CN101193932A

CN101193932A - Polyester compositions which comprise cyclobutanediol and have a certain combination of inherent viscosity and moderate glass transition temperature and articles made therefrom

Info

Publication number: CN101193932A
Application number: CNA2006800205611A
Authority: CN
Inventors: E·D·克劳福德; T·J·佩科里尼; D·S·麦克威廉斯; D·S·波特; G·W·康奈尔
Original assignee: Eastman Chemical Co
Current assignee: Eastman Chemical Co
Priority date: 2005-06-17
Filing date: 2006-03-30
Publication date: 2008-06-04
Anticipated expiration: 2026-03-30
Also published as: CN101193668A; CN101203541A; CN101193721A; CN101193945A; CN101193936A; CN101193935B; CN101193936B; CN101203543B; CN101203540A; CN101193944A; CN101193933A; CN101193935A; CN101193978A; CN101193943B; CN101193980A; CN101213239A; CN101193933B; CN101193940A; CN101193733A; CN101193979A

Abstract

Described are polyester compositions comprising at least one polyester which comprises terephthalic acid residues, 2,2,4,4-tetramethyl-1,3-cyclobutanediol, and 1,4-cyclohexanedimethanol, wherein the inherent viscosity and the Tg of the polyester provides for certain polyester properties. The polyesters may be manufactured into articles such as fibers, films, bottles or sheets.

Description

Contain cyclobutanediol and have logarithmic viscosity number and the polymer blend of high glass-transition temperature particular combinations and by the goods of its production

The cross reference of related application

[001] the application requires the right of priority of following application according to 35U.S.C. § 119 (e): the U.S. Provisional Application 60/691 that on June 17th, 2005 submitted, 567, the U.S. Provisional Application 60/731 that on October 28th, 2005 submitted, 454, the U.S. Provisional Application 60/731 that on October 28th, 2005 submitted, 389, the U.S. Provisional Application 60/739 that on November 22nd, 2005 submitted, the U.S. Provisional Application 60/738,869 that on November 22nd, 058,2005 submitted, the U.S. Provisional Application 60/750 that on December 15th, 2005 submitted, the U.S. Provisional Application 60/750,693 that on December 15th, 692,2005 submitted, the U.S. Provisional Application 60/750 that on December 15th, 2005 submitted, the U.S. Provisional Application 60/750,547 that on December 15th, 682,2005 submitted; And be incorporated herein their full content for reference.

Invention field

[002] the present invention relates in general to the polymer blend by following component preparation: terephthalic acid, terephthalate or their mixture; 2,2,4,4-tetramethyl--1,3-cyclobutanediol; And 1,4 cyclohexane dimethanol; Described polyester has the particular combinations of logarithmic viscosity number and second-order transition temperature (Tg).It is believed that these compositions have the particular combinations of following two or more performances: high impact, high glass-transition temperature (Tg), toughness, for example low ductile-brittle transition temperature, specific logarithmic viscosity number, the good color and the transparency, low density, chemical-resistant, stability to hydrolysis, and long half-time of crystallization, this makes these polymer blends be easy to be shaped to goods.

Background of invention

[003] poly terephthalic acid 1, and 4-cyclohexylidene dimethylene ester (PCT) is a kind of only based on the ester of terephthalic acid or its ester and 1,4 cyclohexane dimethanol, and they are well known in the art, and can obtain from commerce.This polyester can when cooling apace from melt crystallization, thereby be difficult to for example extrude by means commonly known in the art, injection moulding etc. forms amorphous goods.For the crystallization rate of the PCT that slows down, can prepare the copolyesters that contains extra dicarboxylic acid or glycol (for example m-phthalic acid or ethylene glycol).These also are well known in the art by the PCT of ethylene glycol or isophthalate modified, and can obtain from commerce.

[004] a kind ofly is generally used for producing the copolyesters of film, sheet material and moulded parts from terephthalic acid, 1,4 cyclohexane dimethanol and ethylene glycol.Though these copolyesters can be used in many end-uses, when comprising enough modification ethylene glycol so that long half-time of crystallization to be provided in batching, they are presented at for example defective of second-order transition temperature and shock strength aspect of performance.For example, by terephthalic acid, 1,4-cyclohexanedimethanol and ethylene glycol and have the copolyesters of sufficiently long half-time of crystallization amorphous products can be provided are compared with composition disclosed herein, and it demonstrates disadvantageous higher ductile-brittle transition temperature and lower second-order transition temperature.

[005] 4, the polycarbonate of 4 '-isopropylidene biphenol (bisphenol-a polycarbonate) as the substitute of polyester known in the art, also has been known engineering moulded plastic.Bisphenol-a polycarbonate is transparent high performance plastics, and it has good physicals, for example dimensional stability, high heat resistance and good shock strength.Although bisphenol-a polycarbonate has many good physicalies, its higher melt viscosity causes melt processability poor, and the chemical-resistant of polycarbonate is poor.They also are difficult to thermoforming.

[006] contain 2,2,4,4-tetramethyl--1, the polymkeric substance of 3-cyclobutanediol also have description in the art.But generally speaking, these polymkeric substance demonstrate high logarithmic viscosity number, high melt viscosity and/or high Tg (second-order transition temperature), make that the equipment that uses in industry is not enough to produce or post polymerization is processed these materials.

[007] therefore, have in a kind of workability on keeping industry standard equipment of this area needs and be selected from following two or more at least a performance combination of polymers: the toughness of polyester, high glass-transition temperature, high impact, stability to hydrolysis, chemical-resistant, long half-time of crystallization, low ductile-brittle transition temperature, the good color and the transparency, low density, and/or thermal formability.

Summary of the invention

[008] it is believed that by terephthalic acid or its ester or their mixture and 1,4-cyclohexanedimethanol residue and 2,2,4,4-tetramethyl--1, that form and the particular composition that have logarithmic viscosity number and second-order transition temperature particular combinations of 3-cyclobutanediol residue known polyester and polycarbonate in the field under following one or more aspect of performances are better than: high impact, stability to hydrolysis, toughness, chemical-resistant, the good color and the transparency, long half-time of crystallization, low ductile-brittle transition temperature, low-gravity and/or thermal formability.It is believed that these compositions are similar to polycarbonate aspect thermotolerance, and still can on standard industry equipment, process.

[009] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

Ii) 0-30 mole %'s has an aromatic dicarboxylic acid residue of 20 carbon atoms at the most; With

Iii) 0-10 mole %'s has an aliphatic dicarboxylic acid residue of 16 carbon atoms at the most; With

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 1-99 mole %,

Wherein dicarboxylic acid component's total mole of % is 100 moles of %, and total mole of % of diol component is 100 moles of %; With

The logarithmic viscosity number of wherein said polyester is 0.35 to less than 0.70dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With the Tg of wherein said polyester be 110-200 ℃.

[010] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) greater than 2,2,4 of 81 to 99 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) 1 to the 1,4 cyclohexane dimethanol residue less than 19 moles of %,

The logarithmic viscosity number of wherein said polyester is 0.35-0.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With the Tg of wherein said polyester be 110-200 ℃.

[011] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-85 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 15-60 mole %,

The logarithmic viscosity number of wherein said polyester is 0.35-1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With the Tg of wherein said polyester be 110-200 ℃.

[012] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-85 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 15-60 mole %,

The logarithmic viscosity number of wherein said polyester is 0.35-1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With the Tg of wherein said polyester be 148-200 ℃.

[013] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-80 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 20-60 mole %,

[014] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 35-60 mole %,

The logarithmic viscosity number of wherein said polyester is 0.35-0.75dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With the Tg of wherein said polyester be 110-200 ℃.

[015] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-64.9 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 35-59.9 mole %,

Iii) 0.10 to the glycol residue less than 15 moles of %;

[016] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-55 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 45-60 mole %,

[017] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 45-55 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 45-55 mole %,

[018] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 35-60 mole %,

The logarithmic viscosity number of wherein said polyester is 0.35-0.75dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration;

The Tg of wherein said polyester be 110-200 ℃ and

Randomly before the polymerization of polymkeric substance or during add one or more branching agents.

[019] in one aspect, the present invention relates to a kind of polymer blend, it contains:

(A) at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 1-99 mole % and

(B) residue of at least a branching agent;

Wherein dicarboxylic acid component's total mole of % is 100 moles of %, and total mole of % of diol component is 100 moles of %;

The logarithmic viscosity number of wherein said polyester is 0.35-1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration;

The Tg of wherein said polyester is 110-200 ℃.

[020] in one aspect, the present invention relates to a kind of polymer blend, it contains:

(A) at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 35-60 mole % and

(B) residue of at least a branching agent;

The logarithmic viscosity number of wherein said polyester is 0.35-1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; The Tg of wherein said polyester is 110-200 ℃.

[021] in one aspect, the present invention relates to a kind of polymer blend, it contains:

(A) at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 35-60 mole % and

(B) residue of at least a branching agent;

The logarithmic viscosity number of wherein said polyester is 0.35-0.75dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; The Tg of wherein said polyester is 110-200 ℃.

[022] in one aspect, the present invention relates to a kind of polymer blend, it contains:

(A) at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 1-99 mole % and

(B) at least a thermo-stabilizer or its reaction product;

[023] in one aspect, the present invention relates to a kind of polymer blend, it contains:

(A) at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 35-60 mole % and

(B) at least a thermo-stabilizer or its reaction product;

[024] in one aspect, the present invention relates to a kind of polymer blend, it contains:

(A) at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 35-60 mole % and

(B) at least a thermo-stabilizer or its reaction product;

[025] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol; With

The ii) 1,4 cyclohexane dimethanol of 35-60 mole %,

The logarithmic viscosity number of wherein said polyester is 0.35-0.75dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With

The Tg of wherein said polyester is 110-150 ℃.

[026] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol; With

The ii) 1,4 cyclohexane dimethanol of 35-60 mole %,

The Tg of wherein said polyester is 120-135 ℃.

[027] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 1-99 mole %,

Wherein the logarithmic viscosity number of polyester is 0.35-0.75dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With

Wherein the Tg of polyester be from greater than 148 ℃ until 200 ℃.

[028] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 1-99 mole %,

Wherein the logarithmic viscosity number of polyester is 0.35-1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With

Wherein the Tg of polyester is 127 ℃-200 ℃.

[029] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-80 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 20-99 mole %,

The Tg of wherein said polyester is greater than 124 ℃ to 200 ℃.In other embodiments, Tg can be greater than 125 ℃ to 200 ℃, or greater than 126 ℃ to 200 ℃, or greater than 127 ℃ to 200 ℃.

[030] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) greater than 50 until 2,2,4 of 99 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) 1 to the 1,4 cyclohexane dimethanol residue less than 50 moles of %,

Wherein the Tg of polyester is 110 ℃-200 ℃.

[031] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) greater than 50 until 2,2,4 of 80 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) 20 to the 1,4 cyclohexane dimethanol residue less than 50 moles of %,

Wherein the Tg of polyester is 110-200 ℃.

[032] in one aspect, the present invention relates to a kind of polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 1-99 mole %,

Wherein the logarithmic viscosity number of polyester is greater than 0.76 until 1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; With

Wherein the Tg of polyester is 110-200 ℃.

[033] in one aspect, described polymer blend contains at least a polycarbonate.

[034] in one aspect, described polymer blend does not contain polycarbonate.

[035] in one aspect, be used for polyester of the present invention and contain glycol residue less than 15 moles of %, for example 0.01 mole of % is to the glycol residue less than 15 moles of %.

[036] in one aspect, be used for polyester of the present invention and do not contain glycol residue.

[037] in one aspect, be used for polyester of the present invention and contain at least a thermo-stabilizer and/or its reaction product.

[038] in one aspect, be used for polyester of the present invention and do not contain branching agent, or before the polymerization of polyester or during add at least a branching agent.

[039] in one aspect, be used for polyester of the present invention and contain at least a branching agent, and with the addition means or the sequence independence of branching agent.

[040] in one aspect, being used for polyester of the present invention is not by 1, ammediol or 1,4-propylene glycol or its combined preparation.In yet another aspect, 1, ammediol or 1,4-propylene glycol or its combination can be used to prepare polyester of the present invention.

[041] in one aspect of the invention, in the specific polyester of the present invention, use suitable-2,2,4,4-tetramethyl--1, the mole % of 3-cyclobutanediol is greater than 50 moles of % or greater than suitable-2 of 55 moles of %, 2,4,4-tetramethyl--1, the 3-cyclobutanediol, or greater than suitable-2,2,4 of 70 moles of %, 4-tetramethyl--1, the 3-cyclobutanediol; Wherein suitable-2,2,4,4-tetramethyl--1,3-cyclobutanediol and anti--2,2,4,4-tetramethyl--1, total molar percentage of 3-cyclobutanediol equals 100 moles of %.

[042] in one aspect of the invention, in the specific polyester of the present invention, use 2,2,4,4-tetramethyl--1, the mole % of 3-cyclobutanediol isomer is suitable-2,2,4 of 30-70 mole %, 4-tetramethyl--1, anti--2,2 of 3-cyclobutanediol and 30-70 mole %, 4,4-tetramethyl--1,3-cyclobutanediol, perhaps 40-60 mole %'s suitable-2,2,4,4-tetramethyl--1, anti--2,2 of 3-cyclobutanediol and 40-60 mole %, 4,4-tetramethyl--1,3-cyclobutanediol, wherein suitable-2,2,4,4-tetramethyl--1,3-cyclobutanediol and anti--2,2,4,4-tetramethyl--1, total molar percentage of 3-cyclobutanediol equals 100 moles of %.

[043] in one aspect, described polymer blend is used to produce goods of the present invention, described goods include but not limited to extrude, the goods of calendering and/or molding, include but not limited to injection-molded item, extruded product, casting extruded product, thermoformed articles, section bar extruded product, melt spinning goods, thermoformed articles, extrusion molding goods, injection blow molding goods, injection drawing blow goods, extrusion-blow molding product and extrude the stretch-blow goods.These goods can include but not limited to film, bottle (including but not limited to infant bottle), container, sheet material and/or fiber.In one aspect, being used for polymer blend of the present invention can use with the form of various types of films and/or sheet material, includes but not limited to: film of extruding and/or sheet material, the film of calendering and/or sheet material, the film of compression moulding and/or sheet material, the film of solution casting and/or sheet material.The method for preparing film and/or sheet material includes but not limited to extrude, calendering, compression moulding and solution casting.

[044] in addition, in one aspect, use polymer blend of the present invention that drying step before melt and/or the thermoforming is minimized and/or do not need this drying step.

[045] in one aspect, it can be amorphous or hemicrystalline being used for specific polyester of the present invention.In one aspect, be used for specific polyester of the present invention and have lower degree of crystallinity.Therefore, be used for specific polyester of the present invention and have essentially amorphous rheology, this represents that described polyester contains unordered substantially polymer areas.

The accompanying drawing summary

[046] Fig. 1 shows the figure of comonomer to the influence of the fastest half-time of crystallization of modification PCT copolyesters.

[047] Fig. 2 shows that comonomer is to the brittle-ductile transition temperature (T in the notched izod strength trial (ASTM D256,1/8 inch thick, 10 mil breach) _Bd) the figure of influence.

[048] Fig. 3 shows 2,2,4,4-tetramethyl--1, and the composition of 3-cyclobutanediol is to the figure of the influence of the glass transition transition temperature (Tg) of copolyesters.

Detailed Description Of The Invention

[049] can understand better the present invention with reference to following detailed description to specific embodiments of the present invention and work embodiment. According to purpose of the present invention, certain embodiments of the present invention are disclosed in " summary of the invention ", and are described further below. Other embodiment of the present invention also is described below.

[050] it is believed that the unique combination that has following two or more physical properties for polyester of the present invention and/or polymer blend described herein: high impact, high glass-transition temperature, chemical-resistant, hydrolytic stability, toughness, low ductile-brittle transition temperature for example, good color and the transparency, low-density, long half-crystallization time, and good processability, this is so that they are easy to be shaped to goods. In some embodiments of the present invention, polyester has the special performance combination of good impact strength, heat resistance, chemical-resistant, density, and/or the performance of good impact strength, heat resistance and processability combination, and/or the combination of two or more described performances, this is irrealizable in existing polyester.

[051] comprises " copolyesters " at term used herein " polyester ", and be interpreted as that expression reacts the synthetic polymer that makes by one or more bifunctional carboxylic acids and/or polyfunctional carboxylic acids and one or more difunctionality hydroxy compounds and/or multifunctional hydroxy compounds. Usually, the bifunctional carboxylic acid can be dicarboxylic acids, and the difunctionality hydroxy compounds can be dihydroxylic alcohols, for example glycol (glycol) and glycol (diol). The term " glycol " that uses in this application includes but not limited to glycol, glycol and/or multifunctional hydroxy compounds, for example branching agent. Perhaps, the bifunctional carboxylic acid can be hydroxycarboxylic acid, for example p-hydroxybenzoic acid; The difunctionality hydroxy compounds can be the virtue nuclear with two hydroxyl substituents, for example quinhydrones. Be introduced into organic structure in the polymer by carrying out polycondensation and/or esterification with corresponding monomer in that term used herein " residue " expression is any. Have the dicarboxylic acid residue that connects via the ketonic oxygen base key and the organic structure of diol residue in term used herein " repetitive " expression. Therefore, for example, dicarboxylic acid residue can be derived from dicarboxylic acid monomer or its corresponding carboxylic acid halides, ester, salt, acid anhydrides or its mixture. In addition, the term " diacid " that uses in this application comprises polyfunctional acid, for example branching agent. So, the any derivative that comprises dicarboxylic acids and dicarboxylic acids in term used herein " dicarboxylic acids " expression, comprise its corresponding carboxylic acid halides, ester, half ester, salt, half salt, acid anhydrides, mixed acid anhydride or its mixture, be used for the process with glycol reaction preparation polyester. Comprise terephthalic acid (TPA) itself and its residue in term used herein " terephthalic acid (TPA) " expression, and any derivative of terephthalic acid (TPA), comprise its corresponding carboxylic acid halides, ester, half ester, salt, half salt, acid anhydrides, mixed acid anhydride or its mixture, be used for the process with glycol reaction preparation polyester.

[052] in one embodiment, terephthalic acid (TPA) can be used as raw material. In another embodiment, dimethyl terephthalate (DMT) is as raw material. In another embodiment, the mixture of terephthalic acid (TPA) and dimethyl terephthalate (DMT) can be as raw material and/or as intermediate materials.

[053] be used for polyester of the present invention and usually can prepare according to the basic ratio reaction that equates from dicarboxylic acids and glycol, described dicarboxylic acids and glycol are introduced in the polyester polymers as their corresponding residue. So polyester of the present invention can contain sour residue (100 % by mole) and glycol (and/or multifunctional hydroxy compounds) residue (100 % by mole) of basic equimolar ratio example, so that total % by mole of repetitive equals 100 % by mole. So the molar percentage that provides in this manual can be based on the total mole number of sour residue, the total mole number of diol residue or the total mole number of repetitive. For example, the polyester that contains 30 % by mole of M-phthalic acids based on sour residue total amount meter represents that polyester contains 30 % by mole of isophthalic acid residues, based on 100 % by mole sour residue meter. Therefore, in per 100 moles sour residue, 30 moles isophthalic acid residues is arranged. In another example, contain 30 % by mole 2,2 based on diol residue total amount meter, 4,4-tetramethyl-1, the polyester of 3-cyclobutanediol represent polyester contain 30 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol residue is based on 100 % by mole diol residue meter. Therefore, 30 moles TMCBD residue is arranged in per 100 moles diol residue.

[054] in another aspect of the present invention, the Tg that is used for the polyester of polymer blend of the present invention includes but not limited to: 85-200 ℃; 85-190 ℃; 85-180 ℃; 85-170 ℃; 85-160 ℃; 85-155 ℃; 85-150 ℃; 85-145 ℃; 85-140 ℃; 85-138 ℃; 85-135 ℃; 130 ℃ of 85-; 85-125 ℃; 85-120 ℃; 85-115 ℃; 85-110 ℃; 85-105 ℃; 85-100 ℃; 85-95 ℃; 85-90 ℃; 90-200 ℃; 90-190 ℃; 90-180 ℃; 90-170 ℃; 90-160 ℃; 90-155 ℃; 90-150 ℃; 90-145 ℃; 90-140 ℃; 90-138 ℃; 135 ℃ of 90-; 90-130 ℃; 90-125 ℃; 90-120 ℃; 90-115 ℃; 90-110 ℃; 90-105 ℃; 90-100 ℃; 90-95 ℃; 95-200 ℃; 95-190 ℃; 95-180 ℃; 95-170 ℃; 95-160 ℃; 95-155 ℃; 95-150 ℃; 95-145 ℃; 95-140 ℃; 95-138 ℃; 135 ℃ of 95-; 95-130 ℃; 95-125 ℃; 95-120 ℃; 95-115 ℃; 95-110 ℃; 95-105 ℃; 95-is less than 105 ℃; 95-100 ℃; 100-200 ℃; 100-190 ℃; 100-180 ℃; 100-170 ℃; 100-160 ℃; 100-155 ℃; 100-150 ℃; 100-145 ℃; 100-140 ℃; 100-138 ℃; 100-135 ℃; 100-130 ℃; 100-125 ℃; 100-120 ℃; 115 ℃ of 100-; 100-110 ℃; 105-200 ℃; 105-190 ℃; 105-180 ℃; 105-170 ℃; 105-160 ℃; 105-155 ℃; 105-150 ℃; 105-145 ℃; 105-140 ℃; 105-138 ℃; 105-135 ℃; 105-130 ℃; 105-125 ℃; 105-120 ℃; 105-115 ℃; 110 ℃ of 105-; Greater than 105-125 ℃; Greater than 105-120 ℃; Greater than 105-115 ℃; Greater than 110 ℃ of 105-; 110-200 ℃; 110-195 ℃; 110-190 ℃; 110-185 ℃; 110-180 ℃; 110-175 ℃; 110-170 ℃; 110-165 ℃; 110-160 ℃; 110-155 ℃; 110-150 ℃; 110-145 ℃; 110-138 ℃; 110-140 ℃; 110-135 ℃; 110-130 ℃; 110-125 ℃; 110-120 ℃; 110-115 ℃; 115-200 ℃; 115-195 ℃; 115-190 ℃; 115-185 ℃; 115-180 ℃; 115-175 ℃; 115-170 ℃; 115-165 ℃ 115-160 ℃; 115-155 ℃; 115-150 ℃; 115-145 ℃; 115-140 ℃; 115-138 ℃; 115-135 ℃; 125 ℃ of 115-; 115-120 ℃; 120-200 ℃; 120-195 ℃; 120-190 ℃; 120-185 ℃ 120-180 ℃; 120-175 ℃ 120-170 ℃; 120-165 ℃; 120-160 ℃; 120-155 ℃; 120-150 ℃; 120-145 ℃; 120-140 ℃; 120-138 ℃; 120-135 ℃; 180 ℃ of 125-; 125-170 ℃; 125-160 ℃; 125-155 ℃; 125-150 ℃; 125-145 ℃; 125-140 ℃; 125-138 ℃; 125-135 ℃; 135-180 ℃; 127-180 ℃; 127-170 ℃; 127-160 ℃; 127-150 ℃; 127-145 ℃; 127-140 ℃; 127-138 ℃; 135 ℃ of 127-; 130-200 ℃; 130-195 ℃; 130-190 ℃; 130-185 ℃; 130-180 ℃; 130-175 ℃; 130-170 ℃; 130-165 ℃ 130-160 ℃; 130-155 ℃; 130-150 ℃; 130-145 ℃; 130-140 ℃; 130-138 ℃; 130-135 ℃; 135-170 ℃; 160 ℃ of 135-; 135-155 ℃; 135-150 ℃; 135-145 ℃; 135-140 ℃; 135-135 ℃; 140-200 ℃; 140-195 ℃; 140-190 ℃; 140-185 ℃; 140-180 ℃; 140-170 ℃; 140-165 ℃; 140-160 ℃; 140-155 ℃; 140-150 ℃; 140-145 ℃; 148-200 ℃; 148-190 ℃; 148-180 ℃; 148-170 ℃; 148-160 ℃; 148-155 ℃; 150 ℃ of 148-; 150-200 ℃; 150-195 ℃; 150-190 ℃; 150-185 ℃; 150-180 ℃; 150-175 ℃; 150-170 ℃; 150-165 ℃; 150-160 ℃; 150-155 ℃; 155-200 ℃; 150-190 ℃; 150-180 ℃; 150-170 ℃; 150-160; 155-190 ℃; 155-180 ℃; 155-170 ℃; 155-165 ℃; Greater than 124 ℃ until 200 ℃; Greater than 125 ℃ until 200 ℃; Greater than 126 ℃ until 200 ℃; Greater than 148 ℃ until 200 ℃.

[055] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 1-99 % by mole of TMCBD and 1-99 % by mole of 1,4-CHDM; 1-95 % by mole of TMCBD and 5-99 % by mole of 1,4-CHDM; 1-90 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-99 % by mole 1,4-CHDM; 1-85 % by mole of TMCBD and 15-99 % by mole of 1,4-CHDM; 1-80 % by mole of TMCBD and 20-99 % by mole of 1,4-CHDM, 1-75 % by mole of TMCBD and 25-99 % by mole of 1,4-CHDM; 1-70 % by mole of TMCBD and 30-99 % by mole of 1,4-CHDM; 1-65 % by mole of TMCBD and 35-99 % by mole of 1,4-CHDM; 1-60 % by mole of TMCBD and 40-99 % by mole of 1,4-CHDM; 1-55 % by mole of TMCBD and 99 % by mole of 1,4-CHDMs of 45-; 1-50 % by mole of TMCBD and 50-99 % by mole of 1,4-CHDM; 1-45 % by mole of TMCBD and 55-99 % by mole of 1,4-CHDM; 1-40 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 60-99 % by mole 1,4-CHDM; 1-35 % by mole of TMCBD and 65-99 % by mole of 1,4-CHDM; 1-30 % by mole of TMCBD and 70-99 % by mole of 1,4-CHDM; 25 % by mole of TMCBDs of 1-and 75-99 % by mole of 1,4-CHDM; 1-20 % by mole of TMCBD and 80-99 % by mole of 1,4-CHDM; 5 % by mole of TMCBDs of 1-1 and 85-99 % by mole of 1,4-CHDM; 1-10 % by mole of TMCBD and 90-99 % by mole of 1,4-CHDM; 1-5 % by mole of TMCBD and 99 % by mole of 1,4-CHDMs of 95-.

[056] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 5-is less than 50 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and greater than 50-95 % by mole of 1,4-CHDM; 5-45 % by mole of TMCBD and 55-95 % by mole of 1,4-CHDM; 5-40 % by mole of TMCBD and 60-95 % by mole of 1,4-CHDM; 5-35 % by mole of TMCBD and 65-95 % by mole of 1,4-CHDM; 5 to less than 35 % by mole of TMCBDs with greater than 65-95 % by mole of 1,4-CHDM; 5-30 % by mole of TMCBD and 70-95 % by mole of 1,4-CHDM; 5-25 % by mole of TMCBD and 75-95 % by mole of 1,4-CHDMs; 5-20 % by mole of TMCBD and 80-95 % by mole of 1,4-CHDM; 5-15 % by mole of TMCBD and 85-95 % by mole of 1,4-CHDM; 5-10 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 90-95 % by mole 1,4-CHDM; Greater than 5 to less than 10 % by mole of TMCBDs and less than 90 to greater than 95 % by mole of 1,4-CHDMs; 5.5-9.5 % by mole TMCBD and 94.5-90.5 % by mole 1,4-CHDM; 6-9 % by mole of TMCBD and 94-91 % by mole of 1,4-CHDM.

[057] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 10-100 % by mole of TMCBD and 0-90 % by mole of 1,4-CHDM; 10-95 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 5-90 % by mole 1,4-CHDM; 10-95 % by mole of TMCBD and 5-90 % by mole of 1,4-CHDM; 10-90 % by mole of TMCBD and 10-90 % by mole of 1,4-CHDM; 85 % by mole of TMCBDs of 10-and 1 5-90 % by mole 1,4-CHDM; 10-80 % by mole of TMCBD and 20-90 % by mole of 1,4-CHDM, 10-75 % by mole of TMCBD and 25-90 % by mole of 1,4-CHDM; 10-70 % by mole of TMCBD and 90 % by mole of 1,4-CHDMs of 30-; 10-65 % by mole of TMCBD and 35-90 % by mole of 1,4-CHDM; 10-60 % by mole of TMCBD and 40-90 % by mole of 1,4-CHDM; 10-55 % by mole of TMCBD and 45-90 % by mole of 1,4-CHDM; 10-50 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 50-90 % by mole 1,4-CHDM; 10 to less than 50 % by mole of TMCBDs with greater than 50-90 % by mole of 1,4-CHDM; 10-45 % by mole of TMCBD and 55-90 % by mole of 1,4-CHDM; 10-40 % by mole of TMCBD and 60-90 % by mole of 1,4-CHDM; 10-35 % by mole of TMCBD and 90 % by mole of 1,4-CHDMs of 65-; 10-is less than 35 % by mole of TMCBDs with greater than 65-90%1, the 4-cyclohexanedimethanol; 10-30 % by mole of TMCBD and 70-90 % by mole of 1,4-CHDM; 10-25 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 75-90 % by mole 1,4-CHDM; 10-20 % by mole of TMCBD and 80-90 % by mole of 1,4-CHDM; 15 % by mole of TMCBDs of 10-and 85-90 % by mole of 1,4-CHDM.

[058] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 14-99 % by mole of TMCBD and 1-86 % by mole of 1,4-CHDM; 14-95 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 5-86 % by mole 1,4-CHDM; 14-90 % by mole of TMCBD and 10-86 % by mole of 1,4-CHDM; 14-85 % by mole of TMCBD and 15-86 % by mole of 1,4-CHDM; 86 % by mole of TMCBDs of 14-and 14-86 % by mole of 1,4-CHDM, 14-75 % by mole of TMCBD and 25-86 % by mole of 1,4-CHDM; 14-70 % by mole of TMCBD and 30-86 % by mole of 1,4-CHDM; 14-65 % by mole of TMCBD and 86 % by mole of 1,4-CHDMs of 35-; 14-60 % by mole of TMCBD and 40-86 % by mole of 1,4-CHDM; 14-55 % by mole of TMCBD and 45-86 % by mole of 1,4-CHDM; 14-50 % by mole of TMCBD and 50-86 % by mole of 1,4-CHDM; 14 to less than 50 % by mole of TMCBDs with greater than 50 to 86 % by mole of 1,4-CHDMs; 14-45 % by mole of TMCBD and 55-86 % by mole of 1,4-CHDM; 14-40 % by mole of TMCBD and 60-86 % by mole of Isosorbide-5-Nitrae-cyclohexanedimethanol; 14-35 % by mole of TMCBD and 65-86 % by mole of 1,4-CHDM; 14-30 % by mole of TMCBD and 70-86 % by mole of 1,4-CHDMs; 1 4-24 % by mole TMCBD and 76-86 % by mole of 1,4-CHDM; 14-25 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 75-86 % by mole 1,4-CHDM.

[059] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 15-99 % by mole of TMCBD and 1-85 % by mole of 1,4-CHDM; 1 5-95 % by mole TMCBD and 5-85 % by mole of 1,4-CHDM; 15-90 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-85 % by mole 1,4-CHDM; 15-85 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 15-85 % by mole 1,4-CHDM; 15-86 % by mole of TMCBD and 15-86 % by mole of 1,4-CHDM, 75 % by mole of TMCBDs of 15-and 25-85 % by mole of 1,4-CHDM; 15-70 % by mole of TMCBD and 30-85 % by mole of 1,4-CHDM; 15-65 % by mole of TMCBD and 35-85 % by mole of 1,4-CHDM; 15-60 % by mole of TMCBD and 85 % by mole of 1,4-CHDMs of 40-; 15-55 % by mole of TMCBD and 45-85 % by mole of 1,4-CHDM; 15-50 % by mole of TMCBD and 50-85 % by mole of 1,4-CHDM; 15 to less than 50 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and greater than 50 to 85 % by mole of 1,4-CHDMs; 15-45 % by mole of TMCBD and 55-85 % by mole of 1,4-CHDM; 15-40 % by mole of TMCBD and 60-85 % by mole of 1,4-CHDM; 15-35 % by mole of TMCBD and 65-85 % by mole of Isosorbide-5-Nitrae-cyclohexanedimethanol; 15-30 % by mole of TMCBD and 70-85 % by mole of 1,4-CHDM; 15-25 % by mole of TMCBD and 85 % by mole of 1,4-CHDMs of 75-; 15-24 % by mole of TMCBD and 76-85 % by mole of 1,4-CHDM.

[060] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 20-99 % by mole of TMCBD and 1-80 % by mole of 1,4-CHDM; 20-95 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 5-80 % by mole 1,4-CHDM; 20-90 % by mole of TMCBD and 10-80 % by mole of 1,4-CHDM; 20-85 % by mole of TMCBD and 15-80 % by mole of 1,4-CHDM; 80 % by mole of TMCBDs of 20-and 20-80 % by mole of 1,4-CHDM, 20-75 % by mole of TMCBD and 25-80 % by mole of 1,4-CHDM; 20-70 % by mole of TMCBD and 30-80 % by mole of 1,4-CHDM; 20-65 % by mole of TMCBD and 80 % by mole of 1,4-CHDMs of 35-; 20-60 % by mole of TMCBD and 40-80 % by mole of 1,4-CHDM; 20-55 % by mole of TMCBD and 45-80 % by mole of 1,4-CHDM; 20-50 % by mole of TMCBD and 50-80 % by mole of 1,4-CHDM; 20 to less than 50 % by mole of TMCBDs with greater than 50-80 % by mole of 1,4-CHDM; 20-45 % by mole of TMCBD and 55-80 % by mole of 1,4-CHDM; 20-40 % by mole of TMCBD and 60-80 % by mole of Isosorbide-5-Nitrae-cyclohexanedimethanol; 20-35 % by mole of TMCBD and 65-80 % by mole of 1,4-CHDM; 20-30 % by mole of TMCBD and 70-80 % by mole of 1,4-CHDMs; 20-25 % by mole of TMCBD and 75-80 % by mole of 1,4-CHDM.

[061] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 25-99 % by mole of TMCBD and 1-75 % by mole of 1,4-CHDM; 25-95 % by mole of TMCBD and 5-75 % by mole of 1,4-CHDM; 25-90 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-75 % by mole 1,4-CHDM; 25-85 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 15-75 % by mole 1,4-CHDM; 25-80 % by mole of TMCBD and 20-75 % by mole of 1,4-CHDM, 75 % by mole of TMCBDs of 25-and 25-75 % by mole of 1,4-CHDM; 25-70 % by mole of TMCBD and 30-75 % by mole of 1,4-CHDM; 25-65 % by mole of TMCBD and 35-75 % by mole of 1,4-CHDM; 25-60 % by mole of TMCBD and 75 % by mole of 1,4-CHDMs of 40-; 25-55 % by mole of TMCBD and 45-75 % by mole of 1,4-CHDM; 25-50 % by mole of TMCBD and 50-75 % by mole of 1,4-CHDM; 25 to less than 50 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and greater than 50-75 % by mole of 1,4-CHDM; 25-45 % by mole of TMCBD and 55-75 % by mole of 1,4-CHDM; 25-40 % by mole of TMCBDs and 60-75 % by mole of 1,4-CHDM; 25-35 % by mole of TMCBD and 65-75 % by mole of 1,4-CHDM; 25-30 % by mole of TMCBD and 70-75 % by mole of 1,4-CHDM.

[062] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 30-99 % by mole of TMCBD and 1-70 % by mole of 1,4-CHDM; 30-95 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 5-70 % by mole 1,4-CHDM; 30-90 % by mole of TMCBD and 10-70 % by mole of 1,4-CHDM; 30-85 % by mole of TMCBD and 15-70 % by mole of 1,4-CHDM; 80 % by mole of TMCBDs of 30-and 20-70 % by mole of 1,4-CHDM; 30-75 % by mole of TMCBD and 25-70 % by mole of 1,4-CHDM; 30-70 % by mole of TMCBD and 30-70 % by mole of 1,4-CHDM; 30-65 % by mole of TMCBD and 70 % by mole of 1,4-CHDMs of 35-; 30-60 % by mole of TMCBD and 40-70 % by mole of 1,4-CHDM; 30-55 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 45-70 % by mole 1,4-CHDM; 30-50 % by mole of TMCBD and 50-70 % by mole of 1,4-CHDM; 30 to less than 50 % by mole of TMCBDs with greater than 50 to 70 % by mole of 1,4-CHDMs; 30-45 % by mole of TMCBD and 55-70 % by mole of 1,4-CHDM; 30-40 % by mole of TMCBD and 60-70 % by mole of Isosorbide-5-Nitrae-cyclohexanedimethanol; 30-35 % by mole of TMCBD and 65-70 % by mole of 1,4-CHDM.

[063] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 35-99 % by mole of TMCBD and 1-65 % by mole of 1,4-CHDM; 35-95 % by mole of TMCBD and 5-65 % by mole of 1,4-CHDM; 35-90 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-65 % by mole 1,4-CHDM; 35-85 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 15-65 % by mole 1,4-CHDM; 35-80 % by mole of TMCBD and 20-65 % by mole of 1,4-CHDM, 75 % by mole of TMCBDs of 35-and 25-65 % by mole of 1,4-CHDM; 35-70 % by mole of TMCBD and 30-65 % by mole of 1,4-CHDM; 35-65 % by mole of TMCBD and 35-65 % by mole of 1,4-CHDM; 35-60 % by mole of TMCBD and 65 % by mole of 1,4-CHDMs of 40-; 3 5-55 % by mole TMCBD and 45-65 % by mole of 1,4-CHDM; 35-50 % by mole of TMCBD and 50-65 % by mole of 1,4-CHDM; 35 to less than 50 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and greater than 50 to 65 % by mole of 1,4-CHDMs; 35-45 % by mole of TMCBD and 55-65 % by mole of 1,4-CHDM; 35-40 % by mole of TMCBDs and 60-65 % by mole of 1,4-CHDM.

[064] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 40-99 % by mole of TMCBD and 1-60 % by mole of 1,4-CHDM; 40-95 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 5-60 % by mole 1,4-CHDM; 40-90 % by mole of TMCBD and 10-60 % by mole of 1,4-CHDM; 40-85 % by mole of TMCBD and 15-60 % by mole of 1,4-CHDM; 80 % by mole of TMCBDs of 40-and 20-60 % by mole of 1,4-CHDM; 40 to less than 80 % by mole of TMCBDs with greater than 20 to 60 % by mole of 1,4-CHDMs; 40-75 % by mole of TMCBD and 60 % by mole of 1,4-CHDMs of 25-; 40-70 % by mole of TMCBD and 30-60 % by mole of 1,4-CHDM; 40-65 % by mole of TMCBD and 35-60 % by mole of 1,4-CHDM; 40-60 % by mole of TMCBD and 40-60 % by mole of 1,4-CHDM; 40-55 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 45-60 % by mole 1,4-CHDM; 40 to less than 50 % by mole of TMCBDs with greater than 50 to 60 % by mole of 1,4-CHDMs; 40-50 % by mole of TMCBD and 50-60 % by mole of 1,4-CHDM; 40-45 % by mole of TMCBD and 55-60 % by mole of 1,4-CHDM.

[065] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 45-99 % by mole of TMCBD and 1-55 % by mole of 1,4-CHDM; 45-95 % by mole of TMCBD and 5-55 % by mole of 1,4-CHDM; 45-90 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-55 % by mole 1,4-CHDM; 45-85 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 15-55 % by mole 1,4-CHDM; 45-80 % by mole of TMCBD and 20-55 % by mole of 1,4-CHDM, 75 % by mole of TMCBDs of 45-and 25-55 % by mole of 1,4-CHDM; 45-70 % by mole of TMCBD and 30-55 % by mole of 1,4-CHDM; 45-65 % by mole of TMCBD and 35-55 % by mole of 1,4-CHDM; 45-60 % by mole of TMCBD and 55 % by mole of 1,4-CHDMs of 40-; Greater than 45 to 55 % by mole of TMCBDs and 45 to less than 55 % by mole of 1,4-CHDMs; 45-55 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 45-55 % by mole 1,4-CHDM; 45-50 % by mole of TMCBD and 50-55 % by mole of 1,4-CHDM; Greater than 45 to 52 % by mole of TMCBDs and 48-55 % by mole of 1,4-CHDM; 46-55 % by mole of TMCBD and 45-54 % by mole of 1,4-CHDM; 48-52 % by mole of TMCBD and 52 % by mole of 1,4-CHDMs of 48-.

[066] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: greater than 50 to 99 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 1 is to less than 50 % by mole of 1,4-CHDMs; Greater than 50 to 90 % by mole of TMCBDs and 10 to less than 50 % by mole of 1,4-CHDMs; Greater than 50 to 85 % by mole of TMCBDs and 15 to less than 50 % by mole of 1,4-CHDMs; Greater than 50 to 80 % by mole of TMCBDs and 20 to less than 50 % by mole of 1,4-CHDMs, greater than 50 to 75 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 25 is to less than 50 % by mole of 1,4-CHDMs; Greater than 50 to 70 % by mole of TMCBDs and 30 to less than 50 % by mole of 1,4-CHDMs; Greater than 50 to 65 % by mole of TMCBDs and 35 to less than 50 % by mole of 1,4-CHDMs; Greater than 50 to 60 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 40 is to less than 50 % by mole of 1,4-CHDMs.

[067] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least-individual following scope combination: 55-99 % by mole of TMCBD and 1-45 % by mole of 1,4-CHDM; 55-95 % by mole of TMCBD and 5-45 % by mole of 1,4-CHDM; 55-90 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-45 % by mole 1,4-CHDM; 55-85 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 15-45 % by mole 1,4-CHDM; 55-80 % by mole of TMCBD and 20-45 % by mole of 1,4-CHDM, 75 % by mole of TMCBDs of 55-and 25-45 % by mole of 1,4-CHDM; 55-70 % by mole of TMCBD and 30-45 % by mole of 1,4-CHDM; 55-65 % by mole of TMCBD and 35-45 % by mole of 1,4-CHDM; 55-60 % by mole of TMCBD and 45 % by mole of 1,4-CHDMs of 40-.

[068] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 60-99 % by mole of TMCBD and 1-40 % by mole of 1,4-CHDM; 60-95 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 5-40 % by mole 1,4-CHDM; 60-90 % by mole of TMCBD and 10-40 % by mole of 1,4-CHDM; 60-85 % by mole of TMCBD and 15-40 % by mole of 1,4-CHDM; 80 % by mole of TMCBDs of 60-and 20-40 % by mole of 1,4-CHDM, 60-75 % by mole of TMCBD and 25-40 % by mole of 1,4-CHDM; 60-70 % by mole of TMCBD and 30-40 % by mole of 1,4-CHDM.

[069] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 65-99 % by mole of TMCBD and 1-35 % by mole of 1,4-CHDM; 65-95 % by mole of TMCBD and 5-35 % by mole of 1,4-CHDM; 65-90 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-35 % by mole 1,4-CHDM; 65-85 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 15-35 % by mole 1,4-CHDM; 65-80 % by mole of TMCBD and 20-35 % by mole of 1,4-CHDM, 75 % by mole of TMCBDs of 65-and 25-35 % by mole of 1,4-CHDM; 65-70 % by mole of TMCBD and 30-35 % by mole of 1,4-CHDM.

[070] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 70-99 % by mole of TMCBD and 1-30 % by mole of 1,4-CHDM; 70-95 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 5-30 % by mole 1,4-CHDM; 70-90 % by mole of TMCBD and 10-30 % by mole of 1,4-CHDM; 70-85 % by mole of TMCBD and 15-30 % by mole of 1,4-CHDM; 80 % by mole of TMCBDs of 70-and 20-30 % by mole of 1,4-CHDM.

[071] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 75-99 % by mole of TMCBD and 1-25 % by mole of 1,4-CHDM; 75-95 % by mole of TMCBD and 5-25 % by mole of 1,4-CHDM; 75-90 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-25 % by mole 1,4-CHDM; 75-85 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 15-25 % by mole 1,4-CHDM.

[072] in other side of the present invention, the diol component that is used for polyester of the present invention includes but not limited at least one following scope combination: 80-99 % by mole of TMCBD and 1-20 % by mole of 1,4-CHDM; 80-95 % by mole 2,2,4,4-tetramethyl-1,3-cyclobutanediol and 5-20 % by mole 1,4-CHDM; 80-90 % by mole 2,2,4,2,2,4,4-tetramethyl-1,3-cyclobutanediol and 10-20 % by mole 1,4-CHDM; Greater than 80 to 90 % by mole of TMCBDs and 10 to less than 20 % by mole of 1,4-CHDMs; Greater than 81 to 90 % by mole of TMCBDs and 10 to less than 19 % by mole of 1,4-CHDMs.

[073] except above-mentioned glycol, the polyester that is used for polymer blend of the present invention also can be by 1,3-PD, BDO or the preparation of its mixture. Think by 1, the present composition of ammediol, BDO or the preparation of its mixture can have at least one Tg scope described here, the logarithmic viscosity number scope that at least one is described here and/or glycol or two acid ranges that at least one is described here. Select in addition or as another kind of, the polyester that is prepared by 1,3-PD, BDO or its mixture also can be prepared by the 1,4-CHDM of at least one following consumption: 0.1-99 % by mole; 0.1-95 % by mole; 0.1-90 % by mole; 0.1-85 % by mole; 0.1-80 % by mole; 0.1-75 % by mole; 0.1-70 % by mole; 0.1-60 % by mole; 0.1-50 % by mole; 0.1-40 % by mole; 0.1-35 % by mole; 0.1-30 % by mole; 0.1-25 % by mole; 0.1-20 % by mole; 0.1-15 % by mole; 0.1-10 % by mole; 0.1-5 % by mole; 99 % by mole of 1-; 1-95 % by mole; 1-90 % by mole; 1-85 % by mole; 1-80 % by mole; 70 % by mole of 1-; 1-60 % by mole; 1-50 % by mole; 1-40 % by mole; 1-35 % by mole; 30 % by mole of 1-; 1-25 % by mole; 1-20 % by mole; 1-15 % by mole; 1-10 % by mole; 5 % by mole of 1-; 5-99 % by mole; 5-95 % by mole; 5-90 % by mole; 5-85 % by mole; 80 % by mole of 5-; 5-75 % by mole; 5-70 % by mole; 5-60 % by mole; 5-50 % by mole; 40 % by mole of 5-; 5-35 % by mole; 5-30 % by mole; 5-25 % by mole; 5-20 % by mole; 15 % by mole of 5-; 5-10 % by mole; 10-99 % by mole; 10-95 % by mole; 10-90 % by mole; 10-85 % by mole; 10-80 % by mole; 10-75 % by mole; 10-70 % by mole; 10-60 % by mole; 10-50 % by mole; 10-40 % by mole; 10-35 % by mole; 10-30 % by mole; 10-25 % by mole; 10-20 % by mole; 10-15 % by mole; 20-99 % by mole; 20-95 % by mole; 20-90 % by mole; 20-85 % by mole; 20-80 % by mole; 20-75 % by mole; 70 % by mole of 20-; 20-60 % by mole; 20-50 % by mole; 20-40 % by mole; 20-35 % by mole; 20-30 % by mole; 20-25 % by mole.

[074] for specific embodiments of the present invention, polyester may be displayed in the phenol/tetrachloroethanes of 60/40 (w/w) under the concentration of 0.5g/100ml in any following logarithmic viscosity number of 25 ℃ of mensuration: 0.35-is less than 0.70dL/g; 0.35-0.68dL/g; 0.35-less than 0.68 dL/g; 0.35-0.65dL/g.; 0.40-0.70dL/g; 0.40 extremely less than 0.70dL/g; 0.40-0.68 dL/g; 0.40 extremely less than 0.68dL/g; 0.40-0.65dL/g; 0.45 extremely less than 0.70dL/g; 0.45-0.68dL/g; 0.45 extremely less than 0.68dL/g; 0.45-0.65dL/g; 0.50 extremely less than 0.70dL/g; 0.50-0.68dL/g; 0.50 extremely less than 0.68dL/g; 0.50-0.67dL/g; 0.50-0.66 dL/g; 0.50-0.65dL/g; 0.55-less than 0.70dL/g; 0.55-0.68dL/g; 0.55 extremely less than 0.68dL/g; 0.55-0.65dL/g; 0.58 extremely less than 0.70dL/g; 0.58-0.68dL/g; 0.58 extremely less than 0.68dL/g; Or 0.58-0.65dL/g.

[075] be 0.35-0.75dL/g or larger embodiment for the logarithmic viscosity number of polyester of the present invention wherein, these polyester also may be displayed in the phenol/tetrachloroethanes of 60/40 (w/w) under the concentration of 0.5g/100ml in any following logarithmic viscosity number of 25 ℃ of mensuration: 0.35-less than 0.75dL/g; 0.35-0.72dL/g; Or 0.35-0.70dl/g.

[076] for specific embodiments of the present invention, polyester may be displayed in the phenol/tetrachloroethanes of 60/40 (w/w) under the concentration of 0.5g/100ml in any following logarithmic viscosity number of 25 ℃ of mensuration: 0.10-1.2dL/g; 0.10-1.1dL/g; 0.10-1dL/g; 0.10 extremely less than 1dL/g; 0.10-0.98dL/g; 0.10-0.95dL/g; 0.10-0.90dL/g; 0.10-0.85 dL/g; 0.10-0.80dL/g; 0.10-0.75dL/g; 0.10-less than 0.75dL/g; 0.10-0.72 dL/g; 0.10-0.70dL/g; 0.10 extremely less than 0.70dL/g; 0.10-0.68dL/g; 0.10-less than 0.68dL/g; 0.10-0.65dL/g; 0.10-0.6dL/g; 0.10-0.55dL/g; 0.10-0.5dL/g; 0.10-0.4dL/g; 0.10-0.35dL/g; 0.20-1.2dL/g; 0.20-1.1dL/g; 0.20-1 dL/g; 0.20 extremely less than 1dL/g; 0.20-0.98dL/g; 0.20-0.95dL/g; 0.20-0.90 dL/g; 0.20-0.85dL/g; 0.20-0.80dL/g; 0.20-0.75dL/g; 0.20 extremely less than 0.75 dL/g; 0.20-0.72dL/g; 0.20-0.70dL/g; 0.20 extremely less than 0.70dL/g; 0.20-0.68 dL/g; 0.20 extremely less than 0.68dL/g; 0.20-0.65dL/g; 0.20-0.6dL/g; 0.20-0.55 dL/g; 0.20-0.5dL/g; 0.20-0.4dL/g; And 0.20-0.35dL/g.

[077] be the embodiment of 0.35-1.2dL/g for the logarithmic viscosity number of polyester of the present invention wherein, these polyester also may be displayed in the phenol/tetrachloroethanes of 60/40 (w/w) under the concentration of 0.5g/100ml in any following logarithmic viscosity number of 25 ℃ of mensuration: 0.35-1.2 dL/g; 0.35-1.1dL/g; 0.35-1dL/g; 0.35 extremely less than 1dL/g; 0.35-0.98dL/g; 0.35-0.95dL/g; 0.35-0.9dL/g; 0.35-0.85dL/g; 0.35-0.8dL/g; 0.35-0.75dL/g; 0.35-less than 0.75dL/g; 0.35-0.72dL/g; 0.40-1.2dL/g; 0.40-1.1 dL/g; 0.40-1dL/g; 0.40-less than 1dL/g; 0.40-0.98dL/g; 0.40-0.95dL/g; 0.40-0.9dL/g; 0.40-0.85dL/g; 0.40-0.8dL/g; 0.40-0.75dL/g; 0.40 extremely less than 0.75dL/g; 0.40-0.72dL/g; Greater than 0.42 to 1.2dL/g; Greater than 0.42 to 1.1dL/g; Greater than 0.42 to 1dL/g; Greater than 0.42 to less than 1dL/g; Greater than 0.42-0.98 dL/g; Greater than 0.42-0.95dL/g; Greater than 0.42 to 0.9dL/g; Greater than 0.42 to 0.85dL/g; Greater than 0.42 to 0.80dL/g; Greater than 0.42 to 0.75dL/g; Greater than 0.42 to less than 0.75dL/g; 0.42-0.70dL/g; 0.42 extremely less than 0.70dL/g; Greater than 0.42 to 0.72dL/g; Greater than 0.42 to 0.70dL/g; Greater than 0.42 to 0.68dL/g; Greater than 0.42 to less than 0.68dL/g; 0.42-0.68dL/g; Greater than 0.42 to 0.65dL/g; 0.45-1.2dL/g; 0.45-1.1dL/g; 0.45-1 dL/g; 0.45-0.98dL/g; 0.45-0.95dL/g; 0.45-0.9dL/g; 0.45-0.85dL/g; 0.45-0.80dL/g; 0.45-0.75dL/g; 0.45 extremely less than 0.75dL/g; 0.45-0.72dL/g; 0.45-0.70dL/g; 0.50-1.2dL/g; 0.50-1.1dL/g; 0.50-1dL/g; 0.50 extremely less than 1dL/g; 0.50-0.98dL/g; 0.50-0.95dL/g; 0.50-0.9dL/g; 0.50-0.85dL/g; 0.50-0.80dL/g.; 0.50-0.75dL/g; 0.50 extremely less than 0.75dL/g; 0.50-0.72dL/g; 0.50-0.70dL/g; 0.55-1.2dL/g; 0.55-1.1dL/g; 0.55-1dL/g; 0.55 extremely less than 1dL/g; 0.55-0.98dL/g; 0.55-0.95dL/g; 0.55-0.9dL/g; 0.55-0.85dL/g; 0.55-0.80dL/g; 0.55-0.75dL/g; 0.55-less than 0.75dL/g; 0.55-0.72dL/g; 0.55-0.70dL/g; 0.58-1.2dL/g; 0.58-1.1dL/g; 0.58-1dL/g; 0.58 extremely less than 1dL/g; 0.58-0.98dL/g; 0.58-0.95dL/g; 0.58-0.9dL/g; 0.58-0.85dL/g; 0.58-0.80dL/g; 0.58-0.75dL/g; 0.58 extremely less than 0.75dL/g; 0.58-0.72dL/g; 0.58-0.70dL/g; 0.60-1.2dL/g; 0.60-1.1dL/g; 0.60-1dL/g; 0.60 extremely less than 1dL/g; 0.60-0.98dL/g; 0.60-0.95dL/g; 0.60-0.90dL/g; 0.60-0.85dL/g; 0.60-0.80dL/g; 0.60-0.75dL/g; 0.60 extremely less than 0.75dL/g; 0.60-0.72dL/g; 0.60-0.70dL/g; 0.60 extremely less than 0.70dL/g; 0.60-0.68dL/g; 0.60 extremely less than 0.68 dL/g; 0.60-0.65dL/g; 0.65-1.2dL/g; 0.65-1.1dL/g; 0.65-1dL/g; 0.65 extremely less than 1dL/g; 0.65-0.98dL/g; 0.65-0.95dL/g; 0.65-0.90dL/g; 0.65-0.85 dL/g; 0.65-0.80dL/g; 0.65-0.75dL/g; 0.65-less than 0.75dL/g; 0.65-0.72 dL/g; 0.65-0.70dL/g; 0.65 extremely less than 0.70dL/g; 0.68-1.2dL/g; 0.68-1.1 dL/g; 0.68-1dL/g; 0.68-less than 1dL/g; 0.68-0.98dL/g; 0.68-0.95dL/g; 0.68-0.90dL/g; 0.68-0.85dL/g; 0.68-0.80dL/g; 0.68-0.75dL/g; 0.68 extremely less than 0.75dL/g; 0.68-0.72dL/g; Greater than 0.70dL/g to 1.2dL/g; Greater than 0.76 dL/g to 1.2dL/g; Greater than 0.76 dL/g to 1.1dL/g; Greater than 0.76dL/g to 1dL/g; Greater than 0.76dL/g to less than 1dL/g; Greater than 0.76dL/g to 0.98dL/g; Greater than 0.76dL/g to 0.95dL/g; Greater than 0.76dL/g to 0.90dL/g; Greater than 0.80dL/g to 1.2dL/g; Greater than 0.80dL/g to 1.1dL/g; Greater than 0.80dL/g to 1dL/g; Greater than 0.80dL/g to less than 1dL/g; Greater than 0.80dL/g to 1.2dL/g; Greater than 0.80dL/g to 0.98dL/g; Greater than 0.80 dL/g to 0.95dL/g; Greater than 0.80dL/g to 0.90dL/g.

[078] thinks that composition of the present invention can have at least one in logarithmic viscosity number scope disclosed herein and at least one is in compositing monomer scope disclosed herein, except as otherwise noted. Think that also composition of the present invention can have at least one in Tg scope disclosed herein and at least one is in compositing monomer scope disclosed herein, except as otherwise noted. Also think composition of the present invention can have at least one in Tg scope disclosed herein, at least one is in logarithmic viscosity number scope disclosed herein and at least one is in compositing monomer scope disclosed herein, except as otherwise noted.

[079] for required polyester, the mol ratio of suitable/anti-TMCBD can change from pure form or its mixture separately. In certain embodiments, the molar percentage of cis and/or trans TMCBD is greater than 50 % by mole of cis and trans less than 50 % by mole; Or greater than 55 % by mole of cis and trans less than 45 % by mole; Or 30-70 % by mole of cis and 70-30% are trans; Or 40-60 % by mole of cis and 60-40 % by mole are trans; Or 50-70 % by mole of trans and 50-30% cis; Or 50-70 % by mole of cis and 50-30% are trans; Or 60-70 % by mole of cis and 30-40 % by mole are trans; Or greater than 70 % by mole of cis and trans less than 30 % by mole; Wherein cis-and total molar percentage of trans-TMCBD equal 100 % by mole. The mol ratio of cis/trans 1,4-CHDM can change in the scope of 50/50-0/100, for example 40/60-20/80.

[080] in certain embodiments, terephthalic acid (TPA), its ester (for example dimethyl terephthalate (DMT)) or the mixture of terephthalic acid (TPA) and its ester occupy the most of of the dicarboxylic acid component that forms polyester of the present invention or all. In certain embodiments, the terephthalic acid residue can with at least 70 % by mole, for example at least 80 % by mole, at least 90 % by mole, at least 95 % by mole, at least 99 % by mole or even 100 % by mole concentration occupy part or all of the dicarboxylic acid component that forms polyester of the present invention. The terephthalic acid (TPA) that in certain embodiments, can use higher amount has polyester than high impact with preparation. For disclosed purpose, term " terephthalic acid (TPA) " and " dimethyl terephthalate (DMT) " here can Alternates. In one embodiment, dimethyl terephthalate (DMT) be for the preparation of the dicarboxylic acid component of polyester of the present invention partly or entirely. In all embodiments, can use 70-100 % by mole or 80-100 % by mole or 90-100 % by mole or 99-100 % by mole or even 100 % by mole terephthalic acid (TPA) and/or dimethyl terephthalate (DMT) and/or its mixture.

[081] except the terephthalic acid residue, the dicarboxylic acid component who is used for polyester of the present invention can be contained 30 % by mole at the most, 20 % by mole at the most, 10 % by mole at the most, at the most 5 % by mole or one or more modified aromatic dicarboxylic acids of 1 % by mole at the most. Another embodiment contains 0 % by mole modified aromatic dicarboxylic acids. Therefore, if present, think that the amount of one or more modified aromatic dicarboxylic acids can be the scope between any above-mentioned endpoint value, comprise for example 0.01-30 % by mole, 0.01-20 % by mole, 0.01-10 % by mole, 0.01-5 % by mole and 0.01-1 % by mole. In one embodiment, can be used for modified aromatic dicarboxylic acids of the present invention and include but not limited to have those of 20 carbon atoms at the most, it can be linear, p-orientation or symmetry. The example that can be used for modified aromatic dicarboxylic acids of the present invention include but not limited to M-phthalic acid, 4,4'-diphenyldicarboxylic acids, Isosorbide-5-Nitrae-, 1,5-, 2,6-, 2,7-naphthalenedicarboxylic acid and anti--4,4 '-Stilbene dioctyl phthalate, and their ester. In one embodiment, the modified aromatic dicarboxylic acids is M-phthalic acid.

[082] be used for the carboxyl acid component of polyester of the present invention can be further with 10 % by mole at the most, as at the most 5 % by mole or at the most one or more of 1 % by mole contain the aliphatic dicarboxylic acid modification of 2-16 carbon atom, for example malonic acid, butanedioic acid, glutaric acid, adipic acid, pimelic acid, suberic acid, azelaic acid and dodecane dioctyl phthalate. Some embodiment also can contain 0.01 % by mole or more, such as 0.1 % by mole or more, 1 % by mole or more, 5 % by mole or more or 10 % by mole or more one or more modification aliphatic dicarboxylic acids. Another embodiment contains 0 % by mole modification aliphatic dicarboxylic acid. Therefore, if present, think that the amount of one or more modification aliphatic dicarboxylic acids can be the scope between any above-mentioned endpoint value, comprise for example 0.01-15 % by mole and 0.1-10 % by mole. Total % by mole of the dicarboxylic acid component is 100 % by mole.

[083] can use the ester of terephthalic acid (TPA) and other modification dicarboxylic acids or its corresponding esters and/or salt to replace dicarboxylic acids. The suitable example of dicarboxylic ester includes but not limited to dimethyl esters, diethyl ester, dipropyl, diisopropyl ester, dibutyl ester and diphenyl. In one embodiment, these esters are selected from following at least a: methyl ester, ethyl ester, propyl diester, isopropyl esters and phenylester.

[084] 1,4-CHDM can be cis, trans or its mixture, and for example suitable/inverse proportion is 60: 40 to 40: 60. In another embodiment, anti--1,4-CHDM can exist with 60-80 % by mole amount.

[085] be used for polymer blend of the present invention, the diol component of polyester portion can contain 25 % by mole or one or more modification glycol different from TMCBD or Isosorbide-5-Nitrae-cyclohexanedimethanol still less; In one embodiment, be used for polyester of the present invention and can contain one or more modification glycol less than 15 % by mole. In another embodiment, be used for polyester of the present invention and can contain 10 % by mole or one or more modification glycol still less. In another embodiment, be used for polyester of the present invention and can contain 5 % by mole or one or more modification glycol still less. In another embodiment, be used for polyester of the present invention and can contain 3 % by mole or one or more modification glycol still less. In another embodiment, be used for polyester of the present invention and can contain 0 % by mole modification glycol. Some embodiment also can contain 0.01 % by mole or more, such as 0.1 % by mole or more, 1 % by mole or more, 5 % by mole or more or 10 % by mole or more one or more modification glycol. Therefore, if present, think that the amount of one or more modification glycol can be the scope between any above-mentioned endpoint value, comprise for example 0.01-15 % by mole and 0.01-10 % by mole.

[086] the modification glycol that is used for polyester of the present invention refers to different from TMCBD or 1,4-CHDM and contains the glycol of 2-16 carbon atom. The example of suitable modification glycol includes but not limited to ethylene glycol, diethylene glycol (DEG), 1,2-PD, 1,3-PD, neopentyl glycol, BDO, 1,5-PD, 1,6-hexylene glycol, paraxylene glycol or their mixture. In one embodiment, the modification glycol is ethylene glycol. In another embodiment, the modification glycol includes but not limited to 1,3-PD and/or BDO. In another embodiment, the modification glycol does not comprise ethylene glycol. In another embodiment, the modification glycol does not comprise 1,3-propane diols and BDO. In another embodiment, the modification glycol does not comprise NPG.

[087] is used for the polyester of polymer blend of the present invention and/or Merlon and can contains respectively residue (being also referred to as branching agent here) or its combination that has the branched monomer of 3 or more carboxyl substituents, hydroxyl substituent or its combination based on one or more of 0.5 % by mole of glycol or the total molar percentage meter of diacid residues 0-10 % by mole, for example 0.01-5 % by mole, 0.01-1 % by mole, 0.05-5 % by mole, 0.05-1 % by mole or 0.1-0.7 % by mole or 0.1-. In certain embodiments, branched monomer or branching agent can before the polymerization of polyester and/or during and/or add afterwards. Being used for polyester of the present invention therefore can be linearity or branching. Merlon also can be linearity or branching. In certain embodiments, branched monomer or branching agent can before the polymerization of Merlon and/or during and/or add afterwards.

[088] example of branched monomer includes but not limited to polyfunctional acid or polyfunctional alcohol, such as trimellitic acid, trimellitic anhydride, PMDA, trimethylolpropane, glycerine, pentaerythrite, citric acid, tartaric acid, 3-hydroxyl glutaric acid etc. In one embodiment, the branched monomer residue can contain one or more of 0.1-0.7 % by mole and be selected from least a following residue: trimellitic anhydride, PMDA, glycerine, sorbierite, 1,2,6-hexanetriol, pentaerythrite, trimethylolethane and/or 1,3,5-benzenetricarboxylic acid. Branched monomer can be added in the pet reaction mixture or with the polyester blend of concentrate form, for example be described in United States Patent (USP) 5,654, in 347 and 5,696,176, be incorporated herein the disclosure about branched monomer wherein for reference.

[089] glass transition temperature (Tg) is what to use from the TA DSC 2920 of Thermal Analyst Instrument with 20 ℃/minute determination of scan rate.

[090] because some used polyester of the present invention has long half-crystallization time (for example greater than 5 minutes) at 170 ℃, so can article of manufacture, include but not limited to articles injection-moulded, injection-blow molding goods, injection drawing blow goods, extruded film, extrusion sheet, extrusion-blow molding product and fiber. Polyester of the present invention can be amorphous or hemicrystalline. In one aspect, some used polyester of the present invention can have lower degree of crystallinity. Therefore, some used polyester of the present invention can have essentially amorphous rheology, and the expression polyester contains substantially unordered polymer areas.

[091] in one embodiment, the half-crystallization time of " amorphous " polymer can 170 ℃ greater than 5 minutes or 170 ℃ greater than 10 minutes 170 ℃ greater than 50 minutes or at 170 ℃ greater than 100 minutes. In one embodiment of the invention, half-crystallization time is greater than 1000 minutes at 170 ℃. In another embodiment, the half-crystallization time for polyester of the present invention is greater than 10000 minutes at 170 ℃. Can use the method that well known to a person skilled in the art to detect in half-crystallization time used herein. For example, the half-crystallization time t1/2 of polyester can by via the light transmittance of laser and photo-detector test sample along with the time on the temperature control heating platform changes to measure. This detection can be by making polymer be exposed to temperature T max, then being cooled to required temperature and carrying out. Then sample is remained on required temperature by warm table, detect simultaneously transmissivity over time. During beginning, the sample range estimation is transparent, has high transmission rate, and becomes muddy along with the sample crystallization. Half-crystallization time is the time that light transmittance is in the half between initial light transmittance and the final light transmittance. Tmax is defined as the needed temperature in crystalline phase farmland (if the crystalline phase farmland exists) of fusing sample. Sample can be heated to Tmax before detecting half-crystallization time, to regulate sample. Absolute Tmax is different for each composition. For example, PCT can be heated to than 290 ℃ of high temperature with fused junction crystalline phase farmland.

[092] such as the table 1 of embodiment and shown in Figure 1,2,2,4,4-tetramethyl-1, the 3-cyclobutanediol than other comonomer for example ethylene glycol and M-phthalic acid increasing aspect half-crystallization time more effectively, namely polymer reaches half required time of its maximum degree of crystallinity. By reducing the crystalline rate of PCT, namely increase half-crystallization time, can produce by means commonly known in the art based on the amorphous goods of the PCT of modification, such as extrude, injection moulding etc. As shown in table 1, these materials show than the higher glass transition temperature of the PCT copolyesters of other modification and lower density.

[093] for some embodiment of the present invention, polyester shows the improvement of toughness and processability combination. For example, the logarithmic viscosity number that reduces polyester of the present invention can obtain the better melt viscosity of processability, and the good physical behavior that keeps simultaneously polyester is toughness and heat resistance for example.

[094] improves 1, the 4-cyclohexanedimethanol is based on terephthalic acid (TPA), ethylene glycol and 1, content in the copolyesters of 4-cyclohexanedimethanol can improve toughness, and this can be by detecting the brittle-ductile transition temperature measuring according to ASTM D256 in the notched izod strength test. Think that this improvement by the toughness that realizes with 1,4-CHDM reduction brittle-ductile transition temperature is because the flexibility of the 1,4-CHDM in copolyesters and conformation behavior cause. Think that introducing TMCBD in the PCT can improve toughness by reducing the brittle-ductile transition temperature, such as the table 2 of embodiment and shown in Figure 2.

[095] in one embodiment, in the rotation melt rheometer, be less than 30000 pools 290 ℃ of melt viscosities that record polyester of the present invention under 1 radian per second. In another embodiment, in the rotation melt rheometer, be less than 20000 pools 290 ℃ of melt viscosities that record polyester of the present invention under 1 radian per second.

[096] in one embodiment, in the rotation melt rheometer, be less than 15000 pools 290 ℃ of melt viscosities that record polyester of the present invention under 1 radian per second.

[097] in one embodiment, in the rotation melt rheometer, be less than 10000 pools 290 ℃ of melt viscosities that record polyester of the present invention under 1 radian per second. In another embodiment, in the rotation melt rheometer, be less than 6000 pools 290 ℃ of melt viscosities that record polyester of the present invention under 1 radian per second. Viscosity under radian per second is relevant with processability. Viscosity when typical polymer detects under its processing temperature under 1 radian per second is less than 10000 pools. Polyester is not usually in the temperature processing that is higher than 290 ℃. Merlon is processed 290 ℃ temperature usually. Merlon viscosity under typical case's 12 melt flow of 1 radian per second is 7000 pools at 290 ℃.

[098] polyester of the present invention can have one or more following performances. As described in ASTM D256, notched izod intensity is the toughness detection method of commonly using. In one embodiment, in the thick rod of 3.2mm (1/8 inch), are 150J/m (3ft-lb/in) at least with the breach of 10 mils 23 ℃ of notched izod intensity that record polyester of the present invention according to ASTM D256; In one embodiment, in the thick rod of 3.2mm (1/8 inch), are 400J/m (7.5ft-lb/in) at least with the breach of 10 mils 23 ℃ of notched izod intensity that record polyester of the present invention according to ASTM D256; In one embodiment, in the thick rod of 3.2mm (1/8 inch), are 1000J/m (18ft-lb/in) at least with the breach of 10 mils 23 ℃ of notched izod intensity that record polyester of the present invention according to ASTM D256. In one embodiment, in the thick rod of 6.4mm (1/4 inch), are 150J/m (3ft-lb/in) at least with the breach of 10 mils 23 ℃ of notched izod intensity that record polyester of the present invention according to ASTM D256; In one embodiment, in the thick rod of 6.4mm (1/4 inch), are 400J/m (7.5ft-lb/in) at least with the breach of 10 mils 23 ℃ of notched izod intensity that record polyester of the present invention according to ASTM D256; In one embodiment, in the thick rod of 6.4mm (1/4 inch), are 1000J/m (18ft-lb/in) at least with the breach of 10 mils 23 ℃ of notched izod intensity that record polyester of the present invention according to ASTM D256.

[099] in another embodiment, being used for some polyester of the present invention demonstrates according to ASTM D256 at 1/8 inch thick rod with the breach of 10 mils 0 ℃ of notched izod strength ratio that records at-5 ℃ of notched izod strength increases 3% or 5% or 10% or 15% that record at least at least at least at least. In addition, some other polyester also can demonstrate according to ASTM D256 and remain when detecting for 0-30 ℃ ± 5% notched izod intensity with the breach of 10 mils in 1/8 inch thick rod.

[0100] in another embodiment, with compare in the notched izod intensity of 23 ℃ of detections according to ASTM D256 breach with 10 mils in 1/8 inch thick rod, be used for some polyester of the present invention and demonstrate to lose when detecting for 23 ℃ with the breach of 10 mils at 1/4 inch thick rod according to ASTM D256 and be no more than 70% notched izod intensity.

[0101] in one embodiment, based on the breach according to ASTM D256 10 mils in 1/8 inch thick rod, for the ductile-brittle transition temperature of polyester demonstration of the present invention less than 0 ℃.

[0102] in one embodiment, use the gradient column density 23 ℃ of detections, be used for polyester of the present invention and show at least one following density: 23 ℃ density less than 1.2g/ml; 23 ℃ density less than 1.18g/ml; Be 0.8-1.3g/ml 23 ℃ density; Be 0.80-1.2g/ml 23 ℃ density; Be 0.8 to less than 1.2g/ml 23 ℃ density; Be 1.0-1.3g/ml 23 ℃ density; Be 1.0-1.2g/ml 23 ℃ density; Be 1.0-1.1g/ml 23 ℃ density; Be 1.13-1.3g/ml 23 ℃ density; Be 1.13-1.2g/ml 23 ℃ density.

[0103] in one embodiment, being used for polyester of the present invention can generally be that range estimation is transparent. Term " estimates transparent " here to be defined as do not have appreciable muddiness, mist degree and/or dirt when visual observations. In another embodiment, when polyester and Merlon (including but not limited to bisphenol-a polycarbonate) blend, blend can be that range estimation is transparent.

[0104] in another embodiment of the invention, the xanthochromia index (ASTM D-1925) that is used for polyester of the present invention can be less than 50 or less than 20.

[0105] in one embodiment, be used for polyester of the present invention and/or polymer blend of the present invention (containing or do not contain toner) and can have colour L^*、a ^*And b^*, using Hunter Lab Inc.Reston, the Hunter Lab Ultrascan Spectra Colorimeter that Va. produces measures. The color detection value is the mean value of the value that detects to the pellet of polyester or by its injection moulding or the sheet material of extruding or other goods. They are by the L of CIE^*a ^*b ^*Colour system is measured (Intemational Commission on Illumination) (translating), wherein L^*The expression lightness dimension, a^*Represent red/green coordinate, b^*Expression Huang/blue coordinate. In certain embodiments, the b of polyester of the present invention^*Value can be-10 to less than 10, L^*Value can be 50-90. In other embodiments, the b of polyester of the present invention^*Value can be in one of following scope :-10 to 9;-10 to 8;-10 to 7;-10 to 6;-10 to 5;-10 to 4;-10 to 3;-10 to 2;-5 to 9;-5 to 8;-5 to 7;-5 to 6;-5 to 5;-5 to 4;-5 to 3;-5 to 2; 0 to 9; 0 to 8; 0 to 7; 0 to 6; 0 to 5; 0 to 4; 0 to 3; 0 to 2; 1 to 10; 1 to 9; 1 to 8; 1 to 7; 1 to 6; 1 to 5; 1 to 4; 1 to 3; With 1 to 2. In other embodiments, the L of polyester of the present invention^*Value can be in one of following scope: 50-60; 50-70; 50-80; 50-90; 60-70; 60-80; 60-90; 70-80; 79-90.

[0106] in some embodiments, use polymer blend of the present invention that drying steps before melt processing and/or thermoforming is minimized and/or do not need drying steps.

[0107] polyester portion in polymer blend of the present invention can by the known method preparation of document, for example by the method in homogeneous solution, by the ester exchange method in melt, and be passed through the two-phase interface method. Suitable method includes but not limited to make the reaction under the pressure of 100-315 ℃ temperature and 0.1-760mmHg of one or more dicarboxylic acids and one or more glycol to be enough to form the time of polyester. Can referring to United States Patent (USP) 3,772,405, will be incorporated herein about the disclosure of these methods for reference about the method for producing polyester.

[0108] on the other hand, the present invention relates to a kind of method of producing polyester. The method comprises:

The mixture that (I) will contain the monomer that in any polyester of the present invention, uses in the presence of catalyst in time that 150-240 ℃ of heating is enough to prepare initial polyester;

(II) will be from the initial polyester of step (I) 240-320 ℃ temperature heating 1-4 hour; With

(III) remove any unreacted glycol.

[0109] catalyst that is applicable to the method includes but not limited to organic zinc compound or organo-tin compound. The use of this catalyst is well known in the art. Be used for catalyst of the present invention and for example include but not limited to zinc acetate, three-2 ethyl hexanoic acid butyl tin, oxalic acid two fourth tin and/or dibutyl tin oxides. Other catalyst can include but not limited to based on those of titanium, zinc, manganese, lithium, germanium and cobalt. The amount of catalyst can be 10-20000ppm or 10-10000ppm, or 10-5000ppm or 10-1000ppm or 10-500ppm, or 10-300ppm or 10-250ppm, based on catalyst metals with based on the weighing scale of final polymer. The method can be carried out according to intermittence or continuous processing.

[0110] general, step (I) can be carried out until 50 % by weight or more 2,2,4,4-tetramethyl-1, and the 3-cyclobutanediol reacts. Step (I) can be carried out to the pressure of 100psig at atmospheric pressure. The expression of the term " product " of relevant use with catalyst system therefor among the present invention here any with catalyst and in the preparation polyester polycondensation of used monomer or the product of esterification, and the polycondensation between catalyst and any other additive types or the product of esterification.

[0111] general, step (II) and step (III) can be carried out simultaneously. These steps can be carried out by means commonly known in the art, for example by reactant mixture being placed 0.002psig to the pressure that is lower than barometric pressure range, or by hot nitrogen being blown over this mixture.

[0112] the invention further relates to a kind of polyester product of producing by said method.

[0113] the invention further relates to a kind of blend polymer. This blend comprises:

(a) at least a above-mentioned polyester of 5-95 % by weight; With

(b) at least a polymers compositions of 5-95 % by weight.

[0114] suitable example of polymers compositions include but not limited to nylon, from above-mentioned different polyester, polyamide (for example from DuPont ZYTEL ); Polystyrene; Polystyrene copolymer; Styrene/acrylonitrile copolymer; The acrylonitrile/butadiene/styrene copolymer; Polymethyl methacrylate, acrylic copolymer; PEI, for example ULTEM  (a kind of PEI from General Electric); Polyphenylene oxide, for example poly-2,6-dimethylphenylene ether or polyphenyl ether/styrene blend, for example NORYL 1000  (a kind of blend that gathers 2,6-dimethylphenylene ether and polystyrene resin from General Electric); Polyphenylene sulfide; Polyphenylene sulfide/sulfone; Polyester/carbonic ester; Merlon, for example LEXAN  (a kind of Merlon from General Electric); Polysulfones; Polysulfones ether; The polyether-ketone of aromatic dihydroxy compound; Or the mixture of any above-mentioned polymer. Described blend can be by conventional machining technology preparation well known in the art, for example melt blending or solution blending. In one embodiment, in polymer blend, there is not Merlon. If use Merlon in blend in polymer blend of the present invention, then this blend can be that range estimation is transparent. But, be used for polymer blend of the present invention and also can get rid of Merlon or comprise Merlon.

[0115] being used for Merlon of the present invention can be according to known program preparation, for example by making dihydroxy aromatic compounds and carbonate precursor (for example phosgene, haloformate or carbonic ester), molecular weight regulator, acid acceptor and catalyst reaction. The method for preparing Merlon is well known in the art, for example is described in United States Patent (USP) 4,452, in 933, is incorporated herein the content about the Merlon preparation wherein for reference.

[0116] example of suitable carbonate precursor includes but not limited to carbonyl bromine, carbonyl chlorine or its mixture; Dipheryl carbonate base ester; Carbonic acid two (halogenophenyl) ester, such as carbonic acid two (trichlorophenyl) ester, carbonic acid two (tribromo phenyl) ester etc.; Carbonic acid two (alkyl phenyl) ester, for example carboxylol base ester; Carbonic acid two (naphthyl) ester; Carbonic acid two (chloronaphthyl, methylnaphthyl) ester, or its mixture; Haloformate with dihydric phenol.

[0117] example of suitable molecular weight regulator includes but not limited to phenol, cyclohexanol, methyl alcohol, alkylated phenol, such as octyl phenol, p-t-butyl phenol etc. In one embodiment, molecular weight regulator is phenol or alkylated phenol.

[0118] acid acceptor can be organic acid or examples of inorganic acceptors. Suitable organic acid acceptor can be tertiary amine, includes but not limited to pyridine, triethylamine, dimethylaniline, tri-n-butylamine etc. Examples of inorganic acceptors can be hydroxide, carbonate, bicarbonate or the phosphate of alkali metal or alkaline-earth metal.

[0119] operable catalyst includes but not limited to usually to assist those of polymerisation of monomer and phosgene. Suitable catalyst includes but not limited to tertiary amine, for example triethylamine, tripropyl amine (TPA), DMA; Quaternary ammonium compound, for example tetraethylammonium bromide, cetyltriethylammonium bromide, four n-heptyl ammonium iodides, four n-pro-pyl bromination ammoniums, tetramethyl ammonium chloride, TMAH, tetrabutylammonium iodide, benzyltrimethylammonium chloride; With quaternary phosphonium  compound, for example normal-butyl tri-phenyl-phosphorus bromide  and methyltriphenylphospbromide bromide phosphorus .

[0120] Merlon for polymer blend of the present invention also can be copolyestercarbonates, for example is disclosed in United States Patent (USP) 3,169,121,3,207,814,4,194,038,4,156,069,4,430,484,4,465,820 and 4,981, in 898 those are incorporated herein the content about copolyestercarbonates in these United States Patent (USP)s for reference.

[0121] being used for copolyestercarbonates of the present invention can and/or can prepare by means commonly known in the art from the commerce acquisition. For example, they can be usually mixture reaction acquisition by at least a dihydroxy aromatic compounds and phosgene and at least a diacid chloride (particularly m-phthaloyl chloride, paraphthaloyl chloride or the two).

[0122] in addition, contain the polymer blend of polyester of the present invention and polymer blend composition and also can contain conventional additives based on 0.01-25 % by weight or 0.01-20 % by weight or 0.01-15 % by weight or 0.01-10 % by weight or the 0.01-5 % by weight of polymer blend gross weight meter, for example colouring agent, dyestuff, releasing agent, fire retardant, plasticizer, nucleator, stabilizing agent (including but not limited to UV stabilizing agent, heat stabilizer and/or its mixture), filler and impact modifying agent. Be used for the present invention and the commercially available impact modifying agent of typical case well known in the art and for example include but not limited to the ethylene/propene ter-polymers; Functionalised polyolefin for example contains those of methyl acrylate and/or GMA; The block copolymer impact modifying agent of styrene-based; With various acrylic compounds core/shell type impact modifying agents. For example, can be by adding in the body, by the coating hard conating or by the coextrusion finishing coat UV additive being introduced in the goods of the present invention's production. The residue of these additives also is the part of polymer blend of the present invention.

[0123] polyester of the present invention can contain at least a chain extender. Suitable chain extender includes but not limited to multifunctional (including but not limited to difunctionality) isocyanates, multi-functional epoxy's compound, comprises for example epoxy radicals linear phenol-aldehyde resin, and phenoxy resin. In certain embodiments, chain extender can add when polymerization technique finishes or after polymerization technique. If after polymerization technique, add, then chain extender can conversion process for example injection moulding or extrude during by mixing or introducing by adding. The consumption of chain extender can change according to used concrete monomer composition and required physical property, but about 10 % by weight of normally about 0.1-, and preferred about 5 % by weight of about 0.1-are based on the gross weight meter of polyester.

[0124] heat stabilizer is to include but not limited to phosphorus-containing compound at the compound of stabilized polyester during the production of polyester and/or between rear polymerization period, includes but not limited to phosphoric acid, phosphorous acid, phosphonic acids, phosphinic acids, phosphonous acid and their various esters and salt. They may reside in the polymer blend of the present invention. These esters can be the aryl esters of Arrcostab, difunctionality Arrcostab, alkyl ether, aryl ester and the replacement of Arrcostab, branched alkyl ester, replacement. In one embodiment, the ester group number that exists in concrete phosphorus-containing compound can be from 0 until based on the admissible maximum number of hydroxy number meter that exists used stabilizing agent. Term " heat stabilizer " expression comprises its product. The term that here uses with heat stabilizer of the present invention " product " be illustrated in heat stabilizer and any in producing polyester the polycondensation between the used monomer or the spawn of esterification, and the polycondensation between catalyst and any other additive types or the spawn of esterification.

[0125] reinforcing material can be used for composition of the present invention. Reinforcing material can include but not limited to carbon monofilament, silicate, mica, clay, talcum, titanium dioxide, wollastonite, sheet glass, bead and fiber, polymer fiber and their mixture. In one embodiment, reinforcing material is glass, fibrous glass fiber for example, the mixture of glass and talcum, the mixture of glass and mica, and the mixture of glass and polymer fiber.

[0126] in another embodiment, the invention further relates to the article of manufacture that contains any above-mentioned polyester and blend.

[0127] in another embodiment, the invention further relates to the article of manufacture that contains any above-mentioned polyester and blend. Extrude, the goods of calendering and/or molding, include but not limited to injection-molded item, extruded product, casting extruded product, thermoformed articles, section bar extrusion goods, melt spinning goods, thermoformed articles, extrusion molding goods, injection-blow molding goods, injection drawing blow goods, extrusion-blow molding product and extrude the stretch-blow goods. These goods can include but not limited to film, bottle (including but not limited to infant bottle), container, sheet material and/or fiber.

[0128] polyester of the present invention and/or polyester blend compositions can be used to form fiber, film, moulding article, container and sheet material. The method that polyester is formed fiber, film, moulding article, container and sheet material is well known in the art. The example of potential moulding article includes but not limited to: Medical Devices, for example dialysis equipment, medical treatment bag, health material; The commercial food product dinnerware article, for example food tray, steam plate, glass and storage bin, infant bottle, food processor, mixer and mixing bowl, apparatus, water bottle, Freshness keeping disc, rinsing maching front end and vacuum cleaner parts. Other potential moulding article includes but not limited to ophthalmic lens and mirror holder. For example, this material can include but not limited to infant bottle for the production of bottle, because this material is transparent, toughness, stable on heating, and shows good hydrolytic stability.

[0129] in another embodiment, the invention further relates to the article of manufacture that contains film and/or sheet material, described film and/or sheet material contain above-mentioned polymer blend.

[0130] be used for film of the present invention and/or sheet material and can have any thickness, thickness is obvious to those skilled in the art. In one embodiment, the thickness of film of the present invention is no more than 40 mils. In one embodiment, the thickness of film of the present invention is no more than 35 mils. In one embodiment, the thickness of film of the present invention is no more than 30 mils. In one embodiment, the thickness of film of the present invention is no more than 25 mils. In one embodiment, the thickness of film of the present invention is no more than 20 mils.

[0131] in one embodiment, the thickness of sheet material of the present invention is not less than 20 mils. In another embodiment, the thickness of sheet material of the present invention is not less than 25 mils. In another embodiment, the thickness of sheet material of the present invention is not less than 30 mils. In another embodiment, the thickness of sheet material of the present invention is not less than 35 mils. In another embodiment, the thickness of sheet material of the present invention is not less than 40 mils.

[0132] the invention further relates to film and/or the sheet material that contains polymer blend of the present invention. The method that makes polyester form film and/or sheet material is well known in the art. Film of the present invention and/or sheet material include but not limited to film and/or the sheet material extruded, the film of calendering and/or sheet material, the film of compression moulding and/or sheet material, the film of solution casting and/or sheet material. The method of producing film and/or sheet material includes but not limited to extrude, calendering, compression moulding and solution casting.

[0133] includes but not limited to the film of uniaxial tension, biaxial stretch-formed film, shrink film (no matter whether single shaft or biaxial stretch-formed), the goods of liquid crystal display film (including but not limited to diffusion sheet, compensate film and diaphragm), thermoforming sheet, direction board film, outdoor mark, skylight, coating, coating, goods, laminated material, laminated product and/or many walls film or the sheet material of japanning by the example of the potential goods of described film and/or sheet production.

[0134] example of direction board film includes but not limited to business card, film conversion lamination; The attractable point display; Plane on washing machine or in-mold decoration plate; Plane contact panel on the refrigerator; Flat board on baking oven; The interior trim that is used for automobile; The instrument board of automobile; Phone cover; Heating and Ventilation Control display; The automobile shock dish; Automobile tire displacement dish; The control display device or the warning mark that are used for automobile instrument panel; Panel on the household articles, button or display screen; Panel on the washing machine, button or display screen; Panel on the dishwasher, button or display screen; The keyboard of electronic equipment; The keyboard of mobile phone, PDA (hand-held computer) or remote controller; The display screen of electronic equipment; Palmtronic is the display of phone and PDA for example; The panel and the shell that are used for automobile or standard telephone; Sign on the electronic equipment; With the sign that is used for mobile phone.

[0135] many walls film or sheet material represent the sheet material as section bar extrusion, and it is comprised of the multilayer that connects via vertical bar each other. The example of many walls film or sheet material includes but not limited to greenhouse and commercial shelter.

[0136] example of extruded product includes but not limited to be used to indicate the film in board, coating, outdoor sign, skylight; the film that is used for the resin glass laminated material; and liquid crystal display (LCD) film, include but not limited to diffuser sheet material, compensate film and diaphragm.

[0137] abbreviation used herein " wt " expression " weight ".

[0138] following examples further specify and how to prepare and estimate polymer blend of the present invention, only are used to explain the present invention, do not limit the scope of the invention.Except as otherwise noted, umber is a weight part, and temperature is ℃ or room temperature, and pressure is normal atmosphere or near normal atmosphere.

Embodiment

Detection method

[0139] logarithmic viscosity number of polyester be in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration.

[0140] except as otherwise noted, second-order transition temperature (Tg) is to use from the TA DSC 2920 of Thermal Analyst Instrument with 20 ℃/minute determination of scan rate according to ASTM D3418.

[0141] glycol content of composition and cis/trans ratio are measured by proton NMR spectrum (NMR).All NMR data are recorded on the JEOL Eclipse Plus 600MHz nuclear magnetic resonance spectrometer, use chloroform-trifluoroacetic acid (70/30 volume/volume) for polymkeric substance, or, use 60/40 (wt/wt) phenol/tetrachloroethane for oligomeric sample, wherein add the deuterate chloroform with locking.For 2,2,4,4-tetramethyl--1, the ownership of 3-cyclobutanediol resonance peak be by with as 2,2,4 of model (model), 4-tetramethyl--1, the list of 3-cyclobutanediol-and two-benzoic ether relatively carry out.These model compounds are very near the resonant position in polymkeric substance and oligopolymer.

[0142] half-time of crystallization t1/2 is by changing and measure along with the time on the temperature control warm table via the transmittance of laser and photo-detector test sample.This detection can be by making polymkeric substance be exposed to temperature T max, being cooled to required temperature then and carrying out.Then sample is remained on required temperature by warm table, detect transmissivity simultaneously over time.During beginning, the sample range estimation is transparent, has high transmission rate, and becomes muddy along with the sample crystallization.Half-time of crystallization is the time that transmittance is in the half between initial transmittance and the final transmittance.Tmax is defined as the needed temperature in crystallization phases farmland (if the crystallization phases farmland exists) of fusing sample.Tmax in following examples represents sample heating with in the temperature that detects when regulating sample before half-time of crystallization.Tmax depends on composition, and normally different for various polyester.For example, PCT can be heated to than 290 ℃ of high temperature with fusion-crystallization phase farmland.

[0143] density is to use gradient density tower 23 ℃ of detections.

[0144] melt viscosity of report is to use Rheometrics Dynamic Analyzer (RDA II) to detect here.Melt viscosity detects under the temperature of being reported under the frequency of 1-400 radian per second as the function of shearing rate.Zero-shear viscosity (η ₀) be the melt viscosity under zero shearing rate, by estimating according to model extrapolation data known in the art.This step is carried out automatically by Rheometrics Dynamic Analyzer (RDA II) software.

[0145] with polymkeric substance under 80-100 ℃ temperature in vacuum drying oven dry 24 hours, and injection moulding on Boy 22S mould machine, obtains the flexural bars of 1/8 * 1/2 * 5 inches and 1/4 * 1/2 * 5 inches.These rods are cut into 2.5 inches length, and fall 1/2 inch width with 10 mil notch shocks according to ASTM D256.At 23 ℃ average cantilever-type impact strengths is to determine from the detected value of 5 samples.

[0146] in addition, detect 5 samples at various temperatures, thereby measure the brittle-ductile transition temperature with 5 ℃ increments.The brittle-ductile transition temperature is defined as 50% the sample fragility mode destructive temperature with ASTM D 256 explanations.

[0147] colour of report is to use Hunter Associatess Lab Inc.Reston here, and the Hunter Lab Ultrascan Spectra Colorimeter that Va. produces measures.The mean value of the value that the determining of colour detects to the pellet of polyester or by its injection moulding or the sheet material of extruding or other goods.They are by the L of CIE ^*a ^*b ^*Colour system is measured (International Commission onillumination), wherein L ^*The expression lightness dimension, a ^*Represent red/green coordinate, b ^*Expression Huang/blue coordinate.

[0148] in addition, the film of 10 mils uses the Carver press to carry out compression moulding at 240 ℃.

[0149] except as otherwise noted, the suitable/inverse proportion of the 1,4 cyclohexane dimethanol that uses in following examples is about 30/70, can be in 35/65 to 25/75 scope.Except as otherwise noted, in following examples, use 2,2,4,4-tetramethyl--1, the suitable/inverse proportion of 3-cyclobutanediol is about 50/50.

[0150] abbreviation below the use in work embodiment and accompanying drawing:

TPA	Terephthalic acid
TPA	Terephthalic acid	DMT	Dimethyl terephthalate (DMT)
TMCD	2,2,4,4-tetramethyl--1,3-cyclobutanediol	DMT	Dimethyl terephthalate (DMT)
TMCD	2,2,4,4-tetramethyl--1,3-cyclobutanediol	CHDM	1,4 cyclohexane dimethanol
IV	Logarithmic viscosity number	CHDM	1,4 cyclohexane dimethanol
IV	Logarithmic viscosity number	η ₀	Zero-shear viscosity
Tg	Second-order transition temperature	η ₀	Zero-shear viscosity
Tg	Second-order transition temperature	T _bd	The brittle-ductile transition temperature
T _max	Be used to detect the attemperation of half-time of crystallization	T _bd	The brittle-ductile transition temperature

Embodiment 1

[0151] the present embodiment explanation 2,2,4,4-tetramethyl--1, and the 3-cyclobutanediol is more effective than ethylene glycol or m-phthalic acid aspect the crystallization rate that reduces PCT.In addition, present embodiment explanation 2,2,4,4-tetramethyl--1, the 3-cyclobutanediol is to the benefit of second-order transition temperature and density.

[0152] the various copolyesters of preparation as described below.These copolyesters all use the 200ppm dibutyltin oxide as catalyzer, thereby the influence of the concentration during Study on Crystallization during with catalyst type and nucleation minimizes.Suitable/the inverse proportion of 1,4 cyclohexane dimethanol is 31/69, and 2,2,4,4-tetramethyl--1, the suitable/inverse proportion of 3-cyclobutanediol is listed in the table 1.

[0153] for the purpose of present embodiment, sample has enough similar logarithmic viscosity number, thereby can not become variable effectively in crystallization rate detects.

[0154] half-time of crystallization of melt, detect to be 140-200 ℃ temperature to be listed in the table 1 with 10 ℃ incremental detection.With the fastest half-time of crystallization of each sample as temperature variant minimum value of half-time of crystallization, usually in about 170-180 ℃ appearance.The fastest half-time of crystallization of sample, be plotted in Fig. 1 as the function of the mole % of the comonomer that is used for modification PCT.

[0155] data presentation 2,2,4,4-tetramethyl--1, and the 3-cyclobutanediol is more effective than ethylene glycol and m-phthalic acid at reduction crystallization rate (that is, increasing half-time of crystallization) aspect.In addition, 2,2,4,4-tetramethyl--1,3-cyclobutanediol can improve Tg and reduce density.

Table 1

Half-time of crystallization (minute)

Embodiment	Comonomer (mole %) ¹	IV (dl/g)	Density (g/ml)	T _g (℃)	T _max (℃)	140 ℃ (minute)	150 ℃ (minute)	160 ℃ (minute)	170 ℃ (minute)	180 ℃ (minute)	190 ℃ (minute)	200 ℃ (minute)
Embodiment	Comonomer (mole %) ¹	IV (dl/g)	Density (g/ml)	T _g (℃)	T _max (℃)	140 ℃ (minute)	150 ℃ (minute)	160 ℃ (minute)	170 ℃ (minute)	180 ℃ (minute)	190 ℃ (minute)	200 ℃ (minute)	1A	20.2％A ²	0.630	1.198	87.5	290	2.7	2.1	1.3	1.2	0.9	1.1	1.5
1B	19.8％B	0.713	1.219	87.7	290	2.3	2.5	1.7	1.4	1.3	1.4	1.7	1A	20.2％A ²	0.630	1.198	87.5	290	2.7	2.1	1.3	1.2	0.9	1.1	1.5
1B	19.8％B	0.713	1.219	87.7	290	2.3	2.5	1.7	1.4	1.3	1.4	1.7	1C	20.0％C	0.731	1.188	100.5	290	＞180	＞60	35.0	23.3	21.7	23.3	25.2
1D	40.2％A ²	0.674	1.198	81.2	260	18.7	20.0	21.3	25.0	34.0	59.9	96.1	1C	20.0％C	0.731	1.188	100.5	290	＞180	＞60	35.0	23.3	21.7	23.3	25.2
1D	40.2％A ²	0.674	1.198	81.2	260	18.7	20.0	21.3	25.0	34.0	59.9	96.1	1E	34.5％B	0.644	1.234	82.1	260	8.5	8.2	7.3	7.3	8.3	10.0	11.4
1F	40.1％C	0.653	1.172	122.0	260	＞10 days	＞5 days	＞5 days	19204	＞5 days	＞5 days	＞5 days	1E	34.5％B	0.644	1.234	82.1	260	8.5	8.2	7.3	7.3	8.3	10.0	11.4
1F	40.1％C	0.653	1.172	122.0	260	＞10 days	＞5 days	＞5 days	19204	＞5 days	＞5 days	＞5 days	1G	14.3％D	0.646 ³	1.188	103.0	290	55.0	28.8	11.6	6.8	4.8	5.0	5.5
1H	15.0％E	0.728 ⁴	1.189	99.0	290	25.4	17.1	8.1	5.9	4.3	2.7	5.1	1G	14.3％D	0.646 ³	1.188	103.0	290	55.0	28.8	11.6	6.8	4.8	5.0	5.5

The surplus of the diol component of polyester is a 1,4 cyclohexane dimethanol in 1 table 1; The dicarboxylic acid component's of polyester surplus is a dimethyl terephthalate (DMT) in the table 1; If do not describe dicarboxylic acid, then be the dimethyl terephthalate (DMT) of 100 moles of %.

The 1,4 cyclohexane dimethanol of 2 100 moles of %.

3 from the grinding polyester of embodiment 1G at 240 ℃ of compacting films.The film of gained has the logarithmic viscosity number of 0.575dL/g.

4 from the grinding polyester of embodiment 1H at 240 ℃ of compacting films.The film of gained has the logarithmic viscosity number of 0.652dL/g.

Wherein: A is a m-phthalic acid

B is an ethylene glycol

C is 2,2,4,4-tetramethyl--1,3-cyclobutanediol (suitable/anti-=about 50/50)

D is 2,2,4,4-tetramethyl--1,3-cyclobutanediol (suitable/anti-=about 98/2)

E is 2,2,4,4-tetramethyl--1,3-cyclobutanediol (suitable/anti-=about 5/95)

[0156] as table 1 and shown in Figure 1,2,2,4, for example ethylene glycol and m-phthalic acid are more effective than other comonomer increasing aspect half-time of crystallization (being half required time that polymkeric substance reaches its maximum degree of crystallinity) for 4-tetramethyl--1,3-cyclobutanediol.By reducing the crystallization rate (increase half-time of crystallization) of PCT, described here based on 2,2,4,4-tetramethyl--1, the amorphous goods of 3-cyclobutanediol modification PCT can prepare by means commonly known in the art.As shown in table 1, these materials demonstrate than higher second-order transition temperature of other modification PCT copolyesters and lower density.

[0157] preparation of the polyester shown in the table 1 is described below.

Embodiment 1A

[0158] present embodiment has been described target group becomes the preparation of the copolyesters of the 1,4 cyclohexane dimethanol residue of 80 moles of % dimethyl terephthalate (DMT) residues, 20 moles of % dimethyl isophthalate residues and 100 moles of % (suitable/anti-=28/72).

[0159] mixture of 56.63g dimethyl terephthalate (DMT), 55.2g 1,4 cyclohexane dimethanol, 14.16g dimethyl isophthalate and 0.0419g dibutyl tin oxide is put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Flask is put into the Wood metal bath that is heated to 210 ℃.In experimentation, stirring velocity is set at 200RPM.210 ℃ of heating 5 minutes, in 30 minutes, make temperature be elevated to 290 ℃ gradually then flask contents.Reaction mixture kept 60 minutes at 290 ℃, applies the pressure of vacuum in flask then gradually and reach 100mmHg in subsequently 5 minutes.In subsequently 5 minutes, further the pressure in the flask is reduced to 0.3mmHg.0.3mmHg pressure keep 90 minutes altogether to remove excessive unreacted glycol.The polymkeric substance of obtained to have high melt viscosity, range estimation is transparent and colourless, its second-order transition temperature is 87.5 ℃, logarithmic viscosity number is 0.63dL/g.This polymkeric substance of NMR analysis revealed comprises 1,4 cyclohexane dimethanol residue and 20.2 moles of % dimethyl isophthalate residues of 100 moles of %.

Embodiment 1B

[0160] present embodiment has been described target group becomes the preparation of the copolyesters of the 1,4 cyclohexane dimethanol residue of 100 moles of % dimethyl terephthalate (DMT) residues, 20 moles of % glycol residues and 80 moles of % (suitable/anti-=32/68).

[0161] mixture of 77.68g dimethyl terephthalate (DMT), 50.77g 1,4 cyclohexane dimethanol, 27.81g ethylene glycol and 0.0433g dibutyl tin oxide is put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Flask is put into the Wood metal bath that is heated to 200 ℃.In experimentation, stirring velocity is set at 200RPM.200 ℃ of heating 60 minutes, in 5 minutes, make temperature be elevated to 210 ℃ gradually then flask contents.Reaction mixture kept 120 minutes at 210 ℃, arrived until 280 ℃ at 30 minutes internal heating then.In case reach 280 ℃, in subsequently 5 minutes, apply the pressure of vacuum in flask gradually and reach 100mmHg.In subsequently 10 minutes, further the pressure in the flask is reduced to 0.3mmHg.0.3mmHg pressure keep 90 minutes altogether to remove excessive unreacted glycol.The polymkeric substance of obtained to have high melt viscosity, range estimation is transparent and colourless, its second-order transition temperature is 87.7 ℃, logarithmic viscosity number is 0.71dL/g.This polymkeric substance of NMR analysis revealed comprises 19.8 moles of % glycol residues.

Embodiment 1C

[0162] present embodiment has been described target group becomes 100 moles of % dimethyl terephthalate (DMT) residues, 20 moles of %2,2,4,4-tetramethyl--1, the preparation of the copolyesters of the 1,4 cyclohexane dimethanol residue of 3-cyclobutanediol residue and 80 moles of % (suitable/anti-=31/69).

[0163] with 77.68g dimethyl terephthalate (DMT), 48.46g 1,4-cyclohexanedimethanol, 17.86g 2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol and 0.046g dibutyl tin oxide are put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Prepare polyester according to the mode similar to embodiment 1A.The polymkeric substance of obtained to have high melt viscosity, range estimation is transparent and colourless, its second-order transition temperature is 100.5 ℃, logarithmic viscosity number is 0.73dL/g.This polymkeric substance of NMR analysis revealed comprises 2,2,4 of the 1,4 cyclohexane dimethanol residue of 80.5 moles of % and 19.5 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue.

Embodiment 1D

[0164] present embodiment has been described target group becomes the preparation of the copolyesters of the 1,4 cyclohexane dimethanol residue of 80 moles of % dimethyl terephthalate (DMT) residues, 40 moles of % dimethyl isophthalate residues and 100 moles of % (suitable/anti-=28/72).

[0165] mixture of 42.83g dimethyl terephthalate (DMT), 55.26g 1,4 cyclohexane dimethanol, 28.45g dimethyl isophthalate and 0.0419g dibutyl tin oxide is put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Flask is put into the Wood metal bath that is heated to 210 ℃.In experimentation, stirring velocity is set at 200RPM.210 ℃ of heating 5 minutes, in 30 minutes, make temperature be elevated to 290 ℃ gradually then flask contents.Reaction mixture kept 60 minutes at 290 ℃, applies the pressure of vacuum in flask then gradually and reach 100mmHg in subsequently 5 minutes.In subsequently 5 minutes, further the pressure in the flask is reduced to 0.3mmHg.0.3mmHg pressure keep 90 minutes altogether to remove excessive unreacted glycol.The polymkeric substance of obtained to have high melt viscosity, range estimation is transparent and colourless, its second-order transition temperature is 81.2 ℃, logarithmic viscosity number is 0.67dL/g.This polymkeric substance of NMR analysis revealed comprises 1,4 cyclohexane dimethanol residue and 40.2 moles of % dimethyl isophthalate residues of 100 moles of %.

Embodiment 1E

[0166] present embodiment has been described target group becomes the preparation of the copolyesters of the 1,4 cyclohexane dimethanol residue of 100 moles of % dimethyl terephthalate (DMT) residues, 40 moles of % glycol residues and 60 moles of % (suitable/anti-=31/69).

[0167] mixture of 81.3g dimethyl terephthalate (DMT), 42.85g 1,4 cyclohexane dimethanol, 34.44g ethylene glycol and 0.0419g dibutyl tin oxide is put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Flask is put into the Wood metal bath that is heated to 200 ℃.In experimentation, stirring velocity is set at 200RPM.200 ℃ of heating 60 minutes, in 5 minutes, make temperature be elevated to 210 ℃ gradually then flask contents.Reaction mixture kept 120 minutes at 210 ℃, arrived until 280 ℃ at 30 minutes internal heating then.In case reach 280 ℃, in subsequently 5 minutes, apply the pressure of vacuum in flask gradually and reach 100mmHg.In subsequently 10 minutes, further the pressure in the flask is reduced to 0.3mmHg.0.3mmHg pressure keep 90 minutes altogether to remove excessive unreacted glycol.The polymkeric substance of obtained to have high melt viscosity, range estimation is transparent and colourless, its second-order transition temperature is 82.1 ℃, logarithmic viscosity number is 0.64dL/g.This polymkeric substance of NMR analysis revealed comprises 34.5 moles of % glycol residues.

Embodiment 1F

[0168] present embodiment has been described target group becomes 100 moles of % dimethyl terephthalate (DMT) residues, 40 moles of %2,2,4,4-tetramethyl--1, the preparation of the copolyesters of the 1,4 cyclohexane dimethanol residue of 3-cyclobutanediol residue and 60 moles of % (suitable/anti-=31/69).

[0169] with 77.4g dimethyl terephthalate (DMT), 36.9g 1,4-cyclohexanedimethanol, 32.5g2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol and 0.046g dibutyl tin oxide are put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Flask is put into the Wood metal bath that is heated to 210 ℃.In experimentation, stirring velocity is set at 200RPM.210 ℃ of heating 3 minutes, in 30 minutes, make temperature be elevated to 260 ℃ gradually then flask contents.Reaction mixture kept 120 minutes at 260 ℃, arrived until 290 ℃ at 30 minutes internal heating then.In case reach 290 ℃, in subsequently 5 minutes, apply the pressure of vacuum in flask gradually and reach 100mmHg.In subsequently 5 minutes, further the pressure in the flask is reduced to 0.3mmHg.0.3mmHg pressure keep 90 minutes altogether to remove excessive unreacted glycol.The polymkeric substance of obtained to have high melt viscosity, range estimation is transparent and colourless, its second-order transition temperature is 122 ℃, logarithmic viscosity number is 0.65dL/g.This polymkeric substance of NMR analysis revealed comprises 2,2,4 of the 1,4 cyclohexane dimethanol residue of 59.9 moles of % and 40.1 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue.

Embodiment 1G

[0170] present embodiment has been described target group becomes 100 moles of % dimethyl terephthalate (DMT) residues, 20 moles of %2,2,4,4-tetramethyl--1, the preparation of the copolyesters of the 1,4 cyclohexane dimethanol residue (suitable/anti-=31/69) of 3-cyclobutanediol residue (suitable/anti-=98/2) and 80 moles of %.

[0171] with 77.68g dimethyl terephthalate (DMT), 48.46g 1,4-cyclohexanedimethanol, 20.77g 2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol and 0.046g dibutyl tin oxide are put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Flask is put into the Wood metal bath that is heated to 210 ℃.In experimentation, stirring velocity is set at 200RPM.210 ℃ of heating 3 minutes, in 30 minutes, make temperature be elevated to 260 ℃ gradually then flask contents.Reaction mixture kept 120 minutes at 260 ℃, arrived until 290 ℃ at 30 minutes internal heating then.In case reach 290 ℃, in subsequently 5 minutes, apply the pressure of vacuum in flask gradually and reach 100mmHg, and stirring velocity also is reduced to 100RPM.In subsequently 5 minutes, further the pressure in the flask is reduced to 0.3mmHg, and stirring velocity also is reduced to 50RPM.0.3mmHg pressure keep 60 minutes altogether to remove excessive unreacted glycol.The polymkeric substance of obtained to have high melt viscosity, range estimation is transparent and colourless, its second-order transition temperature is 103 ℃, logarithmic viscosity number is 0.65dL/g.This polymkeric substance of NMR analysis revealed comprises 2,2,4 of the 1,4 cyclohexane dimethanol residue of 85.7 moles of % and 14.3 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue.

Embodiment 1H

[0172] present embodiment has been described target group becomes 100 moles of % dimethyl terephthalate (DMT) residues, 20 moles of %2,2,4,4-tetramethyl--1, the preparation of the copolyesters of the 1,4 cyclohexane dimethanol residue (suitable/anti-=31/69) of 3-cyclobutanediol residue (suitable/anti-=5/95) and 80 moles of %.

[0173] with 77.68g dimethyl terephthalate (DMT), 48.46g 1,4-cyclohexanedimethanol, 20.77g 2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol and 0.046g dibutyl tin oxide are put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Flask is put into the Wood metal bath that is heated to 210 ℃.When the experiment beginning, stirring velocity is set at 200RPM.210 ℃ of heating 3 minutes, in 30 minutes, make temperature be elevated to 260 ℃ gradually then flask contents.Reaction mixture kept 120 minutes at 260 ℃, arrived until 290 ℃ at 30 minutes internal heating then.In case reach 290 ℃, in subsequently 5 minutes, apply the pressure of vacuum in flask gradually and reach 100mmHg, and stirring velocity also is reduced to 100RPM.In subsequently 5 minutes, further the pressure in the flask is reduced to the setting point of 0.3mmHg, and stirring velocity also is reduced to 50RPM.This pressure keeps 60 minutes altogether to remove excessive unreacted glycol.It should be noted that vacuum system fails to reach above-mentioned setting point, but produce enough vacuum with obtain to have high melt viscosity, the transparent and colourless polymkeric substance of range estimation, its second-order transition temperature is 99 ℃, logarithmic viscosity number is 0.73dL/g.This polymkeric substance of NMR analysis revealed comprises 2,2,4 of the 1,4 cyclohexane dimethanol residue of 85 moles of % and 15 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue.

Embodiment 2

[0174] the present embodiment explanation 2,2,4, and 4-tetramethyl--1,3-cyclobutanediol can improve the toughness of PCT type copolyesters (polyester that contains terephthalic acid and 1,4 cyclohexane dimethanol).

[0175] preparation as described below is based on 2,2,4,4-tetramethyl--1, the copolyesters of 3-cyclobutanediol.For all samples, the suitable/inverse proportion of 1,4 cyclohexane dimethanol is about 31/69.Copolyesters based on ethylene glycol and 1,4 cyclohexane dimethanol is the polyester that is purchased.The copolyesters of embodiment 2A (EastarPCTG 5445) obtains from Eastman Chemical Co..The copolyesters of embodiment 2B obtains with trade(brand)name Spectar from Eastman Chemical Co..Embodiment 2C and 2D prepare according to the described operation of embodiment 1A with pilot scale (each 15-lb batch naturally), and have logarithmic viscosity number shown in the table 2 and second-order transition temperature.Embodiment 2C uses the target tin content (dibutyl tin oxide) of 300ppm to prepare.Final product contains the tin of 295ppm.The colour of the polyester of embodiment 2C is L ^*=77.11, a ^*=-1.50, b ^*=5.79.Embodiment 2D uses the target tin content (dibutyl tin oxide) of 300ppm to prepare.Final product contains the tin of 307ppm.The colour of the polyester of embodiment 2D is L ^*=66.72, a ^*=-1.22, b ^*=16.28.

[0176] material is injection molded into rod, beats breach subsequently and be used for socle girder (Izod) detection.Notched izod intensity obtains as the function of temperature, also is listed in the table 2.

[0177] for given sample, cantilever-type impact strength is the main transformation of experience in short temperature range.For example, based on the cantilever-type impact strength of the copolyesters of 38 moles of % ethylene glycol in this transformation of 15-20 ℃ of experience.This transition temperature is relevant with the variation of failure mode: fragility at a lower temperature/low-yield destruction and the toughness/high-energy destruction under comparatively high temps.Transition temperature is expressed as the brittle-ductile transition temperature T _Bd, be to weigh the flexible means.T _BdBe listed in the table 2, and the mole % to comonomer maps in Fig. 2.

[0178] data show and the T that causes PCT _BdThe ethylene glycol that improves is compared, and adds 2,2,4 in PCT, 4-tetramethyl--1, and the 3-cyclobutanediol can reduce T _BdWith improvement toughness.

Table 2

Notched izod energy (ft-lb/in)

Embodiment	Comonomer (mole %) ¹	I (dl/g)	T _g(℃)	T _bd(℃)	At-20 ℃	At-15 ℃	At-10 ℃	At-5 ℃	At 0 ℃	At 5 ℃	At 10 ℃	At 15 ℃	At 20 ℃	At 25 ℃	At 30 ℃
Embodiment	Comonomer (mole %) ¹	I (dl/g)	T _g(℃)	T _bd(℃)	At-20 ℃	At-15 ℃	At-10 ℃	At-5 ℃	At 0 ℃	At 5 ℃	At 10 ℃	At 15 ℃	At 20 ℃	At 25 ℃	At 30 ℃	2A	38.0％B	0.68	86	18	NA	NA	NA	1.5	NA	NA	1.5	1.5	32	32	NA
2B	69.0％B	0.69	82	26	NA	NA	NA	NA	NA	NA	2.1	NA	2.4	13.7	28.7	2A	38.0％B	0.68	86	18	NA	NA	NA	1.5	NA	NA	1.5	1.5	32	32	NA
2B	69.0％B	0.69	82	26	NA	NA	NA	NA	NA	NA	2.1	NA	2.4	13.7	28.7	2C	22.0％C	0.66	106	-5	1.5	NA	12	23	23	NA	23	NA	NA	NA	NA
2D	42.8％C	0.60	133	-12	2.5	2.5	11	NA	14	NA	NA	NA	NA	NA	NA	2C	22.0％C	0.66	106	-5	1.5	NA	12	23	23	NA	23	NA	NA	NA	NA

1 the surplus of diol component of polyester in table is a 1,4 cyclohexane dimethanol.All polymkeric substance are from the dimethyl terephthalate (DMT) preparation of 100 moles of %.

NA=does not obtain

Wherein B is an ethylene glycol

C is 2,2,4,4-tetramethyl--1,3-cyclobutanediol (suitable/anti-=50/50)

Embodiment 3

[0179] the present embodiment explanation 2,2,4, and 4-tetramethyl--1,3-cyclobutanediol can improve the toughness of PCT type copolyesters (polyester that contains terephthalic acid and 1,4 cyclohexane dimethanol).Zhi Bei polyester contains greater than 25 to less than 2,2,4 of 40 moles of % in the present embodiment, 4-tetramethyl--1,3-cyclobutanediol residue.

[0180] preparation as described below is based on dimethyl terephthalate (DMT), 2,2,4,4-tetramethyl--1, and the copolyesters of 3-cyclobutanediol and 1,4 cyclohexane dimethanol (suitable/anti-=31/69), it has composition shown in the following table and performance.The surplus of the diol component of the polyester in following table is 1,4 cyclohexane dimethanol (suitable/anti-=31/69) until 100 moles of %.

[0181] material is injection molded into the thick rod of 3.2mm and 6.4mm, beats breach subsequently and be used for the socle girder detection.Notched izod intensity is listed in the following table 23 ℃ of acquisitions.Detect density, Tg and the half-time of crystallization of molded bar.Melt viscosity at 290 ℃ of detection pellets.

Table 3

The various performances that are used for specific polyester of the present invention gather

Embodiment	TMCD mole %	Cis TMCD mole %	The IV of pellet (dl/g)	The IV of molded bar (dl/g)	3.2mm thick rod is in the scarce formula shock strength (J/m) of 23 ℃ of mouth socle girders	6.4mm the outstanding hit intensity (J/m) of breach that thick rod dashes at 23 ℃ of arm beam types	Proportion (g/mL)	Tg (℃)	170 ℃ melt half-time of crystallization (minute)	290 ℃ of melt viscosities (pool) under 1 radian per second
Embodiment	TMCD mole %	Cis TMCD mole %	The IV of pellet (dl/g)	The IV of molded bar (dl/g)			Proportion (g/mL)	Tg (℃)	170 ℃ melt half-time of crystallization (minute)	290 ℃ of melt viscosities (pool) under 1 radian per second	A	27	47.8	0.714	0.678	877	878	1.178	113	280	8312
B	31	NA	0.667	0.641	807	789	1.174	116	600	6592	A	27	47.8	0.714	0.678	877	878	1.178	113	280	8312

NA=does not obtain

Embodiment 3A

[0182] with 1 of the dimethyl terephthalate (DMT) of 21.24lb (49.71g/mol), 11.82lb (37.28g/mol), 2 of 4-cyclohexanedimethanol and 6.90lb (21.77g/mol), 2,4, the reaction in the presence of catalyzer three (2 ethyl hexanoic acid) butyl tin of 200ppm together of 4-tetramethyl--1,3-cyclobutanediol.This is reflected under the nitrogen purging and carries out in 18 gallons the stainless steel pressure container that is equipped with condensation tower, vacuum system and HELICONE type agitator.Under the stirring of 25RPM, the temperature of reaction mixture is elevated to 250 ℃, and pressure is elevated to 20psig.Reaction mixture kept 2 hours under 250 ℃ and 20psig pressure.With 3psig/ minute speed pressure is reduced to 0psig then.The temperature of reaction mixture is elevated to 270 ℃ then, and pressure is reduced to 90mmHg.Keep after 1 hour agitator speed being reduced to 15RPM under 270 ℃ and 90mmHg, the temperature of reaction mixture is elevated to 290 ℃, and pressure is reduced to less than 1mmHg.Reaction mixture 290 ℃ and less than 1mmHg pressure under keep stretching and no longer increase (50 minutes) up to energy to agitator.Use nitrogen that the pressure of pressurized vessel is elevated to 1 normal atmosphere then.The fused polymkeric substance is extruded from pressurized vessel then.The refrigerative extruded polymer is ground to passes through the 6mm sieve.The logarithmic viscosity number of polymkeric substance is 0.714dL/g, and Tg is 113 ℃.This polymkeric substance of NMR analysis revealed comprises 2,2,4 of the 1,4 cyclohexane dimethanol residue of 73.3 moles of % and 26.7 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue.

Embodiment 3B

[0183] polyester of embodiment 3B is according to preparing to the described similar operation of embodiment 3A.The composition and the performance of these polyester are listed in the table 3.

Embodiment 4

[0184] the present embodiment explanation 2,2,4, and 4-tetramethyl--1,3-cyclobutanediol can improve the toughness of PCT type copolyesters (polyester that contains terephthalic acid and 1,4 cyclohexane dimethanol).Zhi Bei polyester contains 40 moles of % or more 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue in the present embodiment.

[0185] preparation as described below is based on dimethyl terephthalate (DMT), 2,2,4,4-tetramethyl--1, and the copolyesters of 3-cyclobutanediol and 1,4 cyclohexane dimethanol (suitable/anti-=31/69), it has composition shown in the table 4 and performance.The surplus to 100 of the diol component of the polyester in table 4 a mole % is 1,4 cyclohexane dimethanol (suitable/anti-=31/69).

[0186] material is injection molded into the thick rod of 3.2mm and 6.4mm, beats breach subsequently and be used for the socle girder detection.Notched izod intensity is listed in the table 4 23 ℃ of acquisitions.Detect density, Tg and the half-time of crystallization of molded bar.Melt viscosity at 290 ℃ of detection pellets.

Table 4

Embodiment	TMCD mole %	Cis TMCD mole %	The IV of pellet (dl/g)	The IV of molded bar (dl/g)	3.2mm thick rod is 23 ℃ notched izod intensity (J/m)	6.4mm thick rod is 23 ℃ notched izod intensity (J/m)	Proportion (g/mL)	Tg (℃)	170 ℃ melt half-time of crystallization (minute)	290 ℃ of melt viscosities (pool) under 1 radian per second
Embodiment	TMCD mole %	Cis TMCD mole %	The IV of pellet (dl/g)	The IV of molded bar (dl/g)	3.2mm thick rod is 23 ℃ notched izod intensity (J/m)	6.4mm thick rod is 23 ℃ notched izod intensity (J/m)	Proportion (g/mL)	Tg (℃)	170 ℃ melt half-time of crystallization (minute)	290 ℃ of melt viscosities (pool) under 1 radian per second	A	44	46.2	0.657	0.626	727	734	1.172	119	NA	9751
B	45	NA	0.626	0.580	748	237	1.167	123	NA	8051	A	44	46.2	0.657	0.626	727	734	1.172	119	NA	9751
B	45	NA	0.626	0.580	748	237	1.167	123	NA	8051	C	45	NA	0.582	0.550	671	262	1.167	125	19782	5835
D	45	NA	0.541	0.493	424	175	1.167	123	NA	3275	C	45	NA	0.582	0.550	671	262	1.167	125	19782	5835
D	45	NA	0.541	0.493	424	175	1.167	123	NA	3275	E	59	46.6	0.604	0.576	456	311	1.156	139	NA	16537
F	45	47.2	0.475	0.450	128	30	1.169	121	NA	1614	E	59	46.6	0.604	0.576	456	311	1.156	139	NA	16537

NA=does not obtain

Embodiment 4A

[0187] with 1 of the dimethyl terephthalate (DMT) of 21.24lb (49.71g/mol), 8.84lb (27.88g/mol), 2 of 4-cyclohexanedimethanol and 10.08lb (31.77g/mol), 2,4, the reaction in the presence of catalyzer three (2 ethyl hexanoic acid) butyl tin of 200ppm together of 4-tetramethyl--1,3-cyclobutanediol.This is reflected under the nitrogen purging and carries out in 18 gallons the stainless steel pressure container that is equipped with condensation tower, vacuum system and HELICONE type agitator.Under the stirring of 25RPM, the temperature of reaction mixture is elevated to 250 ℃, and pressure is elevated to 20psig.Reaction mixture kept 2 hours under 250 ℃ and 20psig pressure.With 3psig/ minute speed pressure is reduced to 0psig then.Agitator speed is reduced to 15RPM, and the temperature of reaction mixture is elevated to 290 ℃ then, and pressure is reduced to 2mmHg.Reaction mixture keeps stretching up to the energy to agitator under 290 ℃ and 2mmHg pressure no longer increases (80 minutes).Use nitrogen that the pressure of pressurized vessel is elevated to 1 normal atmosphere then.The fused polymkeric substance is extruded from pressurized vessel then.The refrigerative extruded polymer is ground to passes through the 6mm sieve.The logarithmic viscosity number of polymkeric substance is 0.657dL/g, and Tg is 119 ℃.This polymkeric substance of NMR analysis revealed comprises 2,2,4 of the 1,4 cyclohexane dimethanol residue of 56.3 moles of % and 43.7 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue.The colour of polymkeric substance is: L ^*=75.04, a ^*=-1.82, b ^*=6.72.

Embodiment 4B to 4D

[0188] polyester of embodiment 4B to 4D is according to preparing to the described similar operation of embodiment 4A.The composition of these polyester and performance are listed in the following table 4.

Embodiment 4E

[0189] with 1 of the dimethyl terephthalate (DMT) of 21.24lb (49.71g/mol), 6.43lb (20.28g/mol), 2 of 4-cyclohexanedimethanol and 12.49lb (39.37g/mol), 2,4, the reaction in the presence of catalyzer three (2 ethyl hexanoic acid) butyl tin of 200ppm together of 4-tetramethyl--1,3-cyclobutanediol.This is reflected under the nitrogen purging and carries out in 18 gallons the stainless steel pressure container that is equipped with condensation tower, vacuum system and HELICONE type agitator.Under the stirring of 25RPM, the temperature of reaction mixture is elevated to 250 ℃, and pressure is elevated to 20psig.Reaction mixture kept 2 hours under 250 ℃ and 20psig pressure.With 3psig/ minute speed pressure is reduced to 0psig then.Then agitator speed is reduced to 15RPM, the temperature of reaction mixture is elevated to 290 ℃ then, and pressure is reduced to 2mmHg.Reaction mixture 290 ℃ and＜pressure of 1mmHg keeps down up to the no longer increase (50 minutes) that stretches of the energy to agitator.Use nitrogen that the pressure of pressurized vessel is elevated to 1 normal atmosphere then.The fused polymkeric substance is extruded from pressurized vessel then.The refrigerative extruded polymer is ground to passes through the 6mm sieve.The logarithmic viscosity number of polymkeric substance is 0.604dL/g, and Tg is 139 ℃.This polymkeric substance of NMR analysis revealed comprises 2,2,4 of the 1,4 cyclohexane dimethanol residue of 40.8 moles of % and 59.2 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue.The colour of polymkeric substance is: L ^*=80.48, a ^*=-1.30, b ^*=6.82.

Embodiment 4F

[0190] with 1 of the dimethyl terephthalate (DMT) of 21.24lb (49.71g/mol), 8.84lb (27.88g/mol), 2 of 4-cyclohexanedimethanol and 10.08lb (31.77g/mol), 2,4, the reaction in the presence of catalyzer three (2 ethyl hexanoic acid) butyl tin of 200ppm together of 4-tetramethyl--1,3-cyclobutanediol.This is reflected under the nitrogen purging and carries out in 18 gallons the stainless steel pressure container that is equipped with condensation tower, vacuum system and HELICONE type agitator.Under the stirring of 25RPM, the temperature of reaction mixture is elevated to 250 ℃, and pressure is elevated to 20psig.Reaction mixture kept 2 hours under 250 ℃ and 20psig pressure.With 3psig/ minute speed pressure is reduced to 0psig then.The temperature of reaction mixture is elevated to 270 ℃ then, and pressure is reduced to 90mmHg.After 270 ℃ and 90mmHg keep 1 hour, agitator speed is reduced to 15RPM, pressure is reduced to 4mmHg.When reaction mixture reaches 290 ℃ and 4mmHg, use nitrogen that the pressure of pressurized vessel is elevated to 1 normal atmosphere immediately.The fused polymkeric substance is extruded from pressurized vessel then.The refrigerative extruded polymer is ground to passes through the 6mm sieve.The logarithmic viscosity number of polymkeric substance is 0.475dL/g, and Tg is 121 ℃.This polymkeric substance of NMR analysis revealed comprises 2,2,4 of the 1,4 cyclohexane dimethanol residue of 55.5 moles of % and 44.5 moles of %, 4-tetramethyl--1, and 3-cyclobutanediol residue is formed.The colour of polymkeric substance is: L ^*=85.63, a ^*=-0.88, b ^*=4.34.

Embodiment 5-Comparative Examples

[0191] data rows of the contrast material of present embodiment is in table 5.PC is the Makrolon 2608 from Bayer, and it is the diphenyl carbonate residue of 100 moles of % dihydroxyphenyl propane residues and 100 moles of % that its nominal is formed.The nominal melt flow of Makrolon 2608 is 20g/10 minute, uses the 1.2kg weight measurement down at 300 ℃.PET is the Eastar 9921 from Eastman Chemical Company, and it is the cyclohexanedimethanol (CHDM) of 100 moles of % terephthalic acids, 3.5 moles of % and the ethylene glycol of 96.5 moles of % that its nominal is formed.PETG is the Eastar 6763 from Eastman ChemicalCompany, and it is the cyclohexanedimethanol (CHDM) of 100 moles of % terephthalic acids, 31 moles of % and the ethylene glycol of 69 moles of % that its nominal is formed.PCTG is the Eastar DN001 from EastmanChemical Company, and it is the cyclohexanedimethanol (CHDM) of 100 moles of % terephthalic acids, 62 moles of % and the ethylene glycol of 38 moles of % that its nominal is formed.PCTA is the Eastar AN001 from Eastman Chemical Company, and it is the m-phthalic acid of 65 moles of % terephthalic acids, 35 moles of % and the cyclohexanedimethanol (CHDM) of 100 moles of % that its nominal is formed.Polysulfones is the Udel 1700 from S01vay, 4 of the dihydroxyphenyl propane residue that its nominal composition is 100 moles of % and 100 moles of %, 4-dichloro semi-annular jade pendant acyl group sulfone residue.The nominal melt flow of Udel1700 is 6.5g/10 minute, uses the 2.16kg weight measurement down at 343 ℃.SAN is the Lustran 31 from Lanxess, and it is the vinylbenzene of 76 moles of % and the vinyl cyanide of 24 moles of % that its nominal is formed.The nominal melt flow of Lustran 31 is 7.5g/10 minute, uses the 3.8kg weight measurement down at 230 ℃.Compare with all other resins, embodiments of the invention show the toughness improved the thick rod of 6.4mm.

Table 5

The various performances of particular business polymkeric substance gather

Embodiment	The polymkeric substance title	The IV of pellet (dl/g)	The IV of molded bar (dl/g)	3.2mm thick rod is 23 ℃ notched izod intensity (J/m)	6.4m thick rod is 23 ℃ notched izod intensity (J/m)	Proportion (g/mL)	Tg (℃)	Melt half-time of crystallization (min)
Embodiment	The polymkeric substance title	The IV of pellet (dl/g)	The IV of molded bar (dl/g)	3.2mm thick rod is 23 ℃ notched izod intensity (J/m)	6.4m thick rod is 23 ℃ notched izod intensity (J/m)	Proportion (g/mL)	Tg (℃)	Melt half-time of crystallization (min)	A	PC	12 MFR	NA	929	108	1.20	146	NA
B	PCTG	0.73	0.696	NB	70	1.23	87	30 in 170 ℃	A	PC	12 MFR	NA	929	108	1.20	146	NA
B	PCTG	0.73	0.696	NB	70	1.23	87	30 in 170 ℃	C	PCTA	0.72	0.702	98	59	1.20	87	15 in 150 ℃
D	PETG	0.75	0.692	83	59	1.27	80	2500 in 130 ℃	C	PCTA	0.72	0.702	98	59	1.20	87	15 in 150 ℃
D	PETG	0.75	0.692	83	59	1.27	80	2500 in 130 ℃	E	PET	0.76	0.726	45	48	1.33	78	1.5 in 170 ℃
F	SAN	7.5MFR	NA	21	NA	1.07	～110	NA	E	PET	0.76	0.726	45	48	1.33	78	1.5 in 170 ℃
F	SAN	7.5MFR	NA	21	NA	1.07	～110	NA	G	PSU	6.5MFR	NA	69	NA	1.24	～190	NA

NA=does not obtain

Embodiment 6

[0192] the present embodiment explanation is used to prepare 2,2,4 of polyester of the present invention, 4-tetramethyl--1, and the consumption of 3-cyclobutanediol is to the influence of the second-order transition temperature of polyester.

Embodiment 6A

[0193] polyester of present embodiment is by carrying out transesterify and polycondensation prepares in the stage of separating.The transesterify experiment is being carried out in heating type (CTR) reactor continuously.CTR is the glass reactor of 3000ml, is equipped with single shaft to drive paddle agitator, is covered by the electrically heated overcoat, and is equipped with the filling reflux condensation mode post of heating.In reactor, pack into 777g (4 moles) dimethyl terephthalate (DMT), 230g (1.6 moles) 2,2,4,4-tetramethyl--1, the cyclohexanedimethanol of 3-cyclobutanediol, 460.8g (3.2 moles) and three-2 ethyl hexanoic acid butyl tin of 1.12g (make the tin metal of 200ppm is arranged in final polymkeric substance).With the heating jacket manual regulation to 100% output rating.The collection of setting point and data is promoted by the Camile process control system.In case the reactant fusion just begins to stir and slowly be increased to 250rpm.The temperature of reactor progressively raise along with working time.The weight of the methyl alcohol of collecting is equaled a record by the sky.When the effusion of methyl alcohol stops or stopped reaction during predetermined low temperature level at 260 ℃.Under nitrogen purging, take out oligopolymer, and cool to room temperature.Use the liquid nitrogen freezing oligopolymer, and be broken into the fritter that is small enough to weighing adding 500ml round-bottomed flask.

[0194] in polycondensation, in the about 150g oligopolymer adding 500ml round-bottomed flask with as above preparation.This flask is equipped with stainless steel agitator and polymkeric substance head.Glassware is set on the polymeric device of half mole number, and beginning Camile order.In case the oligopolymer fusion just is placed on agitator the full up position in the round-bottomed flask.Temperature/pressure/the stir speed (S.S.) by the Camile software control of these embodiment is listed in the following table, in proper order except as otherwise noted.

[0195] Camile of embodiment 6A order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	3	265	90	50	3	30	265	760	50
4	3	265	90	50	5	110	290	90	50
6	5	290	3	25	5	110	290	90	50
6	5	290	3	25	7	110	290	3	25

[0196] polymkeric substance of gained takes out from flask, uses the hydraulic cutter cutting, and grinds to form the screen size of 6mm.The logarithmic viscosity number of every kind of polymer samples that ground in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration, levels of catalysts (Sn) detects by x-ray fluorescence spectrum, colour (L ^*, a ^*, b ^*) detect by transmitted spectrum.The composition of polymkeric substance passes through ¹H NMR obtains.Use the thermostability and the melt viscosity of RheometricsMechanical Spectrometer (RMS-800) test sample.

[0197] following table shows the experimental data of present embodiment polyester.Fig. 3 also shows the dependency of Tg to composition and logarithmic viscosity number.These data show for the constant logarithmic viscosity number, improve 2,2,4,4-tetramethyl--1, and the consumption of 3-cyclobutanediol can improve second-order transition temperature in almost linear mode

Table 6

Second-order transition temperature, logarithmic viscosity number and composition

Embodiment	Mole % TMCD	% cis TMCD	IV (dL/g)	T _g (℃)	η at 260 ℃ _o(pool)	η at 275 ℃ _o(pool)	η at 290 ℃ _o(pool)
Embodiment	Mole % TMCD	% cis TMCD	IV (dL/g)	T _g (℃)	η at 260 ℃ _o(pool)	η at 275 ℃ _o(pool)	η at 290 ℃ _o(pool)	A	22.7	53	0.69	112	NA	NA	NA

NA=does not obtain

Embodiment 7

[0198] the present embodiment explanation is used to prepare 2,2,4 of polyester of the present invention, 4-tetramethyl--1, and the consumption of 3-cyclobutanediol is to the influence of the second-order transition temperature of polyester.Zhi Bei polyester contains greater than 25 to less than 2,2,4 of 40 moles of % in the present embodiment, 4-tetramethyl--1,3-cyclobutanediol residue.

[0199] with dimethyl terephthalate (DMT), 1,4 cyclohexane dimethanol and 2,2,4,4-tetramethyl--1, the 3-cyclobutanediol adds in single neck round-bottomed flask of 500ml.To 2,2,4,4-tetramethyl--1, the NMR of 3-cyclobutanediol raw material are analyzed and are shown that suitable/inverse proportion is 53/47.The polyester of present embodiment prepares with glycol/sour ratio of 1.2/1, and is wherein all excessive in 2,2,4,4-tetramethyl--1,3-cyclobutanediol.The dibutyl tin oxide that adds capacity is to obtain the tin of 300ppm in final polymkeric substance.Flask is under the 0.2 SCFC nitrogen purging with the low ability of vacuum drop.Flask is immersed in the Belmont metal bath at 200 ℃, and after the reactant fusion, stir in 200RPM.After about 2.5 hours, temperature is elevated to 210 ℃, and these conditions were kept 2 hours again.Temperature is elevated to 285 ℃ (in about 25 minutes), and in 5 minutes, pressure is reduced to 0.3mmHg.Along with viscosity increases and reduce stirring velocity, use the minimum stirring of 15RPM.Change the total polymerization time to reach the target logarithmic viscosity number.After finishing polymerization, the Belmont metal bath of loweing, and make polymkeric substance be cooled to be lower than its second-order transition temperature.After about 30 minutes, flask is immersed Belmont metal bath (at this 30 minutes waiting periods, temperature has been elevated to 295 ℃) once more, and heated polymerizable thing material is up to taking out from glass flask.Stirring polymer material under medium level cools off up to polymkeric substance.Take out polymkeric substance from flask, and be ground to and pass through the 3mm sieve.Change this operation to be prepared as follows the described copolyesters that 32 moles of % targets are formed that has.

[0200] logarithmic viscosity number is as detection as described in above-mentioned " detection method ".The composition of polyester is by being explained in above-mentioned detection method part ¹H NMR measures.Second-order transition temperature uses after quenching 20 ℃/minute speed control second-heating to detect by DSC.

[0201] following table shows the experimental data of present embodiment polyester.Fig. 3 also shows the dependency of Tg to composition and logarithmic viscosity number.These data show for the constant logarithmic viscosity number, improve 2,2,4,4-tetramethyl--1, and the consumption of 3-cyclobutanediol can improve second-order transition temperature in almost linear mode.

Table 7

The relation of second-order transition temperature and logarithmic viscosity number and composition

Embodiment	Mole %TMCD	% cis TMCD	IV(dL/g)	T _g(℃)	η at 260 ℃ _o(pool)	η at 275 ℃ _o(pool)	η at 290 ℃ _o(pool)
Embodiment	Mole %TMCD	% cis TMCD	IV(dL/g)	T _g(℃)	η at 260 ℃ _o(pool)	η at 275 ℃ _o(pool)	η at 290 ℃ _o(pool)	A	31.6	51.5	0.55	112	5195	2899	2088
B	31.5	50.8	0.62	112	8192	4133	2258	A	31.6	51.5	0.55	112	5195	2899	2088
B	31.5	50.8	0.62	112	8192	4133	2258	C	30.7	50.7	0.54	111	4345	2434	1154
D	30.3	51.2	0.61	111	7929	4383	2261	C	30.7	50.7	0.54	111	4345	2434	1154
D	30.3	51.2	0.61	111	7929	4383	2261	E	29.0	51.5	0.67	112	16322	8787	4355

NA=does not obtain

Embodiment 8

[0202] the present embodiment explanation is used to prepare 2,2,4 of polyester of the present invention, 4-tetramethyl--1, and the consumption of 3-cyclobutanediol is to the influence of the second-order transition temperature of polyester.Zhi Bei polyester contains 40 moles of % or more 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue in the present embodiment.

Embodiment A-AC

[0203] these polyester are by carrying out transesterify and polycondensation prepares in the stage of separating.The transesterify experiment is being carried out in heating type (CTR) reactor continuously.CTR is the glass reactor of 3000ml, is equipped with single shaft to drive paddle agitator, is covered by the electrically heated overcoat, and is equipped with the filling reflux condensation mode post of heating.In reactor, pack into 777g dimethyl terephthalate (DMT), 375g 2,2,4,4-tetramethyl--1, three-2 ethyl hexanoic acid butyl tin of the cyclohexanedimethanol of 3-cyclobutanediol, 317g and 1.12g (make the tin metal of 200ppm is arranged in final polymkeric substance).With the heating jacket manual regulation to 100% output rating.The collection of setting point and data is promoted by the Camile process control system.In case the reactant fusion just begins to stir and slowly be increased to 250rpm.The temperature of reactor progressively raise along with working time.The weight of the methyl alcohol of collecting is equaled a record by the sky.When the effusion of methyl alcohol stops or stopped reaction during predetermined low temperature level at 260 ℃.Under nitrogen purging, take out oligopolymer, and cool to room temperature.Use the liquid nitrogen freezing oligopolymer, and be broken into the fritter that is small enough to weighing adding 500ml round-bottomed flask.

[0204] in polycondensation, in the 150g oligopolymer adding 500ml round-bottomed flask with as above preparation.This flask is equipped with stainless steel agitator and polymkeric substance head.Glassware is set on the polymeric device of half mole number, and beginning Camile order.In case the oligopolymer fusion just is placed on agitator the full up position in the round-bottomed flask.Temperature/pressure/the stir speed (S.S.) by the Camile software control of these embodiment is listed in the following table, in proper order except as otherwise noted.

The Camile order of polycondensation

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	3	265	90	50	3	30	265	760	50
4	3	265	90	50	5	110	290	90	50
6	5	290	6	25	5	110	290	90	50
6	5	290	6	25	7	110	290	6	25

[0205] Camile of embodiment A, C, R, Y, AB, AC order

[0206] for Embodiment B, D, F, use with last epiphase with order, the time that different is in the stage 7 is 80 minutes.For embodiment G and J, use with last epiphase with order, the time that different is in the stage 7 is 50 minutes.For embodiment L, use with last epiphase with order, the time that different is in the stage 7 is 140 minutes.

[0207] Camile of embodiment E order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	3	265	90	50	3	30	265	760	50
4	3	265	90	50	5	110	300	90	50
6	5	300	7	25	5	110	300	90	50
6	5	300	7	25	7	110	300	7	25

[0208] for example I, use with last epiphase with order, the vacuum that different is in stage 6 and 7 is 8 holders.For embodiment O, use with last epiphase with order, the vacuum that different is in stage 6 and 7 is 6 holders.For embodiment P, use with last epiphase with order, the vacuum that different is in stage 6 and 7 is 4 holders.For embodiment Q, use with last epiphase with order, the vacuum that different is in stage 6 and 7 is 5 holders.

[0209] Camile of embodiment H order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	3	265	90	50	3	30	265	760	50
4	3	265	90	50	5	110	280	90	50
6	5	280	5	25	5	110	280	90	50
6	5	280	5	25	7	110	280	5	25

[0210] for embodiment U and AA, use with last epiphase with order, the vacuum that different is in stage 6 and 7 is 6 holders.For EXAMPLE V and X, use with last epiphase with order, the vacuum that different is in stage 6 and 7 is that 6 holders and stir speed (S.S.) are 15rpm.For embodiment Z, use with last epiphase with order, the stir speed (S.S.) that different is in stage 6 and 7 is 15rpm.

[0211] Camile of embodiment K order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	3	265	90	50	3	30	265	760	50
4	3	265	90	50	5	110	300	90	50
6	5	300	6	15	5	110	300	90	50
6	5	300	6	15	7	110	300	6	15

[0212] for embodiment M, use with last epiphase with order, the vacuum that different is in stage 6 and 7 is 8 holders.For embodiment N, use with last epiphase with order, the vacuum that different is in stage 6 and 7 is 7 holders.

[0213] Camile of embodiment S and T order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	5	290	6	25	3	30	265	760	50
4	5	290	6	25	5	110	290	6	25

[0214] polymkeric substance of gained takes out from flask, uses the hydraulic cutter cutting, and grinds to form the screen size of 6mm.The logarithmic viscosity number of every kind of polymer samples that ground in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration, levels of catalysts (Sn) detects by x-ray fluorescence spectrum, colour (L ^*, a ^*, b ^*) detect by transmitted spectrum.The composition of polymkeric substance obtains by 1H NMR.Use the thermostability and the melt viscosity of RheometricsMechanical Spectrometer (RMS-800) test sample.

Embodiment A D-AK and AS

[0215] as above for the polyester of described these embodiment of preparation of embodiment A-Z, the target tin content of different the is final polymkeric substance among embodiment A D-AK and the AS is 150ppm.Following table has illustrated the order of passing through the temperature/pressure/stir speed (S.S.) of Camile software control among these embodiment.

[0216] Camile of embodiment A D, AF and AH order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	3	265	400	50	3	30	265	760	50
4	3	265	400	50	5	110	290	400	50
6	5	290	8	50	5	110	290	400	50
6	5	290	8	50	7	110	295	8	50

[0217] for embodiment A D, agitator is adjusted to 25rpm, and in the stage 7, stopped 95 minutes.

[0218] Camile of embodiment A E order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rPm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rPm)	1	10	245	760	0
2	5	245	760	50	1	10	245	760	0
2	5	245	760	50	3	30	283	760	50
4	3	283	175	50	3	30	283	760	50
4	3	283	175	50	5	5	283	5	50
6	5	283	1.2	50	5	5	283	5	50
6	5	283	1.2	50	7	71	285	1.2	50

[0219] for embodiment A K, use with last epiphase with order, the time that different is in the stage 7 is 75 minutes.

[0220] Camile of embodiment A G order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	10	245	760	0
2	5	245	760	50	1	10	245	760	0
2	5	245	760	50	3	30	285	760	50
4	3	285	175	50	3	30	285	760	50
4	3	285	175	50	5	5	285	5	50
6	5	285	4	50	5	5	285	5	50
6	5	285	4	50	7	220	290	4	50

[0221] Camile of embodiment A I order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	3	265	90	50	3	30	265	760	50
4	3	265	90	50	5	110	285	90	50
6	5	285	6	50	5	110	285	90	50
6	5	285	6	50	7	70	290	6	50

[0222] Camile of embodiment A J order

Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)
Stage	Time (minute)	Temperature (℃)	Vacuum (holder)	Stir (rpm)	1	5	245	760	0
2	5	245	760	50	1	5	245	760	0
2	5	245	760	50	3	30	265	760	50
4	3	265	90	50	3	30	265	760	50
4	3	265	90	50	5	110	290	90	50
6	5	290	6	25	5	110	290	90	50
6	5	290	6	25	7	110	295	6	25

Embodiment A L-AR

[0223] with dimethyl terephthalate (DMT), 1,4 cyclohexane dimethanol and 2,2,4,4-tetramethyl--1, the 3-cyclobutanediol adds in single neck round-bottomed flask of 500ml.The polyester of present embodiment prepares with glycol/sour ratio of 1.2/1, and is wherein all excessive in 2,2,4,4-tetramethyl--1,3-cyclobutanediol.The tributyltin oxide catalyst that adds capacity is to obtain the tin of 300ppm in final polymkeric substance.Flask is under the 0.2 SCFC nitrogen purging with the low ability of vacuum drop.Flask is immersed in the Belmont metal bath at 200 ℃, and after the reactant fusion, stir in 200RPM.After about 2.5 hours, temperature is elevated to 210 ℃, and these conditions were kept 2 hours again.Temperature is elevated to 285 ℃ (in about 25 minutes), and in 5 minutes, pressure is reduced to 0.3mmHg.Along with viscosity increases and reduce stirring velocity, use the minimum stirring of 15RPM.Change the total polymerization time to reach the target logarithmic viscosity number.After finishing polymerization, the Belmont metal bath of loweing, and make polymkeric substance be cooled to be lower than its second-order transition temperature.After about 30 minutes, flask is immersed Belmont metal bath (at this 30 minutes waiting periods, temperature has been elevated to 295 ℃) once more, and heated polymerizable thing material is up to taking out from glass flask.Stirring polymer material under medium level cools off up to polymkeric substance.Take out polymkeric substance from flask, and be ground to and pass through the 3mm sieve.Change this operation to be prepared as follows the described copolyesters that 45 moles of % targets are formed that has.

[0224] logarithmic viscosity number is as detection as described in above-mentioned " detection method ".The composition of polyester is by being explained in above-mentioned detection method part ¹H NMR measures.Second-order transition temperature uses after quenching 20 ℃/minute speed control second-heating to detect by DSC.

[0225] following table shows the experimental data of present embodiment polyester.These data show for the constant logarithmic viscosity number, improve 2,2,4,4-tetramethyl--1, and the consumption of 3-cyclobutanediol can improve second-order transition temperature in almost linear mode.Fig. 3 also shows the dependency of Tg to composition and logarithmic viscosity number.

Table 8

Embodiment	Mole % TMCD	% cis TMCD	IV (dL/g)	T _g(℃)	η at 260 ℃ _o(pool)	η at 275 ℃ _o(pool)	η at 290 ℃ _o(pool)
Embodiment	Mole % TMCD	% cis TMCD	IV (dL/g)	T _g(℃)	η at 260 ℃ _o(pool)	η at 275 ℃ _o(pool)	η at 290 ℃ _o(pool)	A	43.9	72.1	0.46	131	NA	NA	NA
B	44.2	36.4	0.49	118	NA	NA	NA	A	43.9	72.1	0.46	131	NA	NA	NA
B	44.2	36.4	0.49	118	NA	NA	NA	C	44	71.7	0.49	128	NA	NA	NA
D	44.3	36.3	0.51	119	NA	NA	NA	C	44	71.7	0.49	128	NA	NA	NA
D	44.3	36.3	0.51	119	NA	NA	NA	E	46.1	46.8	0.51	125	NA	NA	NA
F	43.6	72.1	0.52	128	NA	NA	NA	E	46.1	46.8	0.51	125	NA	NA	NA
F	43.6	72.1	0.52	128	NA	NA	NA	G	43.6	72.3	0.54	127	NA	NA	NA
H	46.4	46.4	0.54	127	NA	NA	NA	G	43.6	72.3	0.54	127	NA	NA	NA
H	46.4	46.4	0.54	127	NA	NA	NA	I	45.7	47.1	0.55	125	NA	NA	NA
J	44.4	35.6	0.55	118	NA	NA	NA	I	45.7	47.1	0.55	125	NA	NA	NA
J	44.4	35.6	0.55	118	NA	NA	NA	K	45.2	46.8	0.56	124	NA	NA	NA
L	43.8	72.2	0.56	129	NA	NA	NA	K	45.2	46.8	0.56	124	NA	NA	NA
L	43.8	72.2	0.56	129	NA	NA	NA	M	45.8	46.4	0.56	124	NA	NA	NA
N	45.1	47.0	0.57	125	NA	NA	NA	M	45.8	46.4	0.56	124	NA	NA	NA
N	45.1	47.0	0.57	125	NA	NA	NA	O	45.2	46.8	0.57	124	NA	NA	NA
P	45	46.7	0.57	125	NA	NA	NA	O	45.2	46.8	0.57	124	NA	NA	NA
P	45	46.7	0.57	125	NA	NA	NA	Q	45.1	47.1	0.58	127	NA	NA	NA
R	44.7	35.4	0.59	123	NA	NA	NA	Q	45.1	47.1	0.58	127	NA	NA	NA
R	44.7	35.4	0.59	123	NA	NA	NA	S	46.1	46.4	0.60	127	NA	NA	NA
T	45.7	46.8	0.60	129	NA	NA	NA	S	46.1	46.4	0.60	127	NA	NA	NA
T	45.7	46.8	0.60	129	NA	NA	NA	U	46	46.3	0.62	128	NA	NA	NA
V	45.9	46.3	0.62	128	NA	NA	NA	U	46	46.3	0.62	128	NA	NA	NA
V	45.9	46.3	0.62	128	NA	NA	NA	X	45.8	46.1	0.63	128	NA	NA	NA
Y	45.6	50.7	0.63	128	NA	NA	NA	X	45.8	46.1	0.63	128	NA	NA	NA
Y	45.6	50.7	0.63	128	NA	NA	NA	Z	46.2	46.8	0.65	129	NA	NA	NA
AA	45.9	46.2	0.66	128	NA	NA	NA	Z	46.2	46.8	0.65	129	NA	NA	NA
AA	45.9	46.2	0.66	128	NA	NA	NA	AB	45.2	46.4	0.66	128	NA	NA	NA
AC	45.1	46.5	0.68	129	NA	NA	NA	AB	45.2	46.4	0.66	128	NA	NA	NA
AC	45.1	46.5	0.68	129	NA	NA	NA	AD	46.3	52.4	0.52	NA	NA	NA	NA
AE	45.7	50.9	0.54	NA	NA	NA	NA	AD	46.3	52.4	0.52	NA	NA	NA	NA
AE	45.7	50.9	0.54	NA	NA	NA	NA	AF	46.3	52.6	0.56	NA	NA	NA	NA
AG	46	50.6	0.56	NA	NA	NA	NA	AF	46.3	52.6	0.56	NA	NA	NA	NA
AG	46	50.6	0.56	NA	NA	NA	NA	AH	46.5	51.8	0.57	NA	NA	NA	NA
AI	45.6	51.2	0.58	NA	NA	NA	NA	AH	46.5	51.8	0.57	NA	NA	NA	NA
AI	45.6	51.2	0.58	NA	NA	NA	NA	AJ	46	51.9	0.58	NA	NA	NA	NA
AK	45.5	51.2	0.59	NA	NA	NA	NA	AJ	46	51.9	0.58	NA	NA	NA	NA
AK	45.5	51.2	0.59	NA	NA	NA	NA	AL	45.8	50.1	0.624	125	NA	NA	7696
AM	45.7	49.4	0.619	128	NA	NA	7209	AL	45.8	50.1	0.624	125	NA	NA	7696
AM	45.7	49.4	0.619	128	NA	NA	7209	AN	46.2	49.3	0.548	124	NA	NA	2348
AP	45.9	49.5	0.72	128	76600	40260	19110	AN	46.2	49.3	0.548	124	NA	NA	2348
AP	45.9	49.5	0.72	128	76600	40260	19110	AQ	46.0	50	0.71	131	68310	32480	17817
AR	46.1	49.6	0.383	117	NA	NA	387	AQ	46.0	50	0.71	131	68310	32480	17817
AR	46.1	49.6	0.383	117	NA	NA	387	AS	47.2	NA	0.48	NA	NA	NA	NA

NA=does not obtain

Embodiment 9

[0226] the present embodiment explanation 2,2,4,4-tetramethyl--1, and the dominant position of 3-cyclobutanediol isomer type (suitable or trans) is to the influence of polyester second-order transition temperature.

[0227] with dimethyl terephthalate (DMT), 1,4 cyclohexane dimethanol and 2,2,4,4-tetramethyl--1, the weighing of 3-cyclobutanediol adds in single neck round-bottomed flask of 500ml.The polyester of present embodiment prepares with glycol/sour ratio of 1.2/1, and is wherein all excessive in 2,2,4,4-tetramethyl--1,3-cyclobutanediol.The tributyltin oxide catalyst that adds capacity is to obtain the tin of 300ppm in final polymkeric substance.Flask is under the 0.2 SCFC nitrogen purging with the low ability of vacuum drop.Flask is immersed in the Belmont metal bath at 200 ℃, and after the reactant fusion, stir in 200RPM.After about 2.5 hours, temperature is elevated to 210 ℃, and these conditions were kept 2 hours again.Temperature is elevated to 285 ℃ (in about 25 minutes), and in 5 minutes, pressure is reduced to 0.3mmHg.Along with viscosity increases and reduce stirring velocity, use the minimum stirring of 15RPM.Change the total polymerization time to reach the target logarithmic viscosity number.After finishing polymerization, the Belmont metal bath of loweing, and make polymkeric substance be cooled to be lower than its second-order transition temperature.After about 30 minutes, flask is immersed Belmont metal bath (at this 30 minutes waiting periods, temperature has been elevated to 295 ℃) once more, and heated polymerizable thing material is up to taking out from glass flask.Stirring polymer material under medium level cools off up to polymkeric substance.Take out polymkeric substance from flask, and be ground to and pass through the 3mm sieve.Change this operation to be prepared as follows the described copolyesters that 45 moles of % targets are formed that has.

[0228] logarithmic viscosity number is as detection as described in above-mentioned " detection method ".The composition of polyester is by being explained in above-mentioned detection method part ¹H NMR measures.Second-order transition temperature uses after quenching 20 ℃/minute speed control second-heating to detect by DSC.

[0229] following table shows the experimental data of present embodiment polyester.These data show for the constant logarithmic viscosity number, cis 2,2,4, and 4-tetramethyl--1, the 3-cyclobutanediol is trans 2,2,4 improving validity aspect the second-order transition temperature, 4-tetramethyl--1, about twice of 3-cyclobutanediol.

Table 9

2,2,4,4-tetramethyl--1, the suitable/trans composition of 3-cyclobutanediol is to the influence of Tg

Embodiment	Mole % TMCD	IV (dL/g)	T _g (℃)	η at 260 ℃ _o(pool)	η at 275 ℃ _o(pool)	η at 290 ℃ _o(pool)	% cis TMCD
Embodiment	Mole % TMCD	IV (dL/g)	T _g (℃)	η at 260 ℃ _o(pool)	η at 275 ℃ _o(pool)	η at 290 ℃ _o(pool)	% cis TMCD	A	45.8	0.71	119	NA.	N.A.	N.A.	4.1
B	43.2	0.72	122	N.A.	N.A.	N.A.	22.0	A	45.8	0.71	119	NA.	N.A.	N.A.	4.1
B	43.2	0.72	122	N.A.	N.A.	N.A.	22.0	C	46.8	0.57	119	26306	16941	6601	22.8
D	43.0	0.67	125	55060	36747	14410	23.8	C	46.8	0.57	119	26306	16941	6601	22.8
D	43.0	0.67	125	55060	36747	14410	23.8	E	43.8	0.72	127	101000	62750	25330	24.5
F	45.9	0.533	119	11474	6864	2806	26.4	E	43.8	0.72	127	101000	62750	25330	24.5
F	45.9	0.533	119	11474	6864	2806	26.4	G	45.0	0.35	107	N.A.	N.A.	N.A.	27.2
H	41.2	0.38	106	1214	757	N.A.	29.0	G	45.0	0.35	107	N.A.	N.A.	N.A.	27.2
H	41.2	0.38	106	1214	757	N.A.	29.0	I	44.7	0.59	123	N.A.	N.A.	N.A.	35.4
J	44.4	0.55	118	N.A.	N.A.	N.A.	35.6	I	44.7	0.59	123	N.A.	N.A.	N.A.	35.4
J	44.4	0.55	118	N.A.	N.A.	N.A.	35.6	K	44.3	0.51	119	N.A.	N.A.	N.A.	36.3
L	44.0	0.49	128	N.A.	N.A.	N.A.	71.7	K	44.3	0.51	119	N.A.	N.A.	N.A.	36.3
L	44.0	0.49	128	N.A.	N.A.	N.A.	71.7	M	43.6	0.52	128	N.A.	N.A.	N.A.	72.1
N	43.6	0.54	127	N.A.	N.A.	N.A.	72.3	M	43.6	0.52	128	N.A.	N.A.	N.A.	72.1
N	43.6	0.54	127	N.A.	N.A.	N.A.	72.3	O	41.5	0.58	133	15419	10253	4252	88.7
P	43.8	0.57	135	16219	10226	4235	89.6	O	41.5	0.58	133	15419	10253	4252	88.7
P	43.8	0.57	135	16219	10226	4235	89.6	Q	41.0	0.33	120	521	351	2261	90.4
R	43.0	0.56	134	N.A.	N.A.	N.A.	90.6	Q	41.0	0.33	120	521	351	2261	90.4
R	43.0	0.56	134	N.A.	N.A.	N.A.	90.6	S	43.0	0.49	132	7055	4620	2120	90.6
T	43.1	0.55	134	12970	8443	3531	91.2	S	43.0	0.49	132	7055	4620	2120	90.6
T	43.1	0.55	134	12970	8443	3531	91.2	U	45.9	0.52	137	N.A.	N.A.	N.A.	98.1

NA=does not obtain

Embodiment 10

[0230] present embodiment has been described and has been contained 100 moles of % dimethyl terephthalate (DMT) residues, 55 moles of %1,4-cyclohexanedimethanol residue and 45 moles of %2,2,4,4-tetramethyl--1, the preparation of the copolyesters of 3-cyclobutanediol residue.

[0231] with 97.10g (0.5mol) dimethyl terephthalate (DMT), 52.46g (0.36mol) 1,4-cyclohexanedimethanol, 34.07g (0.24mol) 2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol and 0.0863g (300ppm) dibutyl tin oxide are put into the 500ml flask that is equipped with nitrogen inlet, metal agitator and short distillation column.Flask is put into the Wood metal bath that is heated to 200 ℃.Flask contents 200 ℃ of heating 1 hour, is elevated to 210 ℃ then.Reaction mixture kept 2 hours at 210 ℃, then at 30 minutes internal heating to 290 ℃.In case reach 290 ℃, in subsequently 3-5 minute, apply the vacuum of 0.01psig gradually.Make whole vacuum (0.01psig) keep about 45 minutes altogether to remove excessive unreacted glycol.The polymkeric substance of obtained to have high melt viscosity, range estimation is transparent and colourless, its second-order transition temperature is 125 ℃, logarithmic viscosity number is 0.64dL/g.

Embodiment 11-Comparative Examples

[0232] present embodiment illustrates based on 100%2,2,4,4-tetramethyl--1, and the polyester of 3-cyclobutanediol has half-time of crystallization slowly.

[0233] only based on terephthalic acid and 2,2,4,4-tetramethyl--1, the polyester of 3-cyclobutanediol according to the foregoing description 1A similar methods preparation, and have the performance shown in the table 10.This polyester has the dibutyl tin oxide of 300ppm.2,2,4,4-tetramethyl--1, the anti-/ suitable ratio of 3-cyclobutanediol is 65/35.

[0234] at 320 ℃ of polymkeric substance compacting film from grinding.Detecting half-time of crystallization from melt is to carry out at 220-250 ℃ the temperature increment with 10 ℃, and is reported in the table 10.With the fastest half-time of crystallization of sample as the half-time of crystallization minimum value relevant with temperature.The fastest half-time of crystallization of this polyester is about 1300 minutes.To be worth and have only comparing of extremely short half-time of crystallization (less than 1 minute), as shown in Figure 1 based on the polyester (PCT) of terephthalic acid and 1,4 cyclohexane dimethanol (being not used in the comonomer of modification).

Table 10

Half-time of crystallization (minute)

Comonomer (mole %)	IV(dl/g)	T _g(℃)	T _max(℃)	220 ℃ (minute)	230 ℃ (minute)	240 ℃ (minute)	250 ℃ (minute)
Comonomer (mole %)	IV(dl/g)	T _g(℃)	T _max(℃)	220 ℃ (minute)	230 ℃ (minute)	240 ℃ (minute)	250 ℃ (minute)	100mol％F	0.63	170.0	330	3291	3066	1303	1888

Wherein: F is 2,2,4,4-tetramethyl--1,3-cyclobutanediol (anti-/ suitable=65/35)

Embodiment 12-Comparative Examples

[0235] use 3.5 inches single screw extrusion machine productions to contain the sheet material of polyester, described polyester made have 100 moles of % terephthalic acid residues, 80 moles of %1,4-cyclohexanedimethanol and 20 moles of %2,2,4,4-tetramethyl--1, the target of 3-cyclobutanediol residue is formed.Sheet material is extruded continuously, be corrected to the thickness of 177 mils, then various sheet materials shearings are reached dimensional requirement.On a sheet material, detect logarithmic viscosity number and second-order transition temperature.The logarithmic viscosity number that records sheet material is 0.69dL/g.The second-order transition temperature that records sheet material is 106 ℃.Then sheet material is regulated fortnights down 50% relative humidity and 60 ℃.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment G) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 106 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has at least 95% stretching, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	86	145	501	64	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	N
B	A	86	145	501	64						N
B		100	150	500	63	N
C		100	150	500	63	N	118	156	672	85	N
C	D	135	163	736	94	N	118	156	672	85	N
E	D	135	163	736	94	N	143	166	760	97	N
E	F	150	168	740	94	L	143	166	760	97	N
G	F	150	168	740	94	L	159	172	787	100	L

Embodiment 13-Comparative Examples

[0236] use 3.5 inches single screw extrusion machine productions to contain the sheet material of polyester, described polyester made have 100 moles of % terephthalic acid residues, 80 moles of %1,4-cyclohexanedimethanol and 20 moles of %2,2,4,4-tetramethyl--1, the target of 3-cyclobutanediol residue is formed.Sheet material is extruded continuously, be corrected to the thickness of 177 mils, then various sheet materials shearings are reached dimensional requirement.On a sheet material, detect logarithmic viscosity number and second-order transition temperature.The logarithmic viscosity number that records sheet material is 0.69dL/g.The second-order transition temperature that records sheet material is 106 ℃.Then sheet material is regulated fortnights down 100% relative humidity and 25 ℃.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 60/40/40% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment G) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 106 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has at least 95% stretching, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	141	154	394	53	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	N
B	A	141	154	394	53	163	157	606	82	N	N
B	C	185	160	702	95	163	157	606	82	N	N
D	C	185	160	702	95	195	161	698	95	N	N
D	E	215	163	699	95	195	161	698	95	N	L
F	E	215	163	699	95	230	168	705	96	L	L
F	G	274	174	737	100	230	168	705	96	L	H
H	G	274	174	737	100	275	181	726	99	H	H

Embodiment 14-Comparative Examples

[0237] uses 3.5 inches sheet materials that single screw extrusion machine production is made up of Kelvx 201.Kelvx is that a kind of 69.85%PCTG of containing is (from the Eastar of Eastman Chemcial Co., have 100 moles of % terephthalic acid residues, 62 moles of %1,4-cyclohexanedimethanol and 38 moles of % glycol residues), the blend of 30%PC (bisphenol-a polycarbonate) and 0.15%Weston 619 (stablizer that Crompton Corporation sells).Sheet material is extruded continuously, be corrected to the thickness of 177 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 100 ℃.Then sheet material is regulated fortnights down 50% relative humidity and 60 ℃.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment E) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 100 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has at least 95% stretching, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	90	146	582	75	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	N
B	A	90	146	582	75	101	150	644	83	N	N
B	C	111	154	763	98	101	150	644	83	N	N
D	C	111	154	763	98	126	159	733	95	N	N
D	E	126	159	775	100	126	159	733	95	N	N
F	E	126	159	775	100	141	165	757	98	N	N
F	G	148	168	760	98	141	165	757	98	N	L

Embodiment 15-Comparative Examples

[0238] uses 3.5 inches sheet materials that single screw extrusion machine production is made up of Kelvx 201.Sheet material is extruded continuously, be corrected to the thickness of 177 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 100 ℃.Then sheet material is regulated fortnights down 100% relative humidity and 25 ℃.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 60/40/40% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment H) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 100 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has at least 95% stretching, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	110	143	185	25	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	N
B	A	110	143	185	25	145	149	529	70	N	N
B	C	170	154	721	95	145	149	529	70	N	N
D	C	170	154	721	95	175	156	725	96	N	N
D	E	185	157	728	96	175	156	725	96	N	N
F	E	185	157	728	96	206	160	743	98	L	N
F	G	253	NR	742	98	206	160	743	98	L	H
H	G	253	NR	742	98	261	166	756	100	H	H

NR=is record not

Embodiment 16-Comparative Examples

[0239] uses 3.5 inches sheet materials that single screw extrusion machine production is made up of PCTG 25976 (the 1,4 cyclohexane dimethanol residue of 100 moles of % terephthalic acid residues, 62 moles of % and the glycol residue of 38 moles of %).Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 87 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.17 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment A) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 87 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has stretching greater than 95%, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	102	183	816	100	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	N
B	A	102	183	816	100	92	171	811	99	N	N
B	C	77	160	805	99	92	171	811	99	N	N
D	C	77	160	805	99	68	149	804	99	N	N
D	E	55	143	790	97	68	149	804	99	N	N
F	E	55	143	790	97	57	138	697	85	N	N

Embodiment 17-Comparative Examples

[0240] use 1.25 inches single screw extrusion machine productions by the Teijin L-1250 polycarbonate (a kind of bisphenol-a polycarbonate) of 20 weight % but, the PCTG 25976 of 79.85 weight % and the miscible blends that 0.15 weight %Weston 619 forms.The sheet material that uses 3.5 inches single screw extrusion machine productions to form then by this blend.Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 94 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.25 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment A) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 94 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has stretching greater than 95%, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	92	184	844	100	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	H
B	A	92	184	844	100	86	171	838	99	N	H
B	C	73	160	834	99	86	171	838	99	N	N
D	C	73	160	834	99	58	143	787	93	N	N
D	E	55	143	665	79	58	143	787	93	N	N

Embodiment 18-Comparative Examples

[0241] but use 1.25 inches single screw extrusion machine productions by the Teijin L-1250 polycarbonate of 30 weight %, the PCTG 25976 of 69.85 weight % and the miscible blends that 0.15 weight %Weston 619 forms.The sheet material that uses 3.5 inches single screw extrusion machine productions to form then by this blend.Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 99 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.25 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment A) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 99 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has stretching greater than 95%, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (C)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	128	194	854	100	Heat-up time (s)	Sheet temperature (C)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	H
B	A	128	194	854	100	98	182	831	97	L	H
B	C	79	160	821	96	98	182	831	97	L	N
D	C	79	160	821	96	71	149	819	96	N	N
D	E	55	145	785	92	71	149	819	96	N	N
F	E	55	145	785	92	46	143	0	0	NA	N
F	G	36	132	0	0	46	143	0	0	NA	NA

NA=does not obtain.Null value represents not form because sheet material does not enter mould sheet material (seemingly because too cold).

Embodiment 19-Comparative Examples

[0242] but use 1.25 inches single screw extrusion machine productions by the Teijin L-1250 polycarbonate of 40 weight %, the PCTG 25976 of 59.85 weight % and the miscible blends that 0.15 weight %Weston 619 forms.The sheet material that uses 3.5 inches single screw extrusion machine productions to form then by this blend.Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 105 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.265 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment 8A-8E) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 105 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has stretching greater than 95%, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	111	191	828	100	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	H
B	A	111	191	828	100	104	182	828	100	H	H
B	C	99	179	827	100	104	182	828	100	H	N
D	C	99	179	827	100	97	177	827	100	N	N
D	E	78	160	826	100	97	177	827	100	N	N
F	E	78	160	826	100	68	149	759	92	N	N
F	G	65	143	606	73	68	149	759	92	N	N

Embodiment 20-Comparative Examples

[0243] but use 1.25 inches single screw extrusion machine productions by the Teijin L-1250 polycarbonate of 50 weight %, the PCTG 25976 of 49.85 weight % and the miscible blends that 0.15 weight %Weston 619 forms.Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 111 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.225 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching by with piece volumes divided by the maximum part volume (embodiment A-D) calculate that in this group experiment, reaches.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result proves that these second-order transition temperatures are 111 ℃ thermoplastic sheets thermoforming under the following conditions, and this shows as these sheet materials and has stretching greater than 95%, do not bubble, and before thermoforming dry sheet material in advance not.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	118	192	815	100	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	H
B	A	118	192	815	100	99	182	815	100	H	H
B	C	97	177	814	100	99	182	815	100	H	L
D	C	97	177	814	100	87	171	813	100	N	L
D	E					87	171	813	100	N
	E	80	160	802	98	N
	F	80	160	802	98	N	64	154	739	91	N
G	F						64	154	739	91	N
G		60	149	0	0	NA

Embodiment 21-Comparative Examples

[0244] but use 1.25 inches single screw extrusion machine productions by the Teijin L-1250 polycarbonate of 60 weight %, the PCTG 25976 of 39.85 weight % and the miscible blends that 0.15 weight %Weston 619 forms.The sheet material that uses 3.5 inches single screw extrusion machine productions to form then by this blend.Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 117 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.215 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment A) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result prove these second-order transition temperatures be 117 ℃ thermoplastic sheets can be under the following conditions can not thermoforming, this does not show as having before the thermoforming can not produce under the situation of dry sheet material in advance has greater than 95% stretching and does not have blistered sheet material.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	114	196	813	100	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	H
B	A	114	196	813	100						H
B		100	182	804	99	H
C		100	182	804	99	H	99	177	801	98	L
C	D	92	171	784	96	L	99	177	801	98	L
E	D	92	171	784	96	L	82	168	727	89	L
E	F	87	166	597	73	N	82	168	727	89	L

Embodiment 22-Comparative Examples

[0245] but use 1.25 inches single screw extrusion machine productions by the Teijin L-1250 polycarbonate of 65 weight %, the PCTG 25976 of 34.85 weight % and the miscible blends that 0.15 weight %Weston 619 forms.The sheet material that uses 3.5 inches single screw extrusion machine productions to form then by this blend.Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 120 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.23 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment A) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result prove these second-order transition temperatures be 120 ℃ thermoplastic sheets can be under the following conditions can not thermoforming, this does not show as having before the thermoforming can not produce under the situation of dry sheet material in advance has greater than 95% stretching and does not have blistered sheet material.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	120	197	825	100	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	H
B	A	120	197	825	100	101	177	820	99	H	H
B	C	95	174	781	95	101	177	820	99	H	L
D	C	95	174	781	95	85	171	727	88	L	L
D	E	83	166	558	68	85	171	727	88	L	L

Embodiment 23-Comparative Examples

[0246] but use 1.25 inches single screw extrusion machine productions by the Teijin L-1250 polycarbonate of 70 weight %, the PCTG 25976 of 29.85 weight % and the miscible blends that 0.15 weight %Weston 619 forms.The sheet material that uses 3.5 inches single screw extrusion machine productions to form then by this blend.Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 123 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.205 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment A and B) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result prove these second-order transition temperatures be 123 ℃ thermoplastic sheets can be under the following conditions can not thermoforming, this does not show as having before the thermoforming can not produce under the situation of dry sheet material in advance has greater than 95% stretching and does not have blistered sheet material.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	126	198	826	100	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	H
B	A	126	198	826	100	111	188	822	100	H	H
B	C	97	177	787	95	111	188	822	100	H	L
D	C	97	177	787	95	74	166	161	19	L	L
D	E	58	154	0	0	74	166	161	19	L	NA
F	E	58	154	0	0	48	149	0	0	NA	NA

Embodiment 24-Comparative Examples

[0247] uses 3.5 inches sheet materials that single screw extrusion machine production is made up of Teijin L-1250 polycarbonate.Sheet material is extruded continuously, be corrected to the thickness of 118 mils, then various sheet materials shearings are reached dimensional requirement.Detect second-order transition temperature on a sheet material, recording is 149 ℃.Then sheet material is regulated the four stars phases down 50% relative humidity and 60 ℃.Recording water-content is 0.16 weight %.Using the Brown thermoforming machine subsequently is in 2.5: 1 the former to stretch ratio with sheet heat forming.Thermoforming baking oven for heating device is set at 70/60/60% output, only uses top firing.In baking oven, keep the various times to measure the influence of sheet temperature sheet material to part quality, as shown in the table.Part quality stretches by volume, the calculating that detects the thermoforming parts and visual observations thermoforming parts are determined.Stretching is by calculating divided by the maximum part volume (embodiment A) that reaches in this group experiment with piece volumes.Any foaming in the parts of visual observations thermoforming, the foaming degree evaluation is not for having (N), low (L) or high (H).Following result prove these second-order transition temperatures be 149 ℃ thermoplastic sheets can be under the following conditions can not thermoforming, this does not show as having before the thermoforming can not produce under the situation of dry sheet material in advance has greater than 95% stretching and does not have blistered sheet material.

Embodiment	The thermoforming condition		Part quality
	The thermoforming condition		Part quality			Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)
	A	152	216	820	100	Heat-up time (s)	Sheet temperature (℃)	Piece volumes (mL)	Stretch (%)	Bubble (N, L, H)	H
B	A	152	216	820	100	123	193	805	98	H	H
B	C	113	191	179	22	123	193	805	98	H	H
D	C	113	191	179	22	106	188	0	0	H	H
D	E	95	182	0	0	106	188	0	0	H	NA
F	E	95	182	0	0	90	171	0	0	NA	NA

[0248] as seen compare with commercial polyesters from the data of above-mentioned related work embodiment are relatively more obvious, polyester of the present invention provides the remarkable advantage aspect second-order transition temperature, density, slow crystallization rate, melt viscosity and toughness.

[0249] describes the present invention in detail, still it should be understood that and in the spirit and scope of the invention, to carry out changes and improvements with reference to embodiment disclosed herein.

[0250] describes the present invention in detail, still it should be understood that and in the spirit and scope of the invention, to carry out changes and improvements with reference to embodiment disclosed herein.

Claims

1. polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

The ii) 1,4 cyclohexane dimethanol residue of 1-99 mole %,

The logarithmic viscosity number of wherein said polyester is 0.35 to less than 0.70dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; The Tg of wherein said polyester is 110-200 ℃.

2. composition as claimed in claim 1, the logarithmic viscosity number of wherein said polyester are 0.35 to less than 0.70dL/g.

3. composition as claimed in claim 1, the logarithmic viscosity number of wherein said polyester is 0.40-0.70dL/g.

4. composition as claimed in claim 1, the logarithmic viscosity number of wherein said polyester is 0.50-0.70dL/g.

5. composition as claimed in claim 1, the logarithmic viscosity number of wherein said polyester is 0.50-0.75dL/g.

6. composition as claimed in claim 1, the logarithmic viscosity number of wherein said polyester are 0.58 to less than 0.70dL/g.

7. composition as claimed in claim 1, the logarithmic viscosity number of wherein said polyester are 0.60 to less than 0.70dL/g.

8. composition as claimed in claim 1, the Tg of wherein said polyester are 110-200 ℃.

9. composition as claimed in claim 1, the Tg of wherein said polyester are 110-170 ℃.

10. composition as claimed in claim 1, the Tg of wherein said polyester are 110-160 ℃.

11. composition as claimed in claim 1, the Tg of wherein said polyester are 110-150 ℃.

12. composition as claimed in claim 1, the Tg of wherein said polyester are 120-160 ℃.

13. composition as claimed in claim 1, the Tg of wherein said polyester are 120-150 ℃.

14. composition as claimed in claim 1, the Tg of wherein said polyester are 130-160 ℃.

15. composition as claimed in claim 1, the Tg of wherein said polyester are 130-150 ℃.

16. composition as claimed in claim 1, the Tg of wherein said polyester are 130-145 ℃.

17. composition as claimed in claim 1, the Tg of wherein said polyester are 140-150 ℃.

18. composition as claimed in claim 1, the Tg of wherein said polyester are 135-145 ℃.

19. composition as claimed in claim 1, the Tg of wherein said polyester are 148-200 ℃.

20. composition as claimed in claim 1, the Tg of wherein said polyester are 127-200 ℃.

21. composition as claimed in claim 1, the diol component of wherein said polyester contain 2,2,4 of 1-80 mole %, 4-tetramethyl--1, the 1,4 cyclohexane dimethanol residue of 3-cyclobutanediol residue and 20-99 mole %.

22. composition as claimed in claim 1, the diol component of wherein said polyester contain 2,2,4 of 50-99 mole %, 4-tetramethyl--1, and 3-cyclobutanediol residue and 1 is to the 1,4 cyclohexane dimethanol residue less than 50 moles of %.

23. composition as claimed in claim 1, the diol component of wherein said polyester contain 2,2,4 of 40-85 mole %, 4-tetramethyl--1, the 1,4 cyclohexane dimethanol residue of 3-cyclobutanediol residue and 15-60 mole %.

24. composition as claimed in claim 1, the diol component of wherein said polyester contain 2,2,4 of 40-80 mole %, 4-tetramethyl--1, the 1,4 cyclohexane dimethanol residue of 3-cyclobutanediol residue and 20-60 mole %.

25. composition as claimed in claim 1, the diol component of wherein said polyester contain 2,2,4 of 40-65 mole %, 4-tetramethyl--1, the 1,4 cyclohexane dimethanol residue of 3-cyclobutanediol residue and 35-55 mole %.

26. composition as claimed in claim 1, the diol component of wherein said polyester contain 2,2,4 of 40-55 mole %, 4-tetramethyl--1, the 1,4 cyclohexane dimethanol residue of 3-cyclobutanediol residue and 45-60 mole %.

27. composition as claimed in claim 1, the diol component of wherein said polyester contain 2,2,4 of 45-55 mole %, 4-tetramethyl--1, the 1,4 cyclohexane dimethanol residue of 3-cyclobutanediol residue and 45-55 mole %.

28. composition as claimed in claim 1, the diol component of wherein said polyester contain 2,2,4 of 46-55 mole %, 4-tetramethyl--1, and 3-cyclobutanediol residue and 45 is to the 1,4 cyclohexane dimethanol residue less than 55 moles of %.

29. composition as claimed in claim 1, wherein the dicarboxylic acid component is contained the terephthalic acid residue of 80-100 mole %.

30. composition as claimed in claim 1, wherein the dicarboxylic acid component is contained the terephthalic acid residue of 90-100 mole %.

31. composition as claimed in claim 1, wherein the dicarboxylic acid component is contained the terephthalic acid residue of 95-100 mole %.

32. composition as claimed in claim 1, wherein said polyester comprises 1, ammediol residue, 1,4-butyleneglycol residue or their mixture.

33. composition as claimed in claim 1, wherein said polyester comprises the ethylene glycol of 0.01-15 mole %.

34. composition as claimed in claim 1, wherein said polyester comprises the ethylene glycol of 0.01-10 mole %.

35. composition as claimed in claim 1 is wherein said 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue is to contain greater than 50 moles of % cis 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue and less than 50 moles of % trans 2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol residue.

36. composition as claimed in claim 1 is wherein said 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue is to contain greater than 55 moles of % cis 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue and less than 45 moles of % trans 2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol residue.

37. composition as claimed in claim 1 is wherein said 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue is that to contain 30-70 mole % trans 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue and 30-70 mole % cis 2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol residue.

38. composition as claimed in claim 1 is wherein said 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue is that to contain 40-60 mole % trans 2,2,4,4-tetramethyl--1,3-cyclobutanediol residue and 40-60 mole % cis 2,2,4,4-tetramethyl--1, the mixture of 3-cyclobutanediol residue.

39. containing, composition as claimed in claim 1, wherein said polymer blend be selected from following at least a polymkeric substance: nylon; Other polyester; Polymeric amide; Polystyrene; Polystyrene copolymer; Styrene/acrylonitrile copolymer; The acrylonitrile/butadiene/styrene multipolymer; Polymethylmethacrylate, acrylic copolymer; Polyetherimide; Polyphenylene oxide for example gathers 2, the 6-dimethylphenylene ether; Or polyphenyl ether/styrene blend; Polyphenylene sulfide; Polyphenylene sulfide/sulfone; Polyester/carbonic ether; Polycarbonate; Polysulfones; Polysulfones ether; The polyetherketone of aromatic dihydroxy compound; Or their mixture.

40. composition as claimed in claim 1, wherein said polymer blend contains at least a polycarbonate.

41. composition as claimed in claim 1, wherein said polyester contains the residue of at least a branching agent that is useful on polyester.

42. composition as claimed in claim 1, wherein said polyester contain the residue of at least a branching agent of 0.01-10 weight %, based on total molar percentage meter of glycol or diacid residues.

43. composition as claimed in claim 1 is wherein moored less than 30000 290 ℃ of melt viscosities that record described polyester on the rotation melt rheometer under 1 radian per second.

44. composition as claimed in claim 1, wherein said polyester 170 ℃ half-time of crystallization greater than 5 minutes.

45. composition as claimed in claim 1, wherein said polyester 170 ℃ half-time of crystallization greater than 1000 minutes.

46. composition as claimed in claim 1, wherein said polyester 170 ℃ half-time of crystallization greater than 10000 minutes.

47. composition as claimed in claim 1, wherein said polymer blend 23 ℃ density less than 1.2g/ml.

48. composition as claimed in claim 1, wherein said polymer blend contain at least a thermo-stabilizer or its reaction product.

49. composition as claimed in claim 1 wherein records the xanthochromia index of described polyester less than 50 according to ASTM D-1925.

50. composition as claimed in claim 1, wherein recording described polyester with 10 mil breach according to ASTM D256 in 1/8 inch thick rod is 3ft-lbs/in at least 23 ℃ notched izod intensity.

51. composition as claimed in claim 1, wherein recording described polyester with 10 mil breach according to ASTM D256 in 1/8 inch thick rod is 10ft-lbs/in at least 23 ℃ notched izod intensity.

52. composition as claimed in claim 1, wherein said polyester contains the residue of at least a catalyzer, described catalyst pack sn-containing compound or its reaction product.

53. a polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 40-65 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 35-60 mole % and

54. a polymer blend, it contains:

(I) at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid of 70-100 mole %, its ester or its mixture;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 1-99 mole % and

(II) residue of at least a branching agent;

Wherein the logarithmic viscosity number of polyester is 0.35-1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; The Tg of wherein said polyester is 110-200 ℃.

55. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.40-1.2dL/g.

56. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.40-1.1dL/g.

57. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.40-1dL/g.

58. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.40-0.9dL/g.

59. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.40-0.8dL/g.

60. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.50-1.2dL/g.

61. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.50-1.1dL/g.

62. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.50-1dL/g.

63. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.50-0.9dL/g.

64. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.50-0.8dL/g.

65. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.60-0.72dL/g.

66. as claim 1,53 or 54 described compositions, the logarithmic viscosity number of wherein said polyester is 0.76-1.2dL/g.

67. a polymer blend, it contains:

(I) at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 1-99 mole % and

(II) at least a thermo-stabilizer or its reaction product;

68. a polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 1-99 mole % and

The logarithmic viscosity number of wherein said polyester is 0.35-1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; The Tg of wherein said polyester be from greater than 148 until 200 ℃.

69. a polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) greater than 2,2,4 of 50 to 99 moles of %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) 1 to less than the 1,4 cyclohexane dimethanol residue of 50 moles of % and

70. as the described composition of claim 67, the Tg of wherein said polyester is 120-150 ℃.

71. as the described composition of claim 67, the Tg of wherein said polyester is 130-145 ℃.

72. as the described composition of claim 67, wherein said logarithmic viscosity number is 0.60-0.75dL/g.

73. as the described composition of claim 67, wherein said logarithmic viscosity number is 0.60-0.72dL/g.

74. a polymer blend, it contains at least a polyester that contains following component:

(a) dicarboxylic acid component, it contains:

I) terephthalic acid residue of 70-100 mole %;

(b) diol component, it contains:

I) 2,2,4 of 1-99 mole %, 4-tetramethyl--1,3-cyclobutanediol residue; With

Ii) the 1,4 cyclohexane dimethanol residue of 1-99 mole % and

Wherein the logarithmic viscosity number of polyester is 0.76-1.2dL/g, in the phenol/tetrachloroethane of 60/40 (w/w) under the concentration of 0.5g/100ml in 25 ℃ of mensuration; The Tg of wherein said polyester is 110-200 ℃.

75. polymer blend as claimed in claim 1, wherein said polyester is unbodied.

76. article of manufacture that comprises the described polymer blend of claim 1.

A 77. film or sheet material that comprises the described polymer blend of claim 1.

78. liquid crystal display film that comprises the described polymer blend of claim 1.

79. as the described liquid crystal display film of claim 78, it comprises the scatterer sheet material.

80. as the described liquid crystal display film of claim 78, it comprises compensate film.

81. as the described liquid crystal display film of claim 78, it comprises protective membrane.

82. as the described goods of claim 76, wherein said article of manufacture forms by extrusion-blown modling.

83. as the described goods of claim 76, wherein said article of manufacture forms by extruding stretch-blow.

84. as the described goods of claim 76, wherein said article of manufacture forms by injection moulding.

85. as the described goods of claim 76, wherein said article of manufacture forms by injection drawing blow.

A 86. film or sheet material that comprises the described polymer blend of claim 1.

87. as described film of claim 86 or sheet material, wherein said film or sheet material are by extruding or rolling formation.

88. injection-molded item that comprises the described polymer blend of claim 1.

89. a blend, it comprises:

(a) polyester of at least a claim 1 of 5-95 weight %; With

(b) at least a polymeric constituent of 5-95 weight %.

90. as the described blend of claim 89, wherein said at least a polymeric constituent is selected from following at least a: nylon; With the different polyester of the described polyester of claim 1; Polymeric amide; Polystyrene; Polystyrene copolymer; Styrene/acrylonitrile copolymer; The acrylonitrile/butadiene/styrene multipolymer; Polymethylmethacrylate, acrylic copolymer; Polyetherimide; Polyphenylene oxide for example gathers 2, the 6-dimethylphenylene ether; Or polyphenyl ether/styrene blend; Polyphenylene sulfide; Polyphenylene sulfide/sulfone; Polyester/carbonic ether; Polycarbonate; Polysulfones; Polysulfones ether; And the polyetherketone of aromatic dihydroxy compound.