U.S. patent application number 12/476853 was filed with the patent office on 2009-10-08 for aluminum hydroxide aggregated particles, process for producing the same, vessel used therefor, and process for producing aluminum hydroxide powder.
Invention is credited to Naoyuki Eguchi, Hisakatsu Kato, Hirofumi Sasaki, Masashi Wada.
Application Number | 20090252964 12/476853 |
Document ID | / |
Family ID | 26624398 |
Filed Date | 2009-10-08 |
United States Patent
Application |
20090252964 |
Kind Code |
A1 |
Kato; Hisakatsu ; et
al. |
October 8, 2009 |
ALUMINUM HYDROXIDE AGGREGATED PARTICLES, PROCESS FOR PRODUCING THE
SAME, VESSEL USED THEREFOR, AND PROCESS FOR PRODUCING ALUMINUM
HYDROXIDE POWDER
Abstract
Aluminum hydroxide aggregated particles which have an average
particle diameter of not less than 40 .mu.m, an average particle
diameter as determined after pressing at 1,000 kg/cm.sup.2 of not
more than 35 .mu.m, and an L value of slurry obtained by mixing 20
ml of glycerol and 10 g of the aluminum hydroxide aggregated
particles of not more than 69, are obtained by a process comprising
the steps of: (a) feeding a supersaturated aqueous sodium aluminate
solution to a vessel, (b) adding aluminum hydroxide seeds to the
supersaturated aqueous sodium aluminate solution, (c) stirring the
seed-added solution in the vessel while continuously feeding an
additional supersaturated aqueous sodium aluminate solution into
the vessel to hydrolyze the supersaturated aqueous sodium aluminate
solution, (d) separating the aluminum hydroxide aggregated
particles from the aqueous sodium aluminate solution, and (e)
continuously discharging the aqueous sodium aluminate solution out
of the vessel.
Inventors: |
Kato; Hisakatsu;
(Niihama-shi, JP) ; Wada; Masashi; (Niihama-shi,
JP) ; Eguchi; Naoyuki; (Niihama-shi, JP) ;
Sasaki; Hirofumi; (Niihama-shi, JP) |
Correspondence
Address: |
BIRCH STEWART KOLASCH & BIRCH
PO BOX 747
FALLS CHURCH
VA
22040-0747
US
|
Family ID: |
26624398 |
Appl. No.: |
12/476853 |
Filed: |
June 2, 2009 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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11748396 |
May 14, 2007 |
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12476853 |
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10289429 |
Nov 7, 2002 |
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11748396 |
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Current U.S.
Class: |
428/402 |
Current CPC
Class: |
B01F 7/00208 20130101;
B01F 7/1675 20130101; B01F 7/00641 20130101; B01F 7/22 20130101;
C01P 2004/50 20130101; B01J 19/1812 20130101; C01F 7/14 20130101;
B01F 2215/0477 20130101; C01P 2004/61 20130101; B01F 2215/0431
20130101; C01F 7/147 20130101; B01J 19/0066 20130101; B01F
2215/0472 20130101; C01F 7/02 20130101; C01F 7/144 20130101; C09C
1/407 20130101; C01P 2006/60 20130101; B01J 19/006 20130101; Y10T
428/2982 20150115; B01F 2215/044 20130101; B01J 2219/00768
20130101; B01F 15/00837 20130101 |
Class at
Publication: |
428/402 |
International
Class: |
B32B 5/16 20060101
B32B005/16 |
Foreign Application Data
Date |
Code |
Application Number |
Nov 7, 2001 |
JP |
2001-342358 |
Nov 7, 2001 |
JP |
2001-342359 |
Claims
1. A filler for resins comprising aluminum hydroxide aggregated
particles, which have an average particle diameter of not less than
40 .mu.m, an average particle diameter as determined after pressing
at 1,000 of not more than 35 .mu.m, and an L value of slurry
obtained by mixing 20 ml of glycerol and 10 g of the aluminum
hydroxide aggregated particles of not more than 69.
2. The filler for resins according to claim 1, wherein the L value
of slurry is not more than 65.
Description
[0001] This application is a Continuation of co-pending application
Ser. No. 11/748,396, filed on May 14, 2007. Application Ser. No.
11/748,396 is a Divisional of application Ser. No. 10/289,429,
filed on Nov. 7, 2002, the entire contents of which are hereby
incorporated by reference and for which priority is claimed under
35 U.S.C. .sctn. 120.
BACKGROUND OF THE INVENTION
[0002] This invention relates to a process for producing aluminum
hydroxide powder which makes it possible to obtain a
filler-containing resin composition having an improved
transparency, aluminum hydroxide aggregated particles which are the
material therefor, a process for producing the same, and a vessel
used therefor.
[0003] Aluminum hydroxide powder is often used as a filler for
resins, such as unsaturated polyester resin, in producing
artificial marble and the like. When aluminum hydroxide powder is
used as a filler for artificial marble and the like, the powder is
required to be excellent in filling property for resins and, at the
same time, not to impair the transparency of resulting resin
compositions.
[0004] As to an industrial process for producing aluminum
hydroxide, there has hitherto been known a process which comprises
hydrolyzing a supersaturated aqueous sodium aluminate solution in
the presence of seeds. For example, JP 63-23131 B discloses a
process which comprises connecting plural vessels in series,
feeding a supersaturated aqueous sodium aluminate solution
continuously to the first vessel, hydrolyzing the supersaturated
aqueous sodium aluminate solution in the presence of seeds, and
allowing hydrolysis to proceed while sending the solution
successively to the second vessel and the third vessel, to obtain
aluminum hydroxide.
[0005] However, even when the aluminum hydroxide obtained by the
above-mentioned process is filled in resins, it has been impossible
to obtain a resin composition having a sufficient transparency.
[0006] The object of this invention is to provide aluminum
hydroxide aggregated particles which can be suitably used for
producing aluminum hydroxide powder which can give a resin
composition that shows a high transparency when filled in resins or
the like, a process for producing the aggregated particles, a
vessel used therefor, and a process for producing aluminum
hydroxide powder which uses the aggregated particles.
BRIEF DESCRIPTION OF THE DRAWINGS
[0007] FIG. 1 is a schematic sectional view showing one embodiment
of a vessel according to this invention.
[0008] FIG. 2 is a schematic transverse sectional view of the
vessel shown in FIG. 1.
[0009] The reference numerals in the Figures signify the
following.
[0010] 1 concentrating region, 2 clarifying region, 3 vessel, 4
baffle plate, 5 stirring blades, 6 rotating shaft, 7 stirrer, 8
sweeper, 9 offtake port, 10 anticorrosive material, 11
straightening vane
SUMMARY OF THE INVENTION
[0011] The present inventors have made extensive study to solve the
above-mentioned problems, and resultantly completed this
invention.
[0012] Thus, according to this invention, there are provided
aluminum hydroxide aggregated particles, which have an average
particle diameter of not less than 40 .mu.m, an average particle
diameter as determined after pressing at: 1,000 kg/cm.sup.2 of not
more than 35 .mu.m, and an L value of slurry obtained by mixing 20
ml of glycerol and 10 g of the aluminum hydroxide aggregated
particles of not more than 69.
[0013] According to this invention, there is further provided a
process for producing aluminum hydroxide aggregated particles
comprising the steps of:
(a) feeding a supersaturated aqueous sodium aluminate solution to a
vessel, (b) adding aluminum hydroxide seeds to the supersaturated
aqueous sodium aluminate solution to form a seed-added solution in
the vessel, (c) stirring the seed-added solution in the vessel
while continuously feeding an additional supersaturated aqueous
sodium aluminate solution into the vessel to hydrolyze the
supersaturated aqueous sodium aluminate solution to obtain aluminum
hydroxide aggregated particles and an aqueous sodium aluminate
solution, (d) separating the aluminum hydroxide aggregated
particles from the aqueous sodium aluminate solution, and (e)
continuously discharging the aqueous sodium aluminate solution out
of the vessel.
[0014] According to this invention, there is further provided a
process for producing aluminum hydroxide powder which comprises
disintegrating the aluminum hydroxide aggregated particles obtained
as above.
[0015] According to this invention, there is further provided a
vessel used for the above-mentioned process for producing aluminum
hydroxide aggregated particles, that is, a vessel having a hollow
space defined by a surrounding wall and a bottom part, wherein the
vessel has:
[0016] a supply port at a lower portion of the wall,
[0017] two or more baffle plates mounted on an inner surface of the
wall so that the baffle plates protrude toward the hollow space and
extend in vertical direction along the inner surface of the wall
from immediately above the bottom part to a prescribed height from
the bottom part, and
[0018] a stirring blade located within the hollow space and within
a space below the prescribed height of the baffle plates.
DETAILED DESCRIPTION OF THE INVENTION
[0019] The aluminum hydroxide aggregated particles (hereinafter
referred to as "aggregated particles") of this invention have an
average particle diameter of 40 .mu.m or more, preferably 50 .mu.m
or more, more preferably 60 .mu.m or more, and has an average
particle diameter, as determined after pressed at 1,000
kg/cm.sup.2, of not more than 35 .mu.m. The aggregated particles
are each an assembly of at least 2, preferably 8 or more primary
particles. For the aggregated particles, the average particle
diameter determined after pressing is smaller than the average
particle diameter before pressing, and the difference of average
particle diameter before and after pressing is usually not less
than 5 .mu.m. The fact that the average particle diameter
determined after pressing is smaller indicates that the cohesive
force of the aggregated particle is weak and the particle is easily
disintegrated to yield primary particles. The average particle
diameter mentioned above can be determined with a laser scattering
type particle distribution measuring apparatus.
[0020] In the aggregated particles of this invention, a slurry
obtained by mixing 20 ml of glycerol and 10 g of aggregated
particles shows an L value of not more than 69 in the Lab
indication system specified by Commission International de
l'Eclairage. Aggregated particles showing an L value higher than
69, even when they are disintegrated and filled in resins, cannot
give a resin composition having a high transparency. The L value of
aggregated particles is the smaller the better, and is, for
example, preferably not more than 65, more preferably not more than
63.
[0021] The aggregated particles of this invention having
characteristic properties shown above can be obtained, for example,
by a process which comprises the steps of (a) feeding a
supersaturated aqueous sodium aluminate solution to a vessel, (b)
adding aluminum hydroxide seeds (hereinafter abbreviated as
"seeds") to the supersaturated aqueous sodium aluminate solution to
form a seed-added solution in the vessel, (c) stirring the
seed-added solution in the vessel while continuously feeding an
additional supersaturated aqueous sodium aluminate solution into
the vessel, to hydrolyze the supersaturated aqueous sodium
aluminate solution to obtain aggregated particles, (d) separating
the aggregated particles from the aqueous sodium aluminate
solution, and (e) continuously discharging the aqueous sodium
aluminate solution out of the vessel.
[0022] In step (a), the supersaturated aqueous sodium aluminate
solution fed into the vessel preferably has an effective Na.sub.2O
(caustic Na.sub.2O) concentration of about 120-180 g/l, an
Al.sub.2O.sub.3 concentration of about 120-180 g/l and a molar
ratio (Na.sub.2O/Al.sub.2O.sub.3) of about 1.2-1.8. The term
"effective Na.sub.2O" refers to a value obtained by subtracting
Na.sub.2CO.sub.3 content (in terms of Na.sub.2O) from the total
Na.sub.2O content in the aqueous sodium aluminate solution. The
supersaturated aqueous sodium aluminate solution can be prepared,
for example, by a method which comprises mixing bauxite with an
aqueous sodium hydroxide solution, heating the resulting mixture at
120.degree. C. or above to extract the alumina component in the
bauxite, then subjecting the mixture to separation for example with
a thickener, filtering the aqueous sodium aluminate solution thus
obtained, and cooling the filtrate, or a method which comprises
mixing aluminum hydroxide with sodium hydroxide, heating the
mixture at 120.degree. C. or above to dissolve aluminum hydroxide,
subjecting the mixture to separation, e.g., filtration, and cooling
the aqueous sodium aluminate solution thus obtained. The
supersaturated aqueous sodium aluminate solution can also be
prepared by a method which comprises mixing aluminum hydroxide with
a saturated aqueous sodium aluminate solution after hydrolysis or
an unsaturated aqueous sodium aluminate solution heating the
mixture at 120.degree. C. or above to dissolve aluminum hydroxide,
followed by filtration, and cooling the aqueous sodium aluminate
solution thus obtained.
[0023] The seeds added in step (b) preferably have an average
particle diameter of about 1-2 .mu.m. The seeds prepared by a
method which comprises, without resorting to grinding, adding an
acid aluminum salt, such as aluminum sulfate, to an aqueous sodium
aluminate solution to cause hydrolysis are more preferable than
those obtained by grinding coarse aluminum hydroxide. Addition of
seeds can shorten the induction period which elapses till aluminum
hydroxide is formed by hydrolysis of the supersaturated aqueous
sodium aluminate, as well as control the particle diameter of
aluminum hydroxide powder ultimately obtained. The amount of seeds
can be appropriately determined according to the particle diameter
of the intended aluminum hydroxide powder.
[0024] The stirring in step (c) is conducted, for example, by using
a mechanical stirrer. The peripheral velocity of the stirring blade
is preferably 0.1 m/s or more. The peripheral velocity is
preferably not more than 5 m/s.
[0025] The separation in step (d) can be conducted, for example, by
a method which utilizes specific gravity difference between the
aggregated particles and the aqueous sodium aluminate solution.
Through the separation, usually the aggregated particles move
toward the lower part of the vessel and the aqueous sodium
aluminate solution moves toward the upper part of the vessel, so
that the aggregated particles sediment at the lower part of the
vessel to give a slurry having a high solid concentration. The
slurry has a concentration of solid (aggregated particles) of
preferably 600 g/l or more, more preferably 700 g/l or more, and
preferably not more than 1000 g/l, more preferably not more than
900 g/l.
[0026] In step (e), the aqueous sodium aluminate solution
discharged out of the vessel preferably has an effective Na.sub.2O
(caustic Na.sub.2O) concentration of about 120-180 g/l, an
Al.sub.2O.sub.3 concentration of about 60-80 g/l and a molar ratio
(Na.sub.2O/Al.sub.2O.sub.3) about 2-3.5.
[0027] The above-mentioned steps (a), (b), (c), (d) and (e) are
preferably conducted in a single vessel. One example of the vessel
used herein is shown in FIG. 1. The vessel 3 has at its lower part
a supply port (not shown in the Figure) and baffle plates 4. The
baffle plates 4, as shown in FIG. 2, protrude from the inner
circumferential surface of the wall of vessel 3 and are provided in
plurality (e.g., 2-10) at predetermined intervals in the peripheral
direction of vessel 3. Each of the baffle plates 4 extrudes from
immediately above the bottom part of vessel 3 long along the
vertical direction (the direction of the rotating shaft) of vessel
3. By baffle plates 4 thus provided, stirring efficiency is
improved and, at the time of stirring, an ascending current is
formed along the inner surface of the wall of vessel 3, whereby the
slurry in the concentrating region 1 specified by the height of
baffle plates 4 can be brought to a substantially complete mixings
state. As the result of the aqueous sodium aluminate solution being
hydrolyzed in the concentrating region 1 at the complete mixing
state, aggregated particles which have only a weak cohesive force
and are easily disintegrated can be obtained. The reachable height
of the ascending current is influenced by the height of baffle
plates 4. The more the height of baffle plates 4 is increased, the
higher point the ascending current reaches, and the concentrating
region 1 increases in size. Usually the upper end of baffle plates
4 and the upper end of the concentrating region 1 are approximately
at the same level. The height of baffle plates 4 is, relative to
the total height of the vessel 3, preferably 50% or more, more
preferably 70% or more, most preferably 75% or more, and preferably
not more than 90%, and more preferably not more than 80%. Vessel 3
has a stirrer 7 which consists of a stirring blade 5 and a rotating
shaft 6 which drives blade 5. Stirring blade 5 is, for example, a
stirring vane and is provided in concentrating region 1. Rotating
shaft 6 is usually provided at the center of the section,
perpendicular to the longitudinal direction, of vessel 3. By the
rotation of stirring blade 5, the slurry of concentrating region 1
is stirred. At the lower end part of rotating shaft 6, a sweeper 8
is provided. With the aid of sweeper 8, sedimentation of aggregated
particles to the bottom part of vessel 3 can be prevented.
[0028] When the aggregated particles are produced by using vessel
3, in vessel 3 are formed a concentrating region 1 and, above
concentrating region 1, a clarifying region 2. With vessel 3 alone,
in addition to the hydrolysis of the supersaturated aqueous sodium
aluminate solution and the separation of the aggregated particles
from the aqueous sodium aluminate solution, concentration of the
aggregated particles can also be conducted.
[0029] The internal circumferential surface of the wall of vessel 3
below the height not higher than baffle plates 4 and the inner
surface of the bottom part of the vessel are preferably lined with
an anticorrosive material 10. The anticorrosive material used can
be, for example, metallic materials, such as stainless steel,
nickel, nickel alloy and titanium; inorganic materials, such as
ceramics; and organic materials, such as fluororesins. The lining
can be conducted, for example, by a method of flame-coating or
baking the above-mentioned metallic materials or inorganic
materials; by a method of welding or adhering a plate-formed
metallic material having a thickness of 1 mm or more, preferably 2
mm or more, and not more than 10 mm, preferably not more than 3 mm;
or by a method of adhering an organic material. With anticorrosive
material 10 being thus lined, the corrosion of the internal surface
of the wall of vessel 3 which is in contact with concentrating
region 1 can be prevented and the coloring of aluminum hydroxide
powder ultimately obtained can be decreased. For example, when 10 g
of methyl methacrylate and 18 g of the aluminum hydroxide powder
obtained are mixed, the resulting slurry shows a b value of not
more than 3, preferably not more than 2, in the Lab indication
system specified by Commission International de l'Eclairage. The
smaller b value indicates the lower coloring.
[0030] On the inner circumferential surface of the wall of vessel 3
contacting with clarifying region 2 are provided in protrusion a
plurality (e.g., 2-8) of straightening vanes 11. These
straightening vanes 11 play the role of promoting the separation of
the aqueous sodium aluminate solution and the aggregated particles,
formed by hydrolysis, from each other in concentrating region 1 and
improving the clarity of the aqueous sodium aluminate solution. The
number and the size of the straightening vane 11 are not
particularly limited so long as the clarifying effect for the
liquid is not impaired. Since the aggregated particles are
substantially not present in clarifying region 2, the inner surface
of vessel 3 contacting with clarifying region 2 needs not be lined
with anticorrosive material 10. The aqueous sodium aluminate
solution in clarifying region 2 is discharged from the discharge
port (not shown in the Figure) provided at the upper part of vessel
3 to the outside of vessel 3.
[0031] In producing aluminum hydroxide powder by using the
above-mentioned vessel, first a predetermined amount of a
supersaturated aqueous sodium aluminate solution is fed into vessel
3 so that the content of the vessel can be stirred. Seeds are added
to vessel 3, stirrer 7 is driven, then a supersaturated aqueous
sodium aluminate solution is continuously fed to vessel 3 and,
while the content is being stirred, the supersaturated aqueous
sodium aluminate solution is hydrolyzed. When the feeding of the
supersaturated aqueous sodium aluminate solution to vessel 3 is
continued, the liquid level rises and reaches the upper end of
baffle plate 4 and, when the feeding is further continued, reaches
the discharge port provided at the upper part of the vessel 3. In
vessel 3, as the result of separation, aggregated particles and an
aqueous sodium aluminate solution are obtained. The solid
(aggregated particles) concentration in concentrating region 1
increases gradually. On the other hand, the aqueous sodium
aluminate solution is discharged from the discharge port provided
at the upper part of vessel 3 to the outside of vessel 3.
Thereafter, an operation which comprises feeding a supersaturated
aqueous sodium aluminate solution from the lower part of vessel 3
and discharging the same amount of an aqueous sodium aluminate
solution is conducted continuously. By this operation, the solid
concentration in concentrating region 1 increases according to the
amount of supersaturated aqueous sodium aluminate solution fed
continuously. Through the above-mentioned series of operation, the
temperature of vessel 3 is kept at 45.degree. C. or above,
preferably at 50.degree. C. or above, and at 80.degree. C. or
below, preferably at 60.degree. C. or below. At the time when the
average particle diameter of aggregated particles has reached a
predetermined value (for example 80 .mu.m), the feeding of
supersaturated aqueous sodium aluminate solution is discontinued,
and the reaction mixture is kept for a predetermined time with
stirring. At this time, the solid concentration of concentrating
region 1 is preferably 600 g/l or more, more preferably 700 g/l or
more, and preferably not more than 1,000 g/l, more preferably not
more than 900 g/l. The time during which the supersaturated aqueous
sodium aluminate solution is fed, though it varies depending on the
intended particle diameter, is preferably not less than 500 hours
and preferably not more than 1,000 hours. The aggregated particles
in concentrating region 1 is taken out of offtake port 9 provided
at the bottom of vessel 3, separated from liquid by centrifugation,
filtration, or the like, and then washed according to
necessity.
[0032] Then the aggregated particles are disintegrated to yield
aluminum hydroxide powder. The disintegration is preferably
conducted by a method which can break the bond between a primary
particle and another primary particle without substantially
destroying the primary particle themselves which constitute an
aggregated particle, and preferably conducted, for example, with a
kneader, blender, extruder, or the like. The aluminum hydroxide
powder can be subjected, according to necessity, to drying or
surface treatment. The aluminum hydroxide powder thus obtained has
an average particle diameter of preferably not less than 10 .mu.m
and preferably not more than 35 .mu.m, and can be suitably used as
a filler for resins, such as unsaturated polyester resin, acrylic
resin and epoxy resin.
Example 1
Preparation of Aggregated Particles
[0033] A supersaturated aqueous sodium aluminate solution having a
temperature of 58.degree. C., a Na.sub.2O concentration of 125 g/l,
an Al.sub.2O.sub.3 concentration of 125 g/l and a molar ratio of
1.65 was fed at a flow rate of 100 parts by weight/hour to vessel 3
having a structure shown in FIG. 1. The inner wall of the vessel 3
is provided with baffle plates 4 each having a height corresponding
to 75% of the total height of vessel 3. When the liquid level of
the supersaturated aqueous sodium aluminate solution reached the
lower end of the upper stirring blade of blades 5 having two upper
and lower stirring blades, rotation of stirrer 7 was started, and
150 parts by weight of seeds having an average particle diameter of
1.1 .mu.m were added. While rotating stirrer 7 so that the
peripheral velocity of stirring blades 5 might be 0.5 m/s, feeding
of the supersaturated aqueous sodium aluminate solution to
concentrating region 1 of vessel 3 was continued to allow
hydrolysis to proceed in the concentrating region, and the aqueous
sodium aluminate solution was discharged from the upper end of
vessel 3. The discharged aqueous sodium aluminate solution had an
Na.sub.2O concentration of 125 g/l, an Al.sub.2O.sub.3
concentration of 65 g/l and a molar ratio of 3.2. When the average
particle diameter of aggregated particles in concentrating region 1
reached 80 .mu.m, feeding of the supersaturated aqueous sodium
aluminate solution was discontinued, and the reaction system was
kept as it was. The solid concentration in concentrating region 1
at the time of discontinuing the feed was 800 g/l. After being
kept, the content was withdrawn from offtake port 9 of vessel 3,
subjected to solid-liquid separation using a centrifugal separator,
and the resulting solid was washed to obtain the aggregated
particles.
Evaluation of Aggregated Particles
[0034] The L value of a slurry obtained by mixing 10 g of the
aggregated particles obtained above and 20 ml of glycerol was
determined with a color-difference meter (Type A-300, a trade name,
mfd. by Nippon Denshoku Kogyo K.K.). The result obtained is shown
in Table 1. Separately, 5 g of the above-mentioned aggregated
particles were placed in a cylindrical die 20 mm in diameter and
pressed under a pressure of 1,000 kg/cm.sup.2 for 1 minute, the
resulting pellets were pulverized with hands and a roller rod, and
then the average particle diameter of the resulting powder was
determined. The result obtained is shown in Table 2. The term "rate
of change" in Table 2 indicates the decrease of average particle
diameter observed after pressing relative to the average particle
diameter before pressing.
Preparation and Evaluation of Aluminum Hydroxide Powder
[0035] The aggregated particles obtained above were disintegrated
by using a blender and then dried to obtain aluminum hydroxide
powder. Filling the aluminum hydroxide powder in an unsaturated
polyester resin gave an artificial marble excellent in
transparency.
Comparative Example 1
[0036] To the first vessel of an apparatus comprising 8 vessels,
each equipped with a stirrer, connected in series was fed
continuously a supersaturated aqueous sodium aluminate solution
having a temperature of 58.degree. C., an Na.sub.2O concentration
of 125 g/l, an Al.sub.2O.sub.3 concentration of 121 g/l and a molar
ratio of 1.7 at a flow rate of 100 parts by weight/hour. In the
vessel, part of aqueous sodium aluminate solution was hydrolyzed to
obtain (aluminum hydroxide) aggregated particles. The aqueous
sodium aluminate solution containing aggregated particles was
transferred to the second vessel to allow hydrolysis to continue.
Succeedingly, the aqueous sodium aluminate solution was hydrolyzed
at the third to eighth vessel, to obtain aggregated particles. The
aqueous sodium aluminate solution discharged from the eighth vessel
had a molar ratio of 3.3. The aggregated particles obtained were
evaluated under the same conditions as in "evaluation of aggregated
particles" described in Example 1. The results thus obtained are
shown in Tables 1 and 2.
TABLE-US-00001 TABLE 1 L value Example 1 63 Comparative Example 1
70
TABLE-US-00002 TABLE 2 Average particle diameter (.mu.m) Before
After Rate of pressing pressing change (%) Example 1 68 30 55.9
Comparative 56 44 21.4 Example 1
[0037] The aggregated particles obtained above were treated in the
same manner as in "preparation and evaluation of aluminum hydroxide
powder" described in Example 1. The artificial marble thus obtained
did not have a sufficient transparency.
Example 2
Preparation of Aluminum Hydroxide Powder
[0038] Aluminum hydroxide powder was obtained by repeating the same
procedures as in Example 1 except that there was used a vessel
lined as an anticorrosive material with a SUS 304 stainless steel
sheet 2 mm in thickness welded to the inner surface of the vessel
ranging from the bottom of the vessel to the upper end of the
baffle plate, and that feeding of supersaturated aqueous sodium
aluminate solution was discontinued at the time when the average
particle diameter of aggregated particles in concentrating region 1
reached 40 .mu.m.
Evaluation of Aluminum Hydroxide Powder
[0039] The b value of a slurry obtained by mixing 18 g of the
powder obtained above and 10 g of methyl methacrylate was
determined with a color-difference meter (Z-1001 DP, a trade name,
mfd. by Nippon Denshoku Kogyo K.K.). The results thus obtained are
shown in Table 3.
Example 3
[0040] Aluminum hydroxide powder was obtained by repeating the same
procedures as in "preparation of aluminum hydroxide powder"
described in Example 2 except that no stainless steel sheet lining
was applied to the vessel. The aluminum hydroxide powder thus
obtained was evaluated under the same conditions as in "evaluation
of aluminum hydroxide powder" described in Example 2. The results
obtained are shown in Table 3.
TABLE-US-00003 TABLE 3 Average particle diameter (.mu.m) b value
Example 2 29 1.5 Example 3 27 3.3
[0041] According to the aluminum hydroxide aggregated particles and
the process for producing the same according to this invention,
aluminum hydroxide aggregated particles are obtained which are the
material for producing aluminum hydroxide powder which in turn can
provide, when filled in a resin, a resin composition having a high
transparency. The process for producing aluminum hydroxide powder
according to this invention is a process which uses the
above-mentioned aluminum hydroxide aggregated particles, and
according to the process, the aluminum hydroxide powder can be
easily obtained. Further, the use of the vessel according to this
invention makes it possible to produce the aluminum hydroxide
aggregated particles in a simple and easy manner.
* * * * *