JP3985264B2 - Method for producing highly functional polycarbonate polyol - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for producing a highly functional polycarbonate polyol.
[0002]
[Prior art]
Polycarbonate polyol is a polyurethane used in rigid foams, flexible foams, paints, adhesives, coating agents, elastomers, fibers, synthetic leather, ink binders, etc., by reaction with isocyanate compounds, like polyester polyols and polyether polyols. It is a useful compound as a raw material for producing a resin.
[0003]
Among these polycarbonate polyols, many polycarbonate diols having 2 hydroxyl groups are known. However, high-functionality polycarbonate polyols having a hydroxyl group number exceeding 2 for the purpose of improving the crosslinking density are not well known because of difficulty in synthesis and the like.
[0004]
For example, JP-B-57-39650 discloses a first aliphatic triol (trimethylolpropane, trimethylolethane, etc.), an aliphatic or alicyclic diol, and an aromatic carbonate. A process for producing polycarbonate triol which is liquid at room temperature by transesterification is described, but as pointed out in JP-A-3-220233, a mixture of diol and triol is used as an aromatic carbonate. In the polycarbonate polyol produced by the transesterification with the aromatic polyol, the aromatic alcohol is present in a free or bonded state. Therefore, when this is used for the reaction with the diisocyanate, the resulting polyurethane resin has satisfactory physical properties. It has been pointed out that things cannot be done. Similarly, when an aliphatic carbonate is used instead of an aromatic carbonate, a portion where the terminal is not a hydroxyl group remains, and when a polyurethane resin is produced, the performance is lowered. Also, in order to obtain the polycarbonate polycarbonate desired in this publication, it is necessary to continue to reduce the pressure throughout the reaction process. In order to remedy such drawbacks, Japanese Patent Application Laid-Open No. 3-220233 discloses a polycarbonate in which a polycarbonate diol and a triol compound and / or a tetraol compound are mixed and end groups are almost completely converted to hydroxyl groups by transesterification. Polyols are described, but polycarbonate diol is obtained by synthesis, and based on it, synthesis is performed through a multi-functionalization reaction and steps, resulting in high energy consumption and high production costs. Become. In addition, since the reaction temperature exceeds 200 ° C., impurities such as allyl group-terminated compounds are likely to be generated and remain, so when this is used for the reaction with diisocyanate, the resulting polyurethane has satisfactory physical properties. It has been pointed out that it cannot be obtained. Further, JP-A-5-9434 discloses a polycarbonate polyol for a coating resin having a specific number of hydroxyl groups, number average molecular weight, and hydroxyl value. Trimethylolethane and trimethyloyl are used as the high-functional alcohol to be used. -Lupropane, hexanetriol, pentaerythritol, and tris (hydroxyethyl) isocyanurate glycerin are mentioned. To obtain the desired polycarbonate polyol in this publication, the pressure is reduced throughout the reaction process. I must continue.
[0005]
As described above, the high-functional polycarbonate polyols obtained based on the description in the above publications all require severe reaction conditions that require heating exceeding 200 ° C. under normal pressure, or pressure reduction even at 200 ° C. or less. At the same time, the production cost for satisfying this reaction condition is increased, and further, there is a problem that impurities such as allyl group terminal compounds increase due to a high synthesis temperature exceeding 200 ° C.
[0006]
[Problems to be solved by the invention]
The present invention solves these problems, which are problems in producing a high-functional polycarbonate polyol, and because there are few terminal impurities, mechanical strength, heat resistance, weather resistance, hydrolysis resistance, crosslinkability, etc. And a method for producing a highly functional polycarbonate polyol that is non-crystalline at room temperature (specifically, there is no endothermic peak in the temperature range of −30 to 50 ° C. in differential scanning calorimetry (DSC)) The purpose is to do.
[0007]
[Means for Solving the Problems]
As a result of diligent research, the present inventors have selected a specific compound and transesterified to obtain a highly functional polycarbonate polyol that is amorphous at room temperature under milder temperature conditions than before. The present inventors have found that the series of problems can be solved, and have completed the present invention.
[0008]
That is, this invention is (1)-(6) shown below.
(1): In the method for producing a highly functional polycarbonate polyol obtained by transesterification, as a raw material composition for obtaining a highly functional polycarbonate polyol,(A) Ethylene oxide addition polymer of glycerin,(B) 3-Methyl-1,5-pentanediol,(C) Diethyl carbonateIt is characterized by consisting ofA method for producing a highly functional polycarbonate polyol having a terminal ethyl group concentration of 0.12% or less and a terminal allyl group concentration of 0.08% or less.
(2): (1)(A) GlycerinThe alkylene oxide addition polymer is an ethylene oxide addition polymer,(1)The manufacturing method of the highly functional polycarbonate polyol as described in 1 above.
(3)1: The average number of hydroxyl groups in the molecule is 2.1 to 3.5, (1Or (2)The manufacturing method of the highly functional polycarbonate polyol as described in 1 above.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
The present invention is described in detail below.
[0010]
As will be described later, when a triol monomer to which no alkylene oxide is added, for example, trimethylolpropane (hereinafter abbreviated as “TMP”), glycerin, or the like, is used as a raw material, a desired transesterification reaction hardly proceeds. In the present invention, this problem is (A)GlycerinThis is solved by using an alkylene oxide addition polymer of
[0011]
(A)GlycerinOf the alkylene oxide addition polymers ofGlycerinExamples of the alkylene oxide subjected to addition polymerization include cyclic ether monomers such as ethylene oxide, propylene oxide, and butylene oxide. These are addition-polymerized to an initiator by a known method as a single product or a mixture. In the present invention,GlycerinAs the alkylene oxide to be subjected to addition polymerization, ethylene oxide, propylene oxide, or a mixture of both is preferably added, and among them, ethylene oxide alone is more preferably added.
[0012]
Of the present inventionWhen producing a highly functional polycarbonate polyol, (B) 3-methyl-1,5-pentanediol is used.
[0013]
Of the present inventionWhen producing a highly functional polycarbonate polyol, (C) diethyl carbonate is used.
[0014]
In the present invention, a highly functional polycarbonate polyol having an average number of hydroxyl groups in at least one molecule of 2.1 to 3.5 can be obtained. If the average number of hydroxyl groups in one molecule is less than 2.1, it is excluded because it is highly functional as intended by the present invention. In order to obtain a highly functional polycarbonate polyol having an average hydroxyl group number exceeding 3.5 in one molecule, it is necessary to use polyols having an average hydroxyl group number exceeding 3 or an addition polymer of alkylene oxide of polyols. In this case, it is not preferable because it lacks practicality in terms of crystallinity of the liquid and increase in viscosity.
[0015]
Subsequently, a specific reaction will be described. The reaction in the present invention has the same reaction mechanism as a known transesterification reaction.
[0016]
In this invention, it is preferable to use the catalyst used by transesterification in the case of reaction. As this catalyst, lithium, sodium, potassium, rubidium, cesium, magnesium, calcium, strontium, barium, zinc, aluminum, titanium, cobalt, germanium, tin, lead, antimony, cerium and other metals, metal alkoxides, metal salts, A metal oxide etc. are mentioned. In the present invention, alkali metal, alkaline earth metal, zinc, titanium, lead carbonate, carboxylate, borate, silicate, carbonate, oxide, organometallic compound may be used as a catalyst. Of these, organic titanium compounds are more preferable.
[0017]
The amount of catalyst used is 0.0001 to 1%, preferably 0.001 to 0.1% of the total mass of the starting materials. When the amount of the catalyst is too small, the reaction time becomes long and the production efficiency is deteriorated. At the same time, the resulting high-functional polycarbonate polyol is also easily colored, which is not preferable. Moreover, when there is too much catalyst amount, since the water resistance of the highly functional polycarbonate polyol obtained may fall, it is unpreferable.
[0018]
The highly functional polycarbonate polyol in the present invention can proceed under milder conditions than known transesterification reactions. Specifically, in the process of proceeding the reaction, it is possible to proceed the reaction in a temperature range of 70 to 200 ° C. under normal pressure (that is, not accompanied by reduced pressure). The reaction is preferably allowed to proceed in the temperature range of 75 to 195 ° C, more preferably in the temperature range of 80 to 190 ° C. A reaction temperature of less than 70 ° C. is not preferable because the desired reaction does not proceed. When the reaction temperature exceeds 200 ° C., the production cost increases due to strict production conditions, and the resulting high-functional polycarbonate polyol is not preferable because impurities such as allyl-terminated compounds increase.
[0019]
Although the reaction can be carried out at normal pressure, it is also possible in the present invention to accelerate the reaction by carrying out the reaction in the latter half of the reaction under reduced pressure, for example, at 0.13 kPa (1 mmHg) to 26.6 kPa (200 mmHg). Further, during the known dealcoholization treatment after the transesterification reaction, it is also possible to promote this by reducing the pressure similarly.
[0020]
The initial stage of the reaction is performed in the vicinity of the boiling point of the dialkyl carbonate, specifically in the temperature range of 90 to 150 ° C. The temperature is gradually raised as the reaction proceeds, and the reaction is further advanced.
[0021]
An apparatus capable of separating the produced high-functional polycarbonate polyol and dialkyl carbonate is usually a reactor with a distillation column, and the reaction is carried out while the dialkyl carbonate is refluxed, and the low molecular hydroxyl group produced as the reaction proceeds. The contained compound is distilled off. At this time, when the dialkyl carbonate partially dissipates and dissipates together with the low molecular weight hydroxyl group-containing compound to be distilled, it is preferable to allow for this dissipating amount when the raw materials are weighed and charged. In practice, the dialkyl carbonate is preferably 1.1 to 1.3 times the theoretical molar ratio.
[0022]
The average number of hydroxyl groups in one molecule of the highly functional polycarbonate polyol in the present invention can be adjusted by changing the reaction molar ratio of triols as raw materials with alkylene oxide addition polymer, diols, and dialkyl carbonate.
[0023]
【Example】
EXAMPLES The present invention will be described below with reference to examples, but the present invention is not limited to these examples. In the examples, unless otherwise specified, “part” indicates mass part and “%” indicates mass%.
[0024]
About the highly functional polycarbonate polyol obtained in each Example, it measured (or calculated) by the method shown below about the following items. Viscosity, hydroxyl value, acid value, water content, number of colors and appearance at 75 ° C. are the methods specified in JIS K1557, and the melting point is DSC (DSC6200R manufactured by Seiko Instruments Inc. 10 ° C./min from −100 to 100 ° C. The terminal ethyl group concentration and the terminal allyl group concentration were measured by NMR (Varian's UNITY-500 type, solvent: CDCl3). The average number of hydroxyl groups in one molecule was calculated from the molar ratio of the polyols involved in the reaction, and the number average molecular weight was calculated from the average number of hydroxyl groups and the hydroxyl value obtained by this calculation.
[0025]
Example 1 In a reaction apparatus comprising a stirrer, a thermometer, a heating device, and a distillation tower, 57 parts of ethylene oxide addition polymer of glycerin (“Leocon GE230” hydroxyl value of 730 mg KOH / g, manufactured by Lion) and 3-789 of 3-MPD Part, 758 parts of DEC, and 0.05 part of tetrabutyl titanate as a reaction catalyst were charged, and the produced ethyl alcohol was distilled while maintaining the reaction product in a temperature range of 125 ° C to 135 ° C under a nitrogen stream. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, 4 to 10 ° C./hr. The temperature was raised to 190 ° C. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. The reduced pressure is 6.6 to 13.2 kPa / hr. While maintaining the reaction temperature at 190 ° C. The reaction was continued at a pressure of 1.3 kPa for 5 hours. The reaction was terminated when the terminal ethyl group concentration in NMR was 0.2% or less, which would not affect the urethanation reaction, and a liquid polycarbonate polyol was obtained at room temperature. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 2.5 Number average molecular weight: 1961 (target: 2000)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 1460 (mm 2 / s)
Hydroxyl value: 71.5 (mgKOH / g)
Acid value: 0.01 (mg KOH / g)
Moisture: 0.01 (%)
Number of colors: 10 (APHA No.)
Melting point: −100 ° C. or less Terminal ethyl group concentration (%): 0.08 Terminal allyl group concentration (%): 0.05
[0026]
Example 2 In the same reactor as in Example 1, 115 parts of ethylene oxide addition polymer of glycerin (“Leocon GE230”), 725 parts of 3-MPD, 725 parts of DEC, and 0 of tetrabutyl titanate as a reaction catalyst .05 parts were charged, and the produced ethyl alcohol was distilled while maintaining the reaction product in a temperature range of 125 ° C. to 135 ° C. under a nitrogen stream. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, 4 to 10 ° C./hr. The temperature was raised to 190 ° C. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a vacuum rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 190 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The reaction was terminated when the terminal ethyl group concentration in NMR was 0.2% or less, which would not affect the urethanation reaction, and a liquid polycarbonate polyol was obtained at room temperature. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 3.0 Number average molecular weight: 1997 (target: 2000)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 1548 (mm 2 / s)
Hydroxyl value: 84.3 (mgKOH / g)
Acid value: 0.01 (mg KOH / g)
Moisture: 0.01 (%)
Number of colors: 10 (APHA No.)
Melting point: −100 ° C. or less Terminal ethyl group concentration (%): 0.10 Terminal allyl group concentration (%): 0.07
[0027]
Example 3 In the same reactor as in Example 1, 87 parts of ethylene oxide addition polymer of glycerin (“Leocon GE350” hydroxyl value 480 mg KOH / g, manufactured by Lion), 753 parts of 3-MPD, 723 parts of DEC, 0.05 parts of tetrabutyl titanate was charged as a reaction catalyst, and the produced ethyl alcohol was distilled while maintaining the reaction product in a temperature range of 125 ° C to 135 ° C under a nitrogen stream. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, the temperature was raised to 190 ° C. at a rate of 4 to 10 ° C./hour. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a vacuum rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 190 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The reaction was terminated when the terminal ethyl group concentration in NMR was 0.2% or less, which would not affect the urethanation reaction, and a liquid polycarbonate polyol was obtained at room temperature. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 2.5 Number average molecular weight: 1908 (target: 2000)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 1640 (mm 2 / s)
Hydroxyl value: 73.5 (mgKOH / g)
Acid value: 0.04 (mgKOH / g)
Moisture: 0.01 (%)
Number of colors: 10 (APHA No.)
Melting point: −100 ° C. or less Terminal ethyl group concentration (%): 0.09 Terminal allyl group concentration (%): 0.07
[0028]
Example 4 In the same reactor as in Example 1, 175 parts of ethylene oxide addition polymer of glycerin (“Leocon GE350”), 676 parts of 3-MPD, 676 parts of DEC, and 0 of tetrabutyl titanate as a reaction catalyst .05 parts were charged, and the produced ethyl alcohol was distilled while maintaining the reaction product in a temperature range of 125 ° C. to 135 ° C. under a nitrogen stream. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, the temperature was raised to 190 ° C. at a rate of 4 to 10 ° C./hour. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a vacuum rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 190 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The reaction was terminated when the terminal ethyl group concentration in NMR was 0.2% or less, which would not affect the urethanation reaction, and a liquid polycarbonate polyol was obtained at room temperature. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 3.0 Number average molecular weight: 2052 (target: 2000)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 1640 (mm 2 / s)
Hydroxyl value: 82.0 (mgKOH / g)
Acid value: 0.04 (mgKOH / g)
Moisture: 0.01 (%)
Number of colors: 30 (APHA No.)
Melting point: −100 ° C. or less Terminal ethyl group concentration (%): 0.12 Terminal allyl group concentration (%): 0.03
[0029]
Example 5 In the same reactor as in Example 1, 350 parts of ethylene oxide addition polymer of glycerin (“Leocon GE350”), 533 parts of 3-MPD, 532 parts of DEC, and tetrabutyl titanate as a reaction catalyst were 0. .05 parts were charged, and the produced ethyl alcohol was distilled while maintaining the reaction product in a temperature range of 125 ° C. to 135 ° C. under a nitrogen stream. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, the temperature was raised to 190 ° C. at a rate of 4 to 10 ° C./hour. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a vacuum rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 190 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The reaction was terminated when the terminal ethyl group concentration in NMR was 0.2% or less, which would not affect the urethanation reaction, and a liquid polycarbonate polyol was obtained at room temperature. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 3.0 Number average molecular weight: 1008 (target: 1000)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 380 (mm 2 / s)
Hydroxyl value: 167 (mgKOH / g)
Acid value: 0.01 (mg KOH / g)
Moisture: 0.01 (%)
Number of colors: 20 (APHA No.)
Melting point: −100 ° C. or less Terminal ethyl group concentration (%): 0.10 Terminal allyl group concentration (%): 0.05
[0030]
Example 6 In the same reactor as in Example 1, 460 parts of ethylene oxide addition polymer of glycerin ("Leocon GE230"), 443 parts of 3-MPD, 442 parts of DEC, and tetrabutyl titanate as a reaction catalyst were 0. .05 parts were charged, and the produced ethyl alcohol was distilled while maintaining the reaction product in a temperature range of 125 ° C. to 135 ° C. under a nitrogen stream. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, the temperature was raised to 190 ° C. at a rate of 4 to 10 ° C./hour. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a vacuum rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 190 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The reaction was terminated when the terminal ethyl group concentration in NMR was 0.2% or less, which would not affect the urethanation reaction, and a liquid polycarbonate polyol was obtained at room temperature. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 3.0 Number average molecular weight: 500 (target: 500)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 153 (mm 2 / s)
Hydroxyl value: 336.8 (mgKOH / g)
Acid value: 0.03 (mgKOH / g)
Moisture: 0.01 (%)
Number of colors: 20 (APHA No.)
Melting point: −100 ° C. or less Terminal ethyl group concentration (%): 0.12 Terminal allyl group concentration (%): 0.08
[0031]
Although all the high-functional polycarbonate polyols obtained in Examples 1 to 6 were synthesized under mild conditions of less than 200 ° C. and under normal pressure except when removing low-boiling substances, terminal alkyl groups ( In the series of examples, there is almost no terminal ethyl group) and no terminal allyl group. As a result, it was possible to obtain a high-functional polycarbonate polyol having excellent quality.
[0032]
Comparative Example 1 A reactor similar to that of Example 1 was charged with 67.1 parts of TMP, 765 parts of 3-MPD, 764 parts of DEC, and 0.05 part of tetrabutyl titanate as a reaction catalyst under a nitrogen stream. The produced ethyl alcohol was distilled while maintaining the reaction product at a temperature of 125 ° C to 135 ° C. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, the temperature was increased to 220 ° C. at a rate of 4 to 10 ° C./hour. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 220 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a pressure reduction rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 220 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The synthesis was carried out with a target of 0.2% or less where the terminal ethyl group concentration would not affect the urethanization reaction by NMR, while the terminal allyl group concentration that would affect the urethanation reaction increased, and 0 Since the terminal ethyl group concentration was 0.2 or more, the reaction was terminated, and a polycarbonate polyol that was liquid at room temperature was obtained. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 3.0 Number average molecular weight (Note): about 1795 (Target: 2000)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 450 (mm 2 / s)
Hydroxyl value: 102.2 (mgKOH / g)
Acid value: 0.09 (mgKOH / g)
Moisture: 0.04 (%)
Number of colors: 30 (APHA No.)
Melting point: (not measured)
Terminal ethyl group concentration (%): 5.2 Terminal allyl group concentration (%): 3.8 (Note) The reason why the number average molecular weight is indicated as “about” is because many impurities that are not hydroxyl groups are present at the end. It is.
[0033]
The highly functional polycarbonate polyol obtained in Comparative Example 1 was synthesized under a high temperature condition of more than 200 ° C. (220 ° C. in this example), so that a terminal alkyl group (terminal ethyl group in this example) and a terminal Many allyl groups are present. Such a high-functional polycarbonate polyol has many impurities as described above, and is difficult to say.
[0034]
Comparative Example 2 A reactor similar to that in Example 1 was charged with 67.1 parts of TMP, 765 parts of 3-MPD, 764 parts of DEC, and 0.05 part of tetrabutyl titanate as a reaction catalyst under a nitrogen stream. The generated ethyl alcohol was distilled off while maintaining the reaction product in a temperature range of 125 ° C to 135 ° C. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, the temperature was raised to 190 ° C. at a rate of 4 to 10 ° C./hour. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a vacuum rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 190 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The synthesis was performed with the target of 0.2% or less, which would not affect the urethane reaction, by NMR, but the terminal ethyl group concentration did not fall below the target value, and the reaction was continued for another 10 hours under the same conditions. Continued. Although the terminal ethyl group concentration was 0.2% or more, the reaction was terminated, and a polycarbonate polyol liquid at room temperature was obtained. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 3.0 Number average molecular weight (Note): about 1713 (Target: 2000)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 340 (mm 2 / s)
Hydroxyl value: 112.2 (mgKOH / g)
Acid value: 0.09 (mgKOH / g)
Moisture: 0.04 (%)
Number of colors: 30 (APHA No.)
Melting point: (not measured)
Terminal ethyl group concentration (%): 14.2 Terminal allyl group concentration (%): 0.07 (Note) “About” is attached to the number average molecular weight because there are many impurities with non-hydroxyl groups at the ends. It is.
[0035]
Comparative Example 3 Reproduction was performed for Comparative Example 2. In the same reactor as in Example 1, 67.1 parts of TMP, 765 parts of 3-MPD, 764 parts of DEC, 0.05 part of tetrabutyl titanate as a reaction catalyst were charged, and the reactants were charged under a nitrogen stream. Ethyl alcohol was distilled off while maintaining a temperature range of 125 ° C to 135 ° C. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, the temperature was raised to 190 ° C. at a rate of 4 to 10 ° C./hour. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a vacuum rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 190 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The synthesis was carried out under exactly the same conditions as in Comparative Example 2 with the goal of 0.2% or less of the terminal ethyl group concentration that would not affect the urethanization reaction in NMR, but the terminal ethyl group concentration was the same as in Comparative Example 2. The reaction was continued for another 10 hours under the same conditions without falling below the target value. Although the terminal ethyl group concentration was 0.2% or more, the reaction was terminated, and a polycarbonate polyol liquid at room temperature was obtained. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 3.0 Number average molecular weight (Note): about 1673 (target: 2000)
Appearance: Room temperature transparent liquid Viscosity at 75 ° C .: 322 (mm 2 / s)
Hydroxyl value: 116.2 (mgKOH / g)
Acid value: 0.08 (mgKOH / g)
Moisture: 0.03 (%)
Number of colors: 20 (APHA No.)
Melting point: (not measured)
Terminal ethyl group concentration (%): 15.5 Terminal allyl group concentration (%): 0.08 (Note) The reason why the number average molecular weight is indicated as “about” is that there are many impurities that are not hydroxyl groups at the end. It is.
[0036]
The high-functional polycarbonate polyols obtained in Comparative Examples 2 and 3 were obtained by using TMP instead of triol alkylene oxide addition polymer, but were synthesized under the same atmospheric conditions as in Examples 1-6. As described above, the reaction did not proceed, and the reaction had to be stopped halfway. Therefore, many terminal alkyl groups (terminal ethyl groups in this embodiment) are present. As described above, the high-functional polycarbonate polyols obtained in Comparative Examples 2 and 3 have a large amount of impurities and cannot be said to be good.
[0037]
Comparative Example 4 46.0 parts of glycerin, 782 parts of 3-MPD, 782 parts of DEC, and 0.05 part of tetrabutyl titanate as a reaction catalyst were charged in the same reactor as in Example 1 under a nitrogen stream. Ethyl alcohol was distilled off while maintaining the reaction product in a temperature range of 125 ° C to 135 ° C. When it was confirmed that the distillation of ethyl alcohol reached the range of 30 to 40% by mass of the theoretical production amount, the temperature was raised to 190 ° C. at a rate of 4 to 10 ° C./hour. After completion of the temperature increase, the reaction was continued until the distillation of ethyl alcohol ceased while maintaining the reaction temperature at 190 ° C. Thereafter, decompression was started to remove low boilers. Depressurization was performed at a vacuum rate of 6.6 to 13.2 kPa / hr while maintaining the reaction temperature at 190 ° C., and the reaction was finally continued at a pressure of 1.3 kPa for 5 hours. The synthesis was performed with the target of 0.2% or less, which would not affect the urethane reaction, by NMR, but the terminal ethyl group concentration did not fall below the target value, and the reaction was continued for another 10 hours under the same conditions. Continued. Although the terminal ethyl group concentration was 0.2% or more, the reaction was terminated, and a polycarbonate polyol liquid at room temperature was obtained. The property of the obtained polycarbonate polyol is shown below.
Average number of hydroxyl groups in one molecule: 3.0 Number average molecular weight (Note): about 1731 (target: 2000)
Appearance: Normal temperature transparent liquid Viscosity at 75 ° C .: 372 (mm 2 / s)
Hydroxyl value: 110.2 (mgKOH / g)
Acid value: 0.08 (mgKOH / g)
Moisture: 0.03 (%)
Number of colors: 30 (APHA No.)
Melting point: (not measured)
Terminal ethyl group concentration (%): 13.3 Terminal allyl group concentration (%): 0.07 (Note) The reason why the number average molecular weight is indicated as “about” is that there are many impurities that are not hydroxyl groups at the end. It is.
[0038]
The high-functional polycarbonate polyol obtained in Comparative Example 4 uses glycerin instead of triol alkylene oxide addition polymer, and in the same atmospheric conditions as in Examples 1 to 6 as in Comparative Examples 2 and 3. However, the reaction did not proceed as described above, and the reaction had to be stopped midway. Therefore, many terminal alkyl groups (terminal ethyl groups in this embodiment) are present. Thus, the highly functional polycarbonate polyol obtained in Comparative Example 4 has a large amount of impurities and cannot be said to be good.
[0039]
【The invention's effect】
The highly functional polycarbonate polyol obtained in the present invention is (A) as a raw material.GlycerinAn alkylene oxide addition polymer of (B)3-methyl-1,5-pentanediol,(C) Diethyl carbonateBy selecting, it can be obtained under milder reaction conditions than before, and at the same time, the production cost for this can be suppressed. Moreover, the highly functional polycarbonate polyol obtained in the present invention is non-crystalline at room temperature, and further, there are few impurities such as terminal alkyl groups and allyl group terminal compounds.
[0040]
Since the highly functional polycarbonate polyol obtained in the present invention has few impurities such as a terminal alkyl group and an allyl group terminal compound, for example, a polyurethane resin reacted with an isocyanate compound as a raw material has excellent weather resistance, heat resistance, This is useful in that it can be provided with water resistance, mechanical strength, crosslinkability and the like. Therefore, it can be widely used in various industrial applications such as rigid foams, flexible foams, paints, adhesives, coating agents, elastomers, fibers, binders for magnetic tapes, various sealing materials, which are main uses of polyurethane resins. It can also be used as a modifier or a raw material for urethane acrylate resin to impart toughness and workability to polyester resin, polycarbonate resin, polyvinyl chloride resin, acrylonitrile-styrene resin, epoxy resin, etc. Useful.

Claims (3)

In the method for producing a highly functional polycarbonate polyol obtained by the transesterification reaction, as a raw material composition for obtaining a highly functional polycarbonate polyol,
(A) alkylene oxide addition polymer of glycerin ,
(B) 3-methyl-1,5-pentanediol ,
(C) diethyl carbonate ,
Is characterized by using
A method for producing a highly functional polycarbonate polyol having a terminal ethyl group concentration of 0.12% or less and a terminal allyl group concentration of 0.08% or less. The method for producing a highly functional polycarbonate polyol according to claim 1, wherein the alkylene oxide addition polymer of glycerin of (A) in claim 1 is an ethylene oxide addition polymer. The method for producing a highly functional polycarbonate polyol according to claim 1 or 2 , wherein the average number of hydroxyl groups in one molecule is 2.1 to 3.5.