingly, it is an object of the invention to provide a filter assembly 
cleaning apparatus and method that has a capability of efficiently 
cleaning the filter assembly with chemical agents within a shortened 
period of time in a sufficiently automated fashion. 
Another object of the invention is to provide an apparatus for cleaning the 
filter assembly which is able to avoid undesirable leakage of corrosive or 
toxic reaction gases from a cleaning vessel. 
A further object of the invention is to provide a filter assembly cleaning 
method which makes it possible to chemically clean the filter assembly in 
a single cleaner vessel without having to disassemble the filter assembly. 
In one aspect, the present invention resides in an apparatus for use in 
cleaning a filter assembly with chemical agents, the filter assembly 
including an elongate stem and porous filter elements stacked one above 
the other along an axis of the stem, the stem having an axial flow path 
extending from an end aperture to the individual filter elements, which 
comprises: a cleaner vessel for accommodating the filter assembly to clean 
it with a spectrum of chemical detergent liquids in a predetermined 
cleaning sequence; a plurality of reservoirs each communicating with the 
cleaner vessel and holding the chemical detergent liquids which are to be 
fed into the cleaner vessel; a water tank communicating with the cleaner 
vessel and holding water therein, the water tank coupled to the end 
aperture of the filter assembly to allow the water to flow through the 
axial flow path into the cleaner vessel; means for causing the chemical 
detergent liquids to circulate, as a stream, within the cleaner vessel; 
and means responsive to the predetermined cleaning sequence for 
controlling operation of the filter assembly cleaning apparatus. 
In another aspect of the invention, there is provide a method for cleaning 
a filter assembly with chemical agents in a cleaner vessel, the filter 
assembly including an elongate stem and porous filter elements stacked one 
above the other along an axis of the stem, the stem having an axial flow 
path extending from an end aperture to the individual filter elements, 
comprising the steps of: 
(a) placing the filter assembly into the cleaner vessel; 
(b) cleaning the filter assembly with triethylene glycol solution at an 
elevated temperature while circulating the triethylene glycol solution 
within the cleaner vessel; 
(c) upon draining the triethylene glycol solution from the cleaner vessel, 
feeding water under pressure through the axial flow path of the filter 
assembly into the vessel to remove residual triethylene glycol solution; 
(d) cleaning the filter assembly with sodium hydroxide solution while 
circulating the sodium hydroxide solution within the cleaner vessel; 
(e) upon draining the sodium hydroxide solution from the cleaner vessel, 
feeding the water under pressure through the axial flow path of the filter 
assembly into the vessel to remove residual sodium hydroxide solution; 
(f) cleaning the filter assembly with nitric acid solution while 
circulating the nitric acid solution within the cleaner vessel; and 
(g) upon draining the nitric acid solution from the cleaner vessel, feeding 
the water under pressure through the axial flow path of the filter 
assembly into the vessel to remove residual nitric acid solution.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Referring to FIG. 1, the cleaning apparatus embodying the instant invention 
comprises a cleaner vessel 100 receiving therein at least one filter 
assembly 102 preferably carried by a filter carrying basket set forth 
below. Since the filter assembly is fairly heavy in weight, a lifting 
device such as hoist (not shown) has to be employed in placing the filter 
assembly 102 into the cleaner vessel 100. Suitable chemical detergent 
liquids, e.g., triethylene glycol, sodium hydroxide and nitric acid are 
admitted into the cleaner vessel 100 in the stated sequence so as to apply 
chemical cleaning forces of varying nature to the filter assembly 102. 
Water is used to wash out residue of the chemical detergent liquids which 
may be left in the cleaner vessel 100. A stream generator 104 is mounted 
on the side wall of the cleaner vessel 100 to enable the chemical 
detergent liquids to circulate, as a vigorous stream, within the cleaner 
vessel 100. Further details regarding the cleaner vessel 100 will be 
described below with reference to FIGS. 2 and 3. 
Coupled to the right-handed top of the cleaner vessel 100 is a first header 
106, with a second header 108 mounted on the left-handed top thereof. It 
can be seen that a triethylene glycol reservoir 112 communicates with the 
cleaner vessel 112 through a first pipeline 110 and then the first header 
106 mentioned above. The triethylene glycol solution is particularly 
useful in decomposing solid polymeric material stuck to the filter 
assembly 102. Midway of the first pipeline 110, there is provided a heat 
exchanger 114 that serves to preheat the triethylene glycol solution up to 
a temperature of, e.g., 230.degree. C., as it is being fed into the 
cleaner vessel 100. A fluid pump 116 may be used in drawing the 
triethylene glycol solution out of the reservoir 112 to deliver it to the 
cleaner vessel 100 via the heat exchanger 114. The triethylene glycol 
solution so supplied will be converted to a vigorous circulating stream by 
means of the stream generator 104, which stream helps accelerate 
decomposition of the solid polymer. At the termination of the cleaning 
operation, the triethylene glycol solution is drained to the outside 
through a central conduit 132 and a first drainpipe 133. Extending from 
the second header 108 is a second pipeline 118 to which first to third 
branch lines 120, 122 and 124 are connected in parallel relationship with 
one another. The first branch line 120 functions to release therethrough 
those gases created in the process of triethylene glycol cleaning. The 
released gases may be liquefied in a condenser 121 before they are 
returned to the reservoir 112. Likewise, the second branch line 122 is 
designed to release therethrough those gases emitted from the sodium 
hydroxide solution or the nitric acid solution, which gases, in turn, will 
be liquefied by a condenser 123 prior to their returning to the reservoir 
128 or 138. The third branch line 124 is used for the purpose of forcing 
nitrogen gas under pressure from a nitrogen tank 126 into the cleaner 
vessel 100, thereby ensuring that the chemical detergent liquids may be 
drained to the outside in a speedy way. 
Referring still to FIG. 1, a sodium hydroxide solution reservoir 128 is in 
a fluid communication with the cleaner vessel 100 through a third pipeline 
130 and then the central conduit 132. The sodium hydroxide solution 
assists in removing such allen matters as survived the triethylene glycol 
cleaning process. A fluid pump 134 may be employed in drawing the sodium 
hydroxide solution out of the reservoir 128 to deliver it to the cleaner 
vessel 100. Supplied into the vessel 100, the sodium hydroxide solution 
will be converted to a vigorous circulating stream by means of the stream 
generator 104. This facilitates removal of the alien matters from the 
filter assembly 102. Upon completion of the cleaning operation, the sodium 
hydroxide solution is either drained to the outside through the central 
conduit 132 and then a second drainpipe 135, or returned to the reservoir 
128 through the central conduit 132, the third pipeline 130 and then a 
by-pass line 136. The exact choice between draining and returning of the 
used sodium hydroxide solution is largely up to the degree of 
contamination of, that solution. To attain an enhanced cleaning effect, it 
is preferred that the sodium hydroxide solution should be heated to a 
temperature of about 90.degree. C., for instance. 
A nitric acid solution reservoir 138 is in a fluid-communication with the 
cleaner vessel 100 through a fourth pipeline 140 and the central conduit 
132. The nitric acid solution is particularly useful in removing those 
foreign materials which has survived the sodium hydroxide cleaning 
process. A fluid pump 142 may be employed to forcedly feed the nitric acid 
solution from the reservoir 138 to the cleaner vessel 100 wherein the 
nitric acid solution will be converted to a vigorous circulating stream by 
means of the stream generator 104. At the termination of such cleaning 
operation, the nitric acid solution is either drained to the outside 
through the central conduit 132 and the second drainpipe 135, or returned 
to the reservoir 138 through the central conduit 132, the fourth pipeline 
140 and a by-pass line 144. Determination of whether the nitric acid 
solution is to be drained or returned depends on the degree of 
contamination of that solution. It is desirable to maintain the nitric 
acid solution at the ambient temperature. 
A water tank 146 communicates with the cleaner vessel 100 through a fifth 
pipeline 148 and then branch pipes 150 and 152. Each time when the 
triethylene glycol cleaning, the sodium hydroxide cleaning or the nitric 
acid cleaning is over, the water under pressure will be fed into the 
cleaner vessel 100 by a water pump 154 to wash out residual chemical 
agents left in the cleaner vessel 100. To ensure an increased cleaning 
effect, it is desirable to preheat the water up to a temperature of about 
90.degree. C. As will be described below in more detail, the water is 
introduced through an axial flow path of the filter assembly 102 into the 
cleaner vessel 100 and, subsequently, drained to the outside through the 
central conduit 132 and the second drainpipe 135. Supplying the water in 
such a manner will ensure an easier removal of the residual chemical 
agents, alien matters or particles from the filter assembly. During the 
water washing process, the stream generator 104 does not operate at all, 
thus creating no water stream. 
The nitrogen tank 126 is connected, on one hand, to the branch pipes 150 
and 152 through first and second supply lines 156 and 158; and, one the 
other hand, to the branch line 124 through third supply line 160. In the 
process of sodium hydroxide cleaning and nitric acid cleaning, nitrogen 
gas is admitted into the cleaner vessel 100 through the supply lines 156 
and 158 to generate nitrogen bubbles. This is referred to as "bubbling" 
which aids in enhancing the cleaning effect of the filter assembly 102. 
Additionally or alternatively, the nitrogen gas may be supplied into the 
cleaner vessel 100 through the supply lines 156 and 158 and the axial flow 
path of the filter assembly 102, immediately after the sodium hydroxide 
solution or the nitric acid solution has been drained from the cleaner 
vessel 100. This is referred to as "flushing" which assists in removing 
the residual sodium hydroxide or nitric acid. Moreover, the nitrogen gas 
may be employed to accelerate the speed at which the chemical detergent 
liquids are drained from the cleaner vessel 100. In other words, as the 
triethylene glycol solution, the sodium hydroxide solution or the nitric 
acid solution begins to drain from the cleaner vessel 100, the nitrogen 
gas may be introduced into the cleaner vessel 100 through the third supply 
line 160 and the second header 108 to increase the internal pressure of 
the vessel 100, thus ensuring a speedy draining of the chemical detergent 
liquids. 
It should be appreciated that the cleaner vessel 100 is provided with a 
heating device and a cooling device. The heating device consists of a 
coil-shaped or helical heating pipe 162 disposed along the interior 
surface of the cleaner vessel 100 and a heat source 164 for supplying heat 
medium, e.g., hot oil, of an elevated temperature through the heating pipe 
62. Such a heating device serves mainly to increase the temperature of the 
triethylene glycol solution up to 280.degree. C., for example. In 
contrast, the cooling device includes a cooling pipe 166 of sinuous 
configuration affixed in the vicinity of the bottom of the cleaner vessel 
100 and a coolant source 168 for feeding coolant, e.g., cold water, 
through the cooling pipe 166. Such a cooling device functions; to reduce 
the temperature of the triethylene glycol prior to its draining to the 
outside. 
The filter assembly cleaning apparatus of the construction set forth above 
is adapted to operate in accordance with a predetermined control sequence, 
which operation may be controlled by a known programmable controller. 
Referring now to FIGS. 2 and 3, there is shown a preferred embodiment of 
the cleaner vessel 100 that has a cleaning chamber enough in capacity to 
receive, e.g., about 2,000 litters of the chemical detergent liquids. As 
shown, the cleaner vessel 100 comprises a bottom wall 170 of an inverted 
arch shape, a cylindrical side wall 172 extending upward from the bottom 
wall 170 and a tapering neck 176 forming a further extension of the side 
wall 172. The neck 176 terminates at an access opening 174 which may be 
openably covered by a cover plate 178. In addition, integrally formed with 
the side wall 172 is a lateral casing 180 that communicates with the 
cleaning chamber of the cleaner vessel 100 through a lower inlet port 182 
and an upper outlet port 184. The stream generator 104 is mounted on the 
lateral casing 180. In a preferred embodiment, the stream generator 104 
includes an electric motor 186 fixedly attached on the top of the casing 
180 and an impeller 188 projecting into the casing 180 from the electric 
motor 186. The impeller 188 is operatively connected to the motor 186 such 
that, when driven by the motor 186, the impeller 188 can forcedly 
circulate the chemical detergent liquids contained within the cleaning 
chamber in the direction as indicated by arrows, thereby generating a 
vigorous stream of the chemical detergent liquids. 
As set forth hereinabove, the first header 106 and the second header 108 
are connected to the neck 176 off the cleaner vessel 100 in the form of a 
mirror image with respect to one another. The first header 106 serves as a 
fluid passageway through which the triethylene glycol solution reservoir 
112 communicates with the cleaner vessel 100. Provision of the second 
header 108 is either to release therethrough such gases as created in the 
cleaning process or to introduce nitrogen gas into the cleaner vessel 100. 
Coupled to the bottom wall 170 of the cleaner vessel 100 is the central 
conduit 132 that functions, on one hand, as a supply path for feeding the 
sodium hydroxide solution or the nitric acid solution to the cleaner 
vessel 100 and, on the other hand, as a drain path for discharging the 
triethylene glycol solution, the sodium hydroxide solution, the nitric 
acid solution or the water from the cleaner vessel 100. A level indicator 
190 may be connected to the cleaner vessel 100 so as to enable the 
operator to visually observe the level of the liquids contained in the 
cleaner vessel 100. 
Within the cleaner vessel 100 and adjacent to the bottom wall 170 thereof, 
a platform 192 is located to stably support filter carrying baskets 194 
which will be described below in more detail. Although the platform 192 
shown in FIGS. 2 and 3 is constructed to support three of such baskets 194 
at a time, it would be possible to modify the configuration of the 
platform 192 so that greater or fewer baskets can be supported by the 
platform 192. The branch pipes 150, 152 and 153 that correspond to each of 
the baskets 194 are directly connected to the platform 192. It can be seen 
in FIG. 1 that the branch pipes 150, 152 and 153 lead to the water tank 
146 via the pipeline 148. Along the interior surface of the side wall. 
172, the helical heating pipe 162 is held in position by means of a rigid 
beam 196 in order to heat, e.g., a triethylene glycol solution up to the 
temperature of about 280.degree. C. On the underlying surface of the 
platform 192, the cooling pipe 166 is disposed in a sinuous pattern for 
the purpose of cooling down the heated triethylene glycol solution to a 
permissible temperature before it is drained to the outside. 
As shown in FIG. 4, the platform 192 includes a base frame 198 and first to 
third bearing seats 200, 202 and 204 on which the filter carrying baskets 
may be placed. It is apparent from FIG. 5 that each of the bearing seats 
200, 202 and 204 has a central boss 208 with a tapering lateral surface 
206 and at least two wedge-like diametrically disposed rim segments 212 
with an inwardly downwardly slanted surface 210. As will be explained 
below, each of the filter carrying baskets 194 has an underlying surface 
generally complementary to the bearing seat 200, 202 and 204. For this 
reason, there is no likelihood of misalignment between the specific basket 
and the corresponding bearing seat, even when the basket is landed on the 
bearing seat in a somewhat misaligned condition. The central bosses 208 
constituting each of the bearing seats 200, 202 and 204 have through-holes 
214, 216 and 218 with which are threadedly engaged the branch pipes 150, 
152 and 153. 
Referring to FIGS. 6 and 7, there is shown a typical filter assembly 102 
which may be cleaned by the cleaning apparatus in accordance with the 
invention. As shown, the filter assembly 102 comprises an elongate stem 
220 which, in turn, is formed with a shaft portion 222 and a head portion 
224. The shaft portion 222 has a plurality of axial grooves 226 extending 
along the length thereof, while the head portion 224 is provided with an 
end aperture 228 leading to the axial grooves 226 of the shaft portion 
222. It should be understood that the axial grooves 225 cooperate with the 
end aperture 228 to define an axial flow path of the filter assembly 102. 
A disk-like spacer 229 is slidingly combined along the shaft portion 222 
of the stem 220. The filter assembly 102 further comprises a plurality of 
porous filter elements 230 which are stacked one above the other along the 
shaft portion 222. Each of the filter elements 230 has fine perforations 
232, on its major surfaces, that will stop any contaminants or alien 
matters present in the molten polymer while allowing the molten polymer to 
flow therethrough toward the axial flow path of the filter assembly 102. A 
cover plate 234 is placed on the lastly stacked filter element to complete 
the filter assembly 102, which cover plate has a hook 236 pivotably 
attached thereto. 
Referring to FIG. 8, there is shown, by way of example, a preferred filter 
carrying basket 194 which comprises a bottom plate 238, a generally 
cylindrical side wall 240 extending upward from the bottom plate 238 and 
terminating at a top opening 239, a lid 242 covering the top opening 239 
of the side wall 240 and a lift bar 244 pivotably mounted on the top edge 
of the side wall 240 to extend transversely over the top opening 239. The 
bottom plate 238 has an underlying surface which is complementary to the 
bearing seat of the platform 192, as best shown in FIG. 5. Furthermore, 
the bottom plate 238 is formed with a tapering bore 246 and a recess 248 
adjoining the bore 246. Seated in the recess 248 is a spacer block 250 on 
which the filter assembly 102 is placed in an end-to-end relationship. The 
spacer block 250 will be described later with reference to FIGS. 11 and 
12. 
As depicted microscopically within a circle 252 in FIG. 8, the side wall 
240 of the basket 194 consists of an inner rigid layer 254, an 
intermediate mesh layer 256 and an outer rigid layer 258. Through the 
thickness of the inner and the outer rigid layers 254 and 258, a multiple 
number of fluid communication holes 260 are formed to allow the chemical 
detergent liquids to flow into or out of the basket 194. The intermediate 
mesh layer 256 serves to prevent solid matters or particles from escaping 
out of the basket 194, which would otherwise cause a trouble in the 
cleaning apparatus. 
Turning to FIGS. 9 and 10, the silk hat-shaped lid 242 of the filter 
carrying basket 194 has a cylindrical flank wall 262, a top wall 266 and a 
flange 268 extending radially outwardly from the lower edge of the flank 
wall 262. As with the side wall 240 of the basket 194, the top wall 266 
consists of an inner rigid layer 270, an intermediate mesh layer 272 and 
an outer rigid layer 274. The inner and the outer rigid layers 270 and 274 
are provided with a number of fluid communication holes 264. The flange 
268 of the lid 242 has a couple of cutouts 276 that will permit the lift 
bar 244 (see FIG. 8) to be mounted on the edge of the side wall. 240 of 
the basket 194. 
Referring to FIGS. 11 and 12, there is shown a preferred spacer block 250 
adapted to be held in place between the filter assembly 102 and the bottom 
plate 238 of the basket 194. As shown, the spacer block 290 includes a 
raised region 278 coming into engagement with the end aperture 228 of the 
filter assembly 102, an underlying recess 280 receiving a top portion of 
the central boss 208 of the platform 192, a central channel 284 formed 
through the thickness of the spacer block 250, an upper stopper 286 having 
a crisscross slot 287, a lower stopper 288 spaced apart from the upper 
stopper 286 and a ball checker 282 trapped within the central channel 284 
for movement between an upper position(indicated by a solid line) in which 
the water is allowed to pass through the central channel 284 and a lower 
position(indicated by a phantom line) in which the central channel 284 is 
completely clogged by the ball checker 282. During the process of chemical 
cleaning, the ball checker 282 is kept in the lower position to prevent 
any solid particles from escaping through the central channel 284 out of 
the cleaner vessel 100. 
Referring to FIG. 12, the sodium hydroxide solution reservoir 128 comprises 
a cylindrical side wall 290, an inverted arch-shaped bottom wall 292 and 
an arch-shaped top wall 294. At the center of the bottom wall 292, there 
is provided a drainpipe 296 which may feed therethrough the sodium 
hydroxide solution to the cleaner vessel 100 and which communicates with a 
level indicator 300 through a horizontal pipe 298. At the center of the 
top wall 294, there is provided a supply pipe 302 which has a water inlet 
port 304 and a sodium hydroxide inlet port 306. Also secured to the top 
wall 294 are a vent pipe 308 and a vacuum prevention pipe 310. 
As best shown in FIG. 14, the nitric acid solution reservoir 138 has a 
cylindrical side wall 312, an inverted arch-shaped bottom wall 314 and an 
arch-shaped top wall 316. At the center of the bottom wall 314, there is 
provided a drainpipe 318 which may feed therethrough the nitric acid 
solution to the cleaner vessel 100 and which communicates with a level 
indicator 322 through a horizontal pipe 320. At the center of the top wall 
316, there is provided a supply pipe 324 which has a water inlet port 328 
and a nitric acid inlet port 330. Also secured to the top wall 316 are a 
vent pipe 332 and a vacuum prevention pipe 334. Unlike the sodium 
hydroxide solution reservoir 128, the nitric acid solution reservoir 138 
further includes a helical cooling pipe 336 disposed adjacent to the 
interior surface of the side wall 312. The cooling pipe 336 has an inlet 
port 338 projecting from the bottom wall 314 and an outlet port 340 
projecting from the side wall 312. Thus, the nitric acid solution may be 
cooled down to the ambient temperature by way of circulating the coolant 
through the cooling pipe 336. 
In FIGS. 15 and 16, support beams 342 are employed to hold the cooling pipe 
336 in position within the nitric acid solution reservoir 138. The support 
beams 342 may be affixed to the side wall 312 of the reservoir 138 by any 
suitable means such as a welding or a bolt/nut fastener. Along the length 
of the support beams 342, several slots 344 are formed at a substantially 
uniform interval so that each convolution of the cooling pipe 336 can be 
inserted therethrough as clearly shown in FIG. 14. Although four of the 
support beams 342 are shown in FIG. 16, the exact number of the support 
beams 342 can be greater or fewer depending on the particular design of 
the nitric acid solution reservoir 138. 
Referring to FIG. 17, the water tank 146 comprises a cylindrical side wall 
346, an inverted arch-shaped bottom wall 348 and an arch-shaped top wall 
350. At the center of the bottom wall 348, there is provided a drainpipe 
352 which may feed therethrough the water to the cleaner vessel 100. The 
drainpipe 352 communicates with the level indicator 356 through an 
horizontal pipe 354. A water supply pipe 358 is connected to the center of 
the top wall 350 with a vent pipe 360 secured adjacent to the water supply 
pipe 358 on the top wall 350. In the vicinity of the drainpipe 352, a 
temperature detection pipe 362 is secured to the bottom wall 348. 
Moreover, the water tank 146 further comprises a helical heating pipe 364 
disposed adjacent to the interior surface of the side wall 346. The 
heating pipe 364 has an inlet port 366 projecting from the side 346 and an 
outlet port 368 projecting from the bottom wall 348. Accordingly, the 
water contained in the water tank 146 may be heated to a temperature of, 
e.g., 90.degree. C. by way of circulating the heating medium through the 
helical heating pipe 364. As illustrated in FIG. 17, the heating pipe 364 
is held in position by means of support beams 370. The foregoing 
description on the support beams 342 made in conjunction with FIGS. 15 and 
16 holds true for the support beams 370 shown in FIG. 17. 
In the following, description will be made on how to carry out the cleaning 
method in accordance with the invention. 
The inventive cleaning method may be advantageously employed in cleaning 
the used filter assembly with chemical agents in a single cleaner vessel. 
As a matter of basic concept, the filter assembly cleaning method 
comprises the steps of: (a) placing the filter assembly into the cleaner 
vessel; (b) cleaning the filter assembly with triethylene glycol solution 
at an elevated temperature while circulating the triethylene glycol 
solution within the cleaner vessel; (c) upon draining the triethylene 
glycol solution from the cleaner vessel, feeding water under pressure 
through the axial flow path of the filter assembly into the vessel to 
remove residual triethylene glycol solution; (d) cleaning the filter 
assembly with sodium hydroxide solution while circulating the sodium 
hydroxide solution within the cleaner vessel; (e) upon draining the sodium 
hydroxide solution from the cleaner vessel, feeding the water under 
pressure through the axial flow path of the filter assembly into the 
vessel to remove residual sodium hydroxide solution; (f) cleaning the 
filter assembly with nitric acid solution while circulating the nitric 
acid solution within the cleaner vessel; and (g) upon draining the nitric 
acid solution from the cleaner vessel, feeding the water under pressure 
through the axial flow path of the filter assembly into the vessel to 
remove residual nitric acid solution. 
It is desirable that the triethylene glycol cleaning step and the water 
washing step should be repeated once more after step(c) has been 
completed. The triethylene glycol cleaning step is preferably performed at 
a temperature of from 275.degree. C. to 285.degree. C. to attain a 
maximized cleaning effect. The sodium hydroxide cleaning step may be 
carried out once more, followed by another water washing step, when 
step(e) has been over. Likewise, the nitric acid cleaning step may be 
repeated once more together with the water washing step, at the 
termination of step(g). If desired, nitrogen gas under pressure may be 
admitted into the cleaner vessel, while performing steps(d) and (f). 
Referring to FIG. 18, there is schematically shown a cleaning method in 
accordance with the particularly preferred embodiment of the invention. As 
shown, the cleaning method comprises eleven steps wherein four sorts of 
cleaning or washing operations labelled by A, B, C and D are carried out 
at the predetermined number of times under the control of a programmable 
controller. 
In Step 1, the used filter assemblies are placed within the cleaner vessel 
through the use of a conventional lifting device. The cleaner vessel in 
then filled with the triethylene glycol solution(TEG) of about 2,000 
litters which, in turn, is heated to a temperature of 280.degree. C. by a 
heating device. The triethylene glycol cleaning is carried out for a time 
period of about 6 hours during which the triethylene glycol solution 
continues to circulate, as a vigorous stream, within the cleaner vessel. 
At the completion of the triethylene glycol cleaning, the waste solution 
is cooled down to a temperature of 100.degree. C. or less and drained to 
the outside. 
In Step 2, the water(H.sub.2 O) under pressure is fed into the cleaner 
vessel through the axial flow path of the individual filter assembly to 
wash out residual triethylene glycol left in the cleaner vessel. To ensure 
an increased washing effect, it is desirable to use pure water preheated 
to a temperature of about 90.degree. C. The time required in the water 
washing step is in the order of 25 minutes. 
In Steps 3 and 4, the triethylene glycol cleaning and the water washing are 
performed once more in the same manner as explained above. These steps are 
optional and, therefore, may be omitted from the cleaning process. 
In Step 5, the cleaner vessel is filled with the sodium hydroxide 
solution(NaOH) at a temperature of about 95.degree. C. The sodium 
hydroxide cleaning is performed for a time period of 3 hours by way of 
forcedly circulating the sodium hydroxide solution within the cleaner 
vessel. Nitrogen gas may be fed into the cleaner vessel to promote the 
cleaning action of the sodium hydroxide solution. At the end of Step 5, 
the sodium hydroxide solution is drained out of the cleaner vessel. In 
case where the waste sodium hydroxide solution is not heavily 
contaminated, it may be returned to the sodium hydroxide reservoir for 
reuse in the later step or another cleaning process. 
In Step 6, the water washing is carried out in the same manner as in Step 2 
to wash out residual sodium hydroxide left in the cleaner vessel. 
In Step 7, the cleaner vessel is filled with the nitric acid 
solution(HNO.sub.3) at the ambient temperature. The nitric acid cleaning 
is performed for a time period of 30 minutes by way of forcedly 
circulating the nitric acid solution within the cleaner vessel. As in Step 
5, nitrogen gas may be fed into the cleaner vessel to promote the cleaning 
action of the nitric acid solution. At the termination of Step 7, the 
nitric acid solution may be either drained to the outside or returned to 
the nitric acid reservoir for reuse in the later step. 
In Steps 8 and 9, the sodium hydroxide cleaning and the water washing are 
repeated once more in the same manner as Steps 5 and 6. 
Finally, in Steps 10 and 11, the nitric acid cleaning and the water washing 
is performed once more in the same manner as stated above to complete the 
overall cleaning process. It should be understood that Steps 8 to 11 are 
optional and, therefore, omitted from the cleaning process. 
While the present invention has been shown and described with reference to 
the particular embodiments, it will be apparent to those skilled in the 
art that many changes and modifications may be made without departing from 
the spirit and scope of the invention as defined in the appended claims.