JPS6281448A - Thermotropic liquid crystal polymer composition and production thereof - Google Patents

Abstract

PURPOSE:To produce the titled compsn. giving moldings in which a difference in strength between molecular orientation directions is small, by kneading a thermotropic liquid crystal polymer with a potassium titanate fiber contg. no water of crystallization in a nitrogen stream. CONSTITUTION:40-95wt% thermotropic liquid crystal polymer (A) contg. at least 10% repeating unit contg. a naphthalene moiety (e.g., a polyethylene terephthalate/hydroxybenzoic acid copolymer) and 60-5wt% potassium titanate fiber (B) having a length of 10-20mum and a fiber diameter of 0.2-0.5mum and contg. no water of crystallization are fed to a kneader equipped with a vent. Dry nitrogen gas is forcedly introduced from the hopper side of the kneader thereinto and kneading is conducted, while gas formed during kneading is vented through the vent connected to a vacuum source.

Description

Detailed Description of the Invention "Field of Industrial Application" The present invention relates to thermotropic liquid crystal polymer compositions that can be used to produce various molded products with excellent physical properties by extrusion molding, compression molding, and injection molding. and its manufacturing method.

"Conventional technology" Thermotropic liquid crystal polymers have mechanical strength, heat resistance,
Properties such as weather resistance and chemical resistance are far superior to other thermoplastic resins.

Moreover, since it has excellent flame retardancy, it is expected to be used in various fields.

On the other hand, since the molecular structure of the CIR7tropic liquid crystal polymer is rod-shaped, the molded product obtained from it is
Its mechanical strength in the direction of molecular arrangement is extremely high, and steel,
It is several times to several tens of times stronger than aluminum or glass fiber. However, in the direction perpendicular to the direction in which one molecule is arranged, its strength is only 1/7 to 1/60 L of that in the direction of arrangement, and the difference in strength due to the difference in direction of arrangement is extremely large.

Therefore, the field of application of molded articles of thermotropic liquid crystal polymers is limited to a small range, which has the disadvantage of t5.

"Problems to be Solved by the Invention" The present invention aims to improve the difference in mechanical strength due to directionality that occurs during molding of thermotropic liquid crystal polymers. That is, when molded, the mechanical strength is excellent both in the direction of molecular arrangement and in the direction perpendicular to the direction of molecular arrangement. The object of the present invention is to provide a thermotropic liquid crystal polymer composition from which molded articles with little difference in strength due to differences in alignment direction can be obtained.

Therefore, the gist of the present invention is that a motropic liquid crystal polymer having a weight of 0 to 12 N and a potassium titanate fiber containing no water of crystallization having a weight of 40-j' A thermotropic liquid crystal polymer composition, and for producing the liquid crystal polymer composition,
A thermotropic liquid crystal polymer composition characterized in that the above thermotropic liquid crystal polymer and the above potassium titanate fibers containing no water of crystallization are uniformly kneaded in a nitrogen gas stream using a kneader having a deaeration port. It depends on the manufacturing method.

The present invention will be explained in detail below.

In the present invention, thermotropic liquid crystal polymer is
A polymer that is liquid crystalline (ie, anisotropic) in the molten phase. Thermotropic liquid crystal polymers include fully and non-fully aromatic polyesters, aromatic-aliphatic polyesters, aromatic polyazomethines, aromatic polyesters.
These include, but are not limited to, carbonates, and aromatic and non-fully aromatic polyester-amides.

Aromatic polyesters and poly(ester-amides) are considered "fully" aromatic in the sense that any component present in the polymer contributes at least one aromatic ring to the polymer backbone, thereby can exhibit anisotropy in the molten phase. The surface ingredients are like this.

It can be derived from aromatic diols, aromatic amines, aromatic dicarboxylic acids and aromatic hydroxy acids.

Components that may be present in the fully aromatic thermotropic liquid crystal polymer of the present invention include, but are not limited to, the following.

O0 1 (H 4 -) The thermotropic liquid crystal polymer in the present invention preferably contains about 7θ% or more of repeating units containing a naphthalene moiety.
There are oxyconaphthoyl, co,6-cyoxynaphthoyl and co,6-dicarpoxynaphthoyl.

A specific example of the aromatic-aliphatic polyester is a copolymer of polyethylene terephthalate and hydroxyambuzoic acid.

A specific example of aromatic polyazomethine is polytrilocomethyl/,! -phenylene nitriloethylisine/, 41-phenylene ethyridine), poly to trilocomethyl-hederphenylene nitriloethyridine, and 1, mo-phenylenenitrilomethylidine/41-phenylene-methylidine).

Examples of aromatic polyester-carbonates are disclosed in US Pat. An example of such a polymer is one essentially p-oxybenzoyl unit.

These include p-dioky7phenyl units, dioxycarbonyl units and terephthoyl units.

Aromatic polyester-amides and methods of making them are disclosed in US Patent No. 11-1.

The liquid crystal polymer composition according to the present invention contains potassium titanate fibers that do not contain water of crystallization in the thermotropic liquid crystal polymer. Potassium titanate fiber is 0
．． It has the chemical composition of 4TiQm and does not contain water of crystallization. In potassium titanate fibers containing water of crystallization, the water of crystallization decomposes during kneading and disperses in the form of bubbles in the molded product, making it impossible to obtain a molded product with an excellent appearance.

Preferably, the potassium titanate fibers have a length of 60-20 μm and a fiber diameter in the range of O.

In the thermotropic liquid crystal polymer composition according to the present invention, the potassium titanate fibers that do not contain crystal water are in the range of r-to weight % with respect to the thermotropic liquid crystal polymer composition, preferably = θ to 〇 It is necessary that the proportion is within the range of weight 9. If the violet content of potassium titanate fibers in the composition is less than S, the mechanical strength (e.g. tensile) strength in the molecular alignment direction and the direction perpendicular to this of the molded product obtained by molding the composition To improve the difference due to the one-sidedness of.

is almost ineffective. Furthermore, when the content of the compound exceeds 60% by weight, the composition produced by kneading hardly exhibits fluidity, making molding difficult and impractical.

The thermotropic liquid crystal polymer and potassium titanate fiber are weighed in predetermined amounts, mixed in a tumbler and mixer, and the resulting mixture is kneaded in a kneader to uniformly transform the potassium titanate fiber into a thermotropic liquid crystal polymer. to be dispersed.

To produce the thermotropic liquid crystal polymer composition according to the present invention, the thermotropic liquid crystal polymer and potassium titanate fibers containing no water of crystallization are uniformly kneaded in a nitrogen stream using a kneader having a degassing port. do. The kneading machine is not particularly limited, and a commonly used extruder having a degassing port may be used.

The degassing port of the kneader is preferably connected to a reduced pressure source to remove gas generated during crosstalk.

The gas includes moisture adsorbed on the thermotropic liquid crystal polymer, decomposition products of the polymer, moisture adsorbed on the potassium titanate fibers, and the like.

The reason why the composition is manufactured in a nitrogen stream is to avoid deterioration of the polymer due to contact with air since the composition is manufactured at a high temperature. As a specific method for the kneading operation, it is preferable to adopt a method in which dry nitrogen gas is forcibly supplied from the hopper side of the kneader and then removed from the degassing port.

In order to cross-wire the two components, it is preferable to select a temperature within the range of -5O to SOθ°C.

The thermotropic liquid crystal polymer composition according to the present invention includes:
It can be molded using ordinary extrusion molding machines, compression molding machines, injection molding machines, etc., and by taking advantage of the excellent heat resistance, weather resistance, flame retardance, IT chemical resistance, etc. of thermotropic liquid crystal polymer, various glaze industries can use it. It can be used for manufacturing material parts.

"Effects of the Invention" The present invention has the following particularly remarkable effects:
Its industrial utility value is extremely large.

+11 Since the thermotropic liquid crystal polymer composition according to the present invention contains potassium titanate fibers as a reinforcing material, the molded product obtained by molding this composition has a structure in which the molecules are arranged in the direction parallel to the gate. The ratio of mechanical strength, especially tensile strength, to the direction perpendicular to the gate is V5 to V3, compared to the conventional ratio of V full 1/60. can be made smaller.

(2) The molded product obtained by molding the thermotropic liquid crystal polymer composition according to the present invention has an extremely smooth appearance and therefore has high commercial value. This indicates that the composition of the present invention is superior to the case where glass fiber or the like is kneaded as a substitute for potassium titanate fiber, the appearance of the forming bacteria becomes rough and the commercial value is lost. There is.

"Examples" Next, the present invention will be explained in more detail by Examples and Comparative Examples, but the present invention is not limited to the following examples as long as they do not exceed the gist thereof.

Example / 40 parts by weight of aromatic polyester thermotropic liquid crystal polymer Zydar BTR300 (manufactured by Da, rtoo Mfg) and potassium titanate fiber Teismo D (manufactured by Ohita Kagaku Co., Ltd., chemical composition: Ni, 044) containing no crystal water
) 1.0) lIt0 heavy violet parts were placed in a commonly used tumbler and mixed. The resulting mixture was heated to 16
It was dried at 0°C for j hours.

The mixture obtained above was charged into the hopper of a yo%φ extruder (manufactured by Mitsubishi Heavy Industries, Ltd.), which had a degassing hole and was able to control the cylinder temperature up to zoo'c, and was heated and kneaded at yoo'C. During heating and kneading, dry phoneme gas was supplied from a hopper and suctioned by a vacuum pump from a degassing port so that the molten mixture was exposed to a nitrogen atmosphere. The composition obtained by kneading is extruded from an extruder and cut with a cutter to create pellets.

It was dried at izo° C. for 1 hour.

The mold clamping force that made it possible to control the cylinder temperature to zoo”c?j ton injection molding machine (Nippon Seido Co., Ltd. M) was used to mold the above pellet to a cylinder temperature of 4600°C.
k tvt X, t31 thickness, 2 at mold temperature -60℃
It was molded into a flat plate. From this slab.

Width lθW and length from the direction parallel to the gate, which is the direction in which the molecules are arranged (this is called the A direction), and the direction at the IH angle to the gate (this is called the B direction). rOwm
Test piece gold clipping.

The tensile strength was measured.

The results are shown in Table 1.

Examples K, J, II By a method similar to that described in Example 1, thermotropic liquid crystal polyester W-
Zydor r3TRJ 00 K, Potassium titanate fiber Teismo D without crystallization water was blended at a ratio of 5 weight X, -0 weight N, and 40 weight 9 to the composition, respectively.

A composition was produced.

The three types of compositions obtained were formed into a flat plate in the same manner as in Example 1, and the test piece gold cut p and tensile p strengths were measured in the same manner as in Example 1.

The results are shown in Table 1.

Comparative Example 11 A thermotropic liquid crystal polymer Z based on aromatic polyester was prepared by a method similar to that described in Example 1.
Potassium titanate fiber Teismo D, which does not contain water of crystallization, was blended into y(lor 13Tfl, 300) at a weight ratio of 3 to the resulting composition to prepare a composition.

As in Example/from the composition of Shiko? A test piece was prepared and the tensile peak degree was measured. The results are shown in Table 1.

In addition, the above amount of potassium titanate fiber Teismo DO is g
The composition obtained by changing the weight to 9 showed almost no fluidity, and therefore could not be molded into a flat plate by injection molding.

Comparative example 3. In the gas described in Example 1, no phoneme gas is supplied from the hopper in the crosstalk process in the extruder, and the other parts are as described in Example 2.
A polymer composition was obtained in the same manner as in . A test piece was prepared from this composition in the same manner as in Example 1, and the tensile strength was measured. The results are shown in Table 1 (comparison fl
I3).

In addition, in the example described in Example 1, when the extruder kneading step was kneaded with the deaeration port of the extruder closed and an attempt was made to form pellets in the same manner as in 9111, one composition was mixed. Foamed pellets 11- similar to Example 1
I couldn't get it (Comparative Example Tei) Comparative Example! *In Example 1, instead of potassium titanate # & fiber Teismo D, which does not refer to water of crystallization, potassium titanate fiber Teismo L, which refers to water of crystallization (chemical composition: O.4T)
60.・THmO) A test piece was prepared in the same manner as in Example I except that the tensile strength was kept constant.

The results are shown in Table 1.

However, when the composition was extruded into pellets, one foaming was noticeable.

Comparative Example 6 A test piece was prepared in the same manner as in Example 1 except that short glass fibers were used as the glue for the potassium titanate fiber Tismo D, and the tensile strength was measured.

The results are shown in Table 7.

The tensile strength shown in Table 7 is based on the JI date.
Measured in accordance with .

From Table 1, the following becomes clear.

(1) A molded article using a composition that satisfies all the essential requirements of the present invention has excellent tensile strength in both the A direction and the B direction, and the difference between them is small.

(2) However, the amount of potassium titanate used was small (comparison fU / ), potassium titanate containing crystal water was used (comparative example S), and glass fiber was used (comparison In Example 6), there is a large difference in tensile strength depending on the direction of the molded product.

(31) Also, if the kneader does not have a deaeration port, foaming occurs during extrusion, making it impossible to obtain a molded product.

(4) Molded products made from the composition obtained using the potassium titanate fibers free of crystallization water of the present invention have smooth surfaces and are of good quality, but when glass fibers are used, the quality of the molded products deteriorates. The surface becomes very rough.

Claims (2)

[Claims] (1) A thermotropic liquid crystal polymer composition comprising 40 to 95% by weight of a thermotropic liquid crystal polymer and 60 to 5% by weight of potassium titanate fibers containing no water of crystallization. (2) In producing a thermotropic liquid crystal polymer composition consisting of 40 to 95% by weight of a thermotropic liquid crystal polymer and 60 to 5% by weight of potassium titanate fibers containing no water of crystallization, the thermotropic liquid crystal polymer and A method for producing a thermotropic liquid crystal polymer composition, comprising uniformly kneading the potassium titanate fibers containing no water of crystallization in a nitrogen stream using a kneader having a deaeration port.