GLYCIDYL ESTERS OF ALPHA, ALPHA BRANCHED ACIDS COMPOSITIONS

Information

  • Patent Application
  • 20190119510
  • Publication Number
    20190119510
  • Date Filed
    October 23, 2017
    7 years ago
  • Date Published
    April 25, 2019
    5 years ago
Abstract
The invention relates to compositions of α,α-branched alkane carboxylic acids glycidyl esters with a defined isomeric composition where the sum of the concentration of the blocked and of the highly branched isomers is maximum 55% preferably below 40%, and most preferably below 30%.
Description

The present invention relates to a composition of α,α-branched alkane carboxylic acids glycidyl esters with a defined isomeric composition; which can lead for example to improved leveling of the coatings derived thereof.


More in particular the invention relates to the compositions of aliphatic tertiary saturated carboxylic acids or α,α-branched alkane carboxylic acids, which contain 9 or 13 carbon atoms and which provide glycidyl esters with a branching level of the alkyl groups depending on the olefin feedstock used and/or the oligomerisation process thereof, and which is defined as below.


It is generally known from e.g. U.S. Pat. Nos. 2,831,877, 2,876,241, 3,053,869, 2,967,873 and 3,061,621 that mixtures of α,α-branched alkane carboxylic acids can be produced, starting from mono-olefins, carbon monoxide and water, in the presence of a strong acid.


One of the more recent method has been disclosed in EP 1033360A1. The problem of providing better softening derivatives of α,α-branched acids, manufactured from alkenes, carbon monoxide and water and a nickel catalyst was solved therein by a process, which actually comprised:

    • (a) oligomerisation of butene;
    • (b) separation of butene dimers and/or trimers from the oligomerisate;
    • (c) conversion of the butene dimers and/or trimers into carboxylic acids;
    • (d) conversion of the carboxylic acids into the corresponding vinyl esters showing attractive softening properties when mixed into other polymers or if used as comonomers in coatings.


If the olefin feed is based on Raf. II or Raf III or any mixture rich in n-butene isomers on the total olefins, the subsequently mixture of neo-acid (C9 or C13 acids) derivatives will provide a mixture where the concentration of blocked and highly branched isomers is maximum 55%, preferably below 40%, and most preferably below 30%.


The glycidyl esters can be obtained according to PCT/EP2010/003334 or the U.S. Pat. No. 6,433,217.


We have discovered that well chosen blend of isomers of the glycidyl ester of mixture compositions of neo-acid (C9 or C13 acids) glycidyl ester, is providing for example a good leveling of a coating, is a mixture where the sum of the concentration of blocked and highly branched isomers is maximum 55%, preferably below 40%, and most preferably below 30% weight on total composition.


We have further discovered that well chosen blend of isomers of the glycidyl ester of, for example, neononanoic acids give different and unexpected performance in combination with some particular polymers such as polyester polyols.


The isomers are described in Table 1 and illustrated in FIG. 1.


We have found that the performance of the glycidyl ester compositions derived from the branched acid is depending on the branching level of the alkyl groups R1, R2 and R3, for example the neononanoic acid has 3, 4 or 5 methyl groups. Highly branched isomers are defined as isomers of neo-acids having at least 5 methyl groups.


Mixture compositions of neononanoic (C9) acids glycidyl esters providing for example a good leveling of a coating, is a mixture where the sum of the concentration of the blocked and of the highly branched isomers derivatives is maximum 55%, preferably below 40%, and most preferably below 30% weight on total composition.


Furthermore the above compositions of neononanoic acids glycidyl esters mixture is comprising 2,2-dimethyl heptanoic acid glycidyl ester and 2-methyl 2-ethyl hexanoic acid glycidyl ester and 2-methyl 2 ethyl 3-methyl pentanoic acid glycidyl esters.


The above compositions of the glycidyl ester mixture is comprising 2,2-dimethyl heptanoic acid glycidyl ester in 4 to 10 weight % and 2-methyl 2-ethyl hexanoic acid glycidyl ester in 40 to 70 weight % and 2-methyl 2-ethyl 3-methyl pentanoic acid glycidyl esters (the sum of the stereoisomers) in 10 to 25 weight % on total composition.


A preferred composition is comprising a mixture of 2,2-dimethyl heptanoic acid glycidyl ester in 5 to 10 weight % and 2-methyl 2-ethyl hexanoic acid glycidyl ester in 45 to 65 weight % and 2-methyl 2-ethyl 3-methyl pentanoic acid glycidyl esters (the sum of the stereoisomers) in 12 to 22 weight % on total composition.


A further preferred composition is comprising a mixture of 2,2-dimethyl heptanoic acid glycidyl ester in 6 to 9 weight % and 2 methyl 2 ethyl hexanoic acid glycidyl ester in 47 to 61 weight % and 2-methyl 2-ethyl 3-methyl pentanoic acid glycidyl esters (the sum of the stereoisomers) in 14 to 21 weight % on total composition.


The above glycidyl esters compositions can be used for example, as reactive diluent or as momomer in binder compositions for paints or adhesives.


The glycidyl esters compositions can be used as reactive diluent for epoxy based formulations such as examplified in the technical brochure of Hexion (Product Bulletin: Cardura N10 The Unique Reactive Diluent).


Other uses of the glycidyl ester are the combinations with polyester polyols, or acrylic polyols, or polyether polyols. The combination with polyester polyols such as the one used in the car industry coating leads to coating system with attractive coating appearance.


Methods Used

The isomer distribution of neo-acid can be determined using gas chromatography, using a flame ionization detector (FID). 0.5 ml sample is diluted in analytical grade dichloromethane and n-octanol may be used as internal standard. The conditions presented below result in the approximate retention times given in Table 1. In that case n-octanol has a retention time of approximately 8.21 minute.


The GC method has the following settings:

    • Column: CP Wax 58 CB (FFAP), 50 m×0.25 mm, df=0.2 μm
    • Oven program: 150° C. (1.5 min)-3.5° C./min-250° C. (5 min)=35 min
    • Carrier gas Helium
    • Flow 2.0 mL/min constant
    • Split flow 150 mL/min
    • Split ratio 1:75
    • Injector temp: 250° C.
    • Detector temp: 325° C.
    • Injection volume: 1 μL


CP Wax 58 CB is a Gas chromatography column available from Agilent Technologies.


The isomers of neononanoic acid as illustrative example have the structure (R1 R2 R3)—C—COOH where the three R groups are linear or branched alkyl groups having together a total of 7 carbon atoms.


The structures and the retention time, using the above method, of all theoretical possible neononanoic isomers are drawn in FIG. 1 and listed in Table 1.


The isomers content is calculated from the relative peak area of the chromatogram obtained assuming that the response factors of all isomers are the same.









TABLE 1







Structure of all possible neononanoic isomers



















Retention time



R1
R2
R3
Methyl groups
Blocking
[Minutes]

















V901
Methyl
Methyl
n-pentyl
3
No
8.90


V902
Methyl
Methyl
2-pentyl
4
Yes
9.18


V903
Methyl
Methyl
2-methyl butyl
4
No
8.6


V904
Methyl
Methyl
3-methyl butyl
4
No
8.08


V905
Methyl
Methyl
1,1-dimethyl propyl
5
Yes
10.21


V906
Methyl
Methyl
1,2-dimethy propyl
5
Yes
9.57


V907
Methyl
Methyl
2,2-dimethyl propyl
5
No
8.26


V908
Methyl
Methyl
3-pentyl
4
Yes
9.45


V909
Methyl
Ethyl
n-butyl
3
No
9.28


V910 K1
Methyl
Ethyl
s-butyl
4
Yes
9.74


V910 K2
Methyl
Ethyl
s-butyl
4
Yes
9.84


V911
Methyl
Ethyl
i-butyl
4
No
8.71


V912
Methyl
Ethyl
t-butyl
5
Yes
9.64


V913
Methyl
n-propyl
n-propyl
3
No
8.96


V914
Methyl
n-propyl
i-propyl
4
Yes
9.30


V915
Methyl
i-propyl
i-propyl
5
Yes
9.74


V916
Ethyl
Ethyl
n-propyl
3
No
9.44


V917
Ethyl
Ethyl
i-propyl
4
Yes
10.00









The isomer distribution of glycidyl esters of neo-acid can be determined by gas chromatography, using a flame ionization detector (FID). 0.5 ml sample is diluted in analytical grade dichloromethane.


The GC method has the following settings:

    • Column: CP Wax 58 CB (FFAP), 50 m×0.2 mm, df=0.52 μm
    • Oven: 175° C. (5 min)-1° C./min-190° C. (0 min)-10° C./min-275° C. (11.5 min)
    • Flow: 2.0 mL/min, constant flow
    • Carrier gas: Helium
    • Split ratio: 1:75
    • Injection volume: 1 μL
    • S/SL injector: 250° C.


CP Wax 58 CB is a Gas chromatography column available from Agilent Technologies.


The isomers of glycidyl esters of neononanoic acid as illustrative example have the structure (R1 R2 R3)—C—COO—CH2—CH(O)CH2 where the three R groups are linear or branched alkyl groups having together a total of 7 carbon atoms.


The isomers content is calculated from the relative peak area of the chromatogram obtained assuming that the response factors of all isomers are the same.


GC-MS method can be used to identify the various isomers providing that the analysis is done by a skilled analytical expert.


FIG. 1: Structure of all possible neononanoic isomers




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Test Methods for the Characterization of the Resins

The molecular weights of the resins are measured with gel permeation chromatography (Perkin Elmer/Water) in THF solution using polystyrene standards. Viscosity of the resins are measured with Brookfield viscometer (LVDV-I) at indicated temperature. Solids content are calculated with a function (Ww-Wd)/Ww×100%. Here Ww is the weight of a wet sample, Wd is the weight of the sample after dried in an oven at a temperature 110° C. for 1 hour.


Tg (glass transition temperature) has been determined either with a DSC 7 from Perkin Elmer or with an apparatus from TA Instruments Thermal Analysis. Scan rates were respectively 20 and 10° C./min. Only data obtained in the same experimental conditions have been compared. If not, the temperature difference occurring from the different scanning rate has been proved not significant for the results compared.


Methods for the Characterization of the Clear Coats
Pot-Life

Pot-life is determined by observing the elapsed time for doubling of the initial viscosity at room temperature, usually 24.0±0.5° C. The initial viscosity of the clear coat is defined at 44-46 mPa·s for Part 1 and 93-108 mPa·s for Part 3 measured with Brookfield viscometer.


Application of Clearcoat

Q-panels are used as substrates. Then the panels are cleaned by a fast evaporating solvent methyl ethyl ketone or acetone. For Part 1 the clearcoat is spray-applied on Q-panels covered with basecoat; for Parts 2 & 3 the clearcoat is barcoated directly on Q-panels.


Dust Free Time

The dust free time (DFT) of clear coat is evaluated by vertically dropping a cotton wool ball on a flat substrate from a defined distance. When the cotton ball contacts with the substrate, the substrate is immediately turned over. The dust free time is defined as the time interval at which the cotton wool ball no longer adhered to the substrate.


Hardness Development

Hardness development is followed using pendulum hardness tester with Koenig method.


Blocking Isomers

Whereas the carbon atom in alpha position of the carboxylic acid is always a quaternary carbon atom, the carbon atom(s) in β position can either be tertiary or quaternary. Neononanoic acids (V9) with a tertiary or a quaternary carbon atom in the β position are defined as blocking isomers (FIGS. 2 and 3).


FIG. 2: Example of a Non-blocked V9 Structure


FIG. 3: Example of a Blocked V9 Structure




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The use of the glycidyl esters compositions, discussed here above, is as reactive diluent or as momomer in binder compositions for paints and adhesives.


These uses can be based on a polyester polyol resin comprising the above composition glycidyl ester and/or an acrylic polyol resin comprising the above composition glycidyl ester and/or a polyether polyol resin comprising the above composition glycidyl ester and/or an epoxy resin formulation comprising the above composition glycidyl ester.







EXAMPLES
Chemicals Used





    • Cardura™ E10: available from Momentive Specialty Chemicals

    • Neononanoic glycidyl ester from Momentive Specialty Chemicals

    • GE9S: neononanoic glycidyl ester of composition A (see table 2 below)

    • GE9H: neononanoic glycidyl ester of composition B (see table 2 below)

    • Neononanoic glycidyl ester of composition C (see table 2 below)

    • Neononanoic glycidyl ester of composition D (see table 2 below)

    • Neononanoic glycidyl ester of composition E (see table 2 below) GE5: glycidyl ester of pivalic acid obtained by reaction of the acid with epichlorhydrin.

    • Ethylene glycol from Aldrich

    • Monopentaerythritol: available from Sigma-Aldrich

    • Methylhexahydrophtalic anhydride: available from Sigma-Aldrich

    • Boron trifluoride diethyl etherate (BF3.OEt2) from Aldrich

    • Acrylic acid: available from Sigma-Aldrich

    • Hydroxyethyl methacrylate: available from Sigma-Aldrich

    • Styrene: available from Sigma-Aldrich

    • 2-Ethylhexyl acrylate: available from Sigma-Aldrich

    • Methyl methacrylate: available from Sigma-Aldrich

    • Butyl acrylate: available from Sigma-Aldrich

    • Xylene

    • Di-t-Amyl Peroxide is Luperox DTA from Arkema

    • tert-Butyl peroxy-3,5,5-trimethylhexanoate: available from Akzo Nobel

    • n-Butyl Acetate from Aldrich

    • Dichloromethane from Biosolve

    • Thinner: A: is a mixture of Xylene 50 wt %, Toluene 30 wt %, ShellsolA 10 wt %, 2-Ethoxyethylacetate l0 wt %. Thinner B: is butyl acetate

    • Curing agents, HDI: 1,6-hexamethylene diisocyanate trimer, Desmodur N3390 BA from Bayer Material Science or Tolonate HDT LV2 from Perstorp

    • Leveling agent: ‘BYK 10 wt %’ which is BYK-331 diluted at 10% in butyl acetate

    • Catalyst: ‘DBTDL 1 wt %’ which is Dibutyl Tin Dilaurate diluted at 1 wt % in butyl acetate












TABLE 2







Composition of the neononanoic glycidyl ester (according to the


described gas chromatography method for glycidyl esters of neo-acid)












Glycidyl ester







of acid V9XX


(described in


Table 1)
A (%)
B (%)
C (%)
D (%)
E (%)















V901
6.5
0.1
3.7
0.1
8.9


V902
0.6
2.55
0.6
2.4
0.7


V903
1.1
0.7
0.3
1.0
2.0


V904
0.8
1
0.1
2.2
1.8


V905
0.2
13.1
0.5
4.1
0.1


V906
0.4
11.6
0.4
9.6
0.4


V907
0.2
15.4
0.1
36.4
0.6


V908
0.1
0
0.1
0.0
0.1


V909
54.8
2.55
52.8
2.4
52.8


V910 K1
7.8
0
10.0
0.0
6.5


V910 K2
7.7
0.6
12.8
0.4
4.8


V911
2.4
1.2
0.7
2.0
4.2


V912
0.0
28.3
0.0
22.4
0.0


V913
6.8
0.1
6.4
0.1
6.5


V914
4.5
0
3.8
0.0
5.7


V915
0.6
22.3
0.6
16.8
0.4


V916
4.4
0.1
5.2
0.1
3.8


V917
1.1
0.4
2.1
0.1
0.5









Example 1

The following constituents were charged to a reaction vessel equipped with a stirrer, a condenser and a thermometer: 92.4 grams of GE9S, 24.0 grams of Butyl Acetate. That initial reactor charge has been heated up to 135° C. Then, the following mixture was added over a period of 1 h20 while keeping the temperature constant: 30.7 grams of acrylic acid, 1.2 grams of Di-t-Amyl Peroxide, 12.0 grams of n-Butyl Acetate. After further adding 1.2 grams of Di-t-Amyl Peroxide and 20.4 grams of n-Butyl Acetate, a post-cooking was pursued at 135° C. for 1 h. The acrylic polyol had a molecular weight (Mw) of 11400 Daltons and a Tg of about −10° C.


Example 2 Comparative

The following constituents were charged to a reaction vessel equipped with a stirrer, a condenser and a thermometer: 92.4 grams of GE9H, 24.0 grams of Butyl Acetate. That initial reactor charge has been heated up to 135° C. Then, the following mixture was added over a period of 1 h18 while keeping the temperature constant: 30.2 grams of acrylic acid, 1.2 grams of Di-t-Amyl Peroxide, 12.0 grams of n-Butyl Acetate. After further adding 1.2 grams of Di-t-Amyl Peroxide and 20.4 grams of n-Butyl Acetate, a post-cooking was pursued at 135° C. for 1 h. The acrylic polyol had a molecular weight (Mw) of 8600 Daltons and a Tg of about +26° C.


Observations: Tg of acrylic polyols is impacted by the composition of the neononanoic glycidyl ester (see examples 1, 2).


Example 3
The Adducts of Glycidyl Neononanoate, GE9S and Acrylic Acid or Methacrylic Acid

The adducts of Glycidyl neononanoate GE9S (see table 3) with acrylic acid (ACE-adduct) and with methacrylic acid (MACE-adduct) are acrylic monomers that can be used to formulate hydroxyl functional (meth)acrylic polymers.









TABLE 3







Compositions of the adducts intakes in parts by weight











Meth acrylic



Acrylic acid adduct
acid adduct













Initial reactor charge




GE9S
250
250


Acrylic acid
80


Methacrylic acid

96.5


Radical Inhibitor


4-Methoxy phenol
0.463
0.463


Catalyst


DABCO T9 (0.07 wt % on
0.175
0.175


Glycidyl ester)











    • DABCO T9 and 4-Methoxy phenol (185 ppm calculated on glycidyl ester weight), are charged to the reactor.

    • The reaction is performed under air flow (in order to recycle the radical inhibitor).

    • The reactor charge is heated slowly under constant stirring to about 80° C., where an exothermic reaction starts, increasing the temperature to about 100° C.

    • The temperature of 100° C. is maintained, until an Epoxy Group Content below 30 meq/kg is reached. The reaction mixture is cooled to room temperature.





Example 4
Acrylic Resins for High Solids Automotive Refinish Clearcoats

A glass reactor equipped with stirrer was flushed with nitrogen, and the initial reactor charge (see table 4) heated to 160° C. The monomer mixture including the initiator was then gradually added to the reactor via a pump over 4 hours at this temperature. Additional initiator was then fed into the reactor during another period of 1 hour at 160° C. Finally the polymer is cooled down to 135° C. and diluted to a solids content of about 68% with xylene.









TABLE 4







Acrylic resins recipe










Weight %
in Reactor 1 L (g)















Initial Reactor Charge





GE9S (or GE9H comparative)
28.2
169.1



Xylene
2.7
16.2



Feeding materials



Acrylic acid
10
59.8



Hydroxy ethyl methacrylate
16.0
96.0



Styrene
30.0
180.0



Methyl methacrylate
15.8
95.0



Di t-Amyl peroxide
4.0
24.0



Xylene
8.3
49.8



Post cooking



Di t-Amyl peroxide
1.0
6.0



Xylene
3.0
18.0



Solvent adding at 130° C.



Xylene
50.8
305.0



Final solids content
61.8%



Hydroxyl content
4.12%










Example 5
Clear Coats for Automotive Refinish

Solvents were blended to yield a thinner mixture of the following composition (table 5):









TABLE 5







Thinner composition










Thinner
Weight % in solvent blend, theory







Toluene
30.1%



ShellSolA
34.9%



2-ethoxyethyl acetate
10.0%



n-Butyl acetate
25.0%



Total
 100%











A clearcoat was then formulated (table 6) with the following ingredients (parts by weight):









TABLE 6







Clearcoat formulation











Resin of
Desmodur
BYK 10 wt % in
DBTDL 1 wt %



example ex 4
N3390
ButAc
in ButAc
Thinner





80.1
27.01
0.53
1.17
40.45





















Clearcoat properties
GE9H (comparative)
GE9S



















Volatile organic content
480
g/l
481
g/l


Initial viscosity
54
cP
54
cP


Dust free time
12
minutes
14.5
minutes


Koenig Hardness after 6 h
8.3
s
7.1
s









Example 6
Acrylic Resins for First Finish Automotive Topcoats
GE9S Based (28%) Acrylic Polymers for Medium Solids First-Finish Clear Coats

A reactor for acrylic polyols is flushed with nitrogen and the initial reactor charge (see table 7) heated to 140° C. At this temperature the monomer mixture including the initiator is added over 4 hours to the reactor via a pump. Additional initiator is fed into the reactor during one hour, and then the mixture is kept at 140° C. to complete the conversion in a post reaction. Finally the polymer is cooled down and diluted with butyl acetate to a solids content of about 60%.









TABLE 7







Acrylic resins recipe









Intakes (parts by weight)














Initial reactor charge




GE9S
164.40



Xylene
147.84



Monomer mixture



Acrylic acid
53.11



Butyl methacrylate
76.88



Butyl acrylate
48.82



Hydroxy-ethyl methacrylate
27.20



Styrene
177.41



Methyl methacrylate
47.31



Initiator



Di-tert.-amyl peroxide (DTAP)
8.87



Post addition



Di-tert.-amyl peroxide
5.91



Solvent (to dilute to 60% solids)



Butyl acetate
246.00



Total
1000.0










Clear Lacquer Formulation

Clear lacquers are formulated (see table 8) from the acrylic polymers by addition of Cymel 1158 (curing agent from CYTEC), and solvent to dilute to spray viscosity. The acidity of the polymer is sufficient to catalyze the curing process, therefore no additional acid catalyst is added. The lacquer is stirred well to obtain a homogeneous composition.









TABLE 8







Clear lacquer formulations and properties of the polymers









Intakes



(part by weight)














Ingredients




Acrylic polymer
60.0



Cymel 1158
8.8



Butyl acetate (to application
24.1



viscosity)



Properties



Solids content [% m/m]
45.3



Density [g/ml]
0.97



VOC [g/l]
531










Application and Cure

The coatings are applied with a barcoater on Q-panels to achieve a dry film thickness of about 40 μm. The systems are flashed-off at room temperature for 15 minutes, then baked at 140° C. for 30 minutes. Tests on the cured systems are carried out after 1 day at 23° C.


Example 7

In a reactor equipped with an anchor stirrer, a thermometer, condenser and monomer/initiator feeding system, 188.6 g of GE9S and 90 g of ethoxypropanol (EPR) were loaded and heated to about 150° C. (see table 9). A mixture of 52 g of hydroxyethylmethacrylate (HEMA), 160 g of styrene, 68 g of acrylic acid (AA), 10 g of dicumylperoxide (DCP), 37.7 g of GE9S and 40 g of ethoxypropanol (EPR) were added over 2 hours 30 minutes to the reactor while keeping its content at 150° C. After the feed, the reactor content was held for 30 minutes at this temperature. After the 30 minutes hold period, 108 g of HEMA, 30 g of AA, 142 g of isobutyl methacrylate (IBMA), 5 g of DCP and 45 grams of EPR were added over 2 hours and 30 minutes at about 150° C. followed by a rinsing step for the feed system with 5 g of EPR. After the rinsing step, the content of the reactor was held for 2 hours at 150° C. The reactor content was cooled down to 100° C. and 100 parts of EPR were distilled off at atmospheric pressure.


The polyacrylate polyol has a solids content of the solution of 90% by weight.









TABLE 9







Composition of polyol










Materials
Intake (g)















Initial charge

EPR

90




GE9S
188.6



Monomer Addition 1
AA
68




Styrene
160




GE9S
37.7





HEMA

52




EPR
40




DCP
10



Monomer Addition 2
AA
30





IBMA

142




HEMA
108




DCP
5




EPR
45



TOTAL

976.3










Example 8

The following constituents were charged to a reaction vessel: 0.7153 grams of a neononanoic glycidyl ester of composition C, 0.5958 grams of hexahydro-4-methylphthalic anhydride, 0.0014 grams of ethylene glycol. The reaction took place for 3 to 4 days at 140° C. The sample has been dried by evaporation. The polyester had a molecular weight (Mn) of 4700 Daltons and a Tg of +18.8° C.


Example 9 Comparative

The following constituents were charged to a reaction vessel: 0.5823 grams of a neononanoic glycidyl ester of composition D, 0.4775 grams of hexahydro-4-methylphthalic anhydride, 0.0011 grams of ethylene glycol, 0.2841 grams of n-Butyl Acetate. The reaction took place for 3 to 4 days at 120-140° C. and the solvent was then thoroughly removed by evaporation. The polyester had a molecular weight (Mn) of 5000 Daltons and a Tg of +43.7° C.


Example 10

The following constituents were charged to a reaction vessel: 0.7235 grams of a neononanoic glycidyl ester of composition E, 0.5981 grams of hexahydro-4-methylphthalic anhydride, 0.0014 grams of ethylene glycol. The reaction took place for 3 to 4 days at 140° C. The sample has been dried by evaporation. The polyester had a molecular weight (Mn) of 5700 Daltons and a Tg of +17.6° C.


Observations:


Tg of polyesters is impacted by the composition of the neononanoic glycidyl ester (see examples 8, 9, 10).


The resins of the examples can be formulated in coating compositions such as 2K (polyurethane) with a low VOC (volatile organic compound) level and still providing and excellent appearance.


Example 11
Monopentaerythritol/Methylhexahydrophtalic Anhydride/GE9S (1/3/3 Molar Ratio)=CE-GE9S

80.4 g amount of butylacetate, 68.3 g of monopentaerythritol, 258.2 g of methylhexahydrophthalic anhydride are loaded in a glass reactor and heated to reflux until complete dissolution. Afterwards, the temperature is decreased down to 120° C. and 333.0 g of GE9S are added over about one hour. The cooking is pursued at 120° C. for the time needed to decrease epoxy group content and acid value down to an acid value below 15 mg KOH/g. Then, further 82.4 g of butylacetate are added. Test results are indicated in table 10.


Example 12 Comparative
Monopentaerythritol/Methylhexahydrophtalic Anhydride/GE9H (1/3/3 Molar Ratio)=CE-GE9Ha

80.4 g amount of butylacetate, 68.3 g of monopentaerythritol, 258.2 g of methylhexahydrophthalic anhydride are loaded in a glass reactor and heated to reflux until complete dissolution. Afterwards, the temperature is decreased down to 120° C. and 337.1 g of GE9H are added over about one hour. The cooking is pursued at 120° C. for the time needed to decrease epoxy group content and acid value down to an acid value below 15 mg KOH/g. Then, further 83.4 g of butylacetate are added. Test results are indicated in table 10.









TABLE 10







Polyesters characterization












Polyester
SC



Viscosity


resin
(%)
Mw (Da)
Mn (Da)
Mw/Mn (PDI)
(cP)















CE-GE9S
78.6
974
919
1.06
2450


CE-GE9Ha
80.0
921
877
1.05
6220





SC: solids content






Formulation of the Clear Coats

The clearcoat has been formulated as follows: CE-GEx polyester with Tolonate HDT LV2 as hardener (0.03 wt % DBTDL)(see table 11).









TABLE 11







Clear coats, formulations
















DBTDL




Binder 2
HDI
BYK 10 wt %
1 wt %
Thinner B


CE-GEx
(g)
(g)
(g)
(g)
(g)















GE9S
80.0
36.56
0.72
3.15
89.75


GE9Ha
80.4
37.27
0.73
3.20
87.83









Characterization of the Clear Coats

The clearcoat formulations are barcoat applied on degreased Q-panel. The panels are dried at room temperature, optionally with a preliminary stoving at 60° C. for 30 min. Results are indicated in table 12.









TABLE 12







Clear coats, performances











Drying
DFT (min)
Koenig Hardness (s)













CE-GEx
SC (%)
conditions
Cotton Balls
6 h
24 h
7 d
















GE9S
48.4
RT
223
3
17
159


GE9Ha
49.2
RT
91
3
36
212


GE9S
48.4
Stoving 30
Dust
4
44
174




min/60° C.
free out





of oven


GE9Ha
49.2
Stoving 30
Dust
10
55
211




min/60° C.
free out





of oven









Example 13 Comparative

The following constituents were charged to a reaction vessel: 2.5500 grams of a neononanoic glycidyl ester of composition D, 1.1571 grams of dichloromethane, 0.0137 grams of boron trifluoride diethyl etherate. The reaction took place for 3 days at room temperature and the solvent was then thoroughly removed by evaporation. The polyether had a molecular weight (Mw) of 1900 Daltons and a Tg of −40.5° C.


Example 14

The following constituents were charged to a reaction vessel: 2.5438 grams of a neononanoic glycidyl ester of composition C, 1.0150 grams of dichloromethane, 0.0128 grams of boron trifluoride diethyl etherate. The reaction took place for 3 days at room temperature and the solvent was then thoroughly removed by evaporation. The polyether had a molecular weight (Mw) of 1500 Daltons and a Tg of −51.1° C.


Observations:


Tg of the modified polyether resin is impacted by the composition of the neononanoic glycidyl ester (see examples 13, 14).


Example 15
Polyether Resin

The following constituents were charged to a reaction vessel equipped with a stirrer, a thermometer and a condenser: 134 grams of di-Trimethylol propane (DTMP), 900 grams of glycidyl neononanoate, GE9S, 135.5 grams of n-butylacetate (BAC) and 2.5 grams of Tin 2 Octoate. The mixture was heated to its reflux temperature of about 180° C. for about 4 hours till the glycidyl neononaoate was converted to an epoxy group content of less than 0.12 mg/g. After cooling down the polyether had a solids content of about 88%.


Example 16 Comparative
Polyether Resin

The following constituents were charged to a reaction vessel equipped with a stirrer, a thermometer and a condenser: 28.8 grams of monopentaerythritol, 201.5 grams of Cardura E10P, 19.4 grams of n-butylacetate and 0.3552 grams of Tin (II) 2-ethylhexanoate. The mixture was heated to a temperature of about 180° C. for about 6 hours till the Cardura E10P was converted to an epoxy group content of about 25 mmol/kg. After cooling down the polyether had a solids content of about 94%.


Example 17
Polyether Resin

The following constituents were charged to a reaction vessel equipped with a stirrer, a thermometer and a condenser: 28.8 grams of monopentaerythritol, 187.1 grams of GE9S, 18.3 grams of n-butylacetate and 0.3550 grams of Tin (II) 2-ethylhexanoate. The mixture was heated to a temperature of about 180° C. for about 5.5 hours till the GE9S was converted to an epoxy group content of about 29 mmol/kg. After cooling down the polyether had a solids content of about 95%.


Example 18 Comparative
Polyether Resin

The following constituents were charged to a reaction vessel equipped with a stirrer, a thermometer and a condenser: 28.8 grams of monopentaerythritol, 189.4 grams of GE9H, 18.5 grams of n-butylacetate and 0.3572 grams of Tin (II) 2-ethylhexanoate. The mixture was heated to a temperature of about 180° C. for about 4 hours till the GE9H was converted to an epoxy group content of about 27 mmol/kg. After cooling down the polyether had a solids content of about 95%.


Formulation of the Clear Coats

A clear coat is formulated with one of the polyether (from examples 16, 17, or 18, the curing agent (HDI, Desmodur N3390), the thinner (Methyl Amyl Ketone), the levelling agent (BYK-331) and the catalyst (dibutyltin dilaurate, DBTDL) according to the amounts indicated in table 13.









TABLE 13







Clear coats, formulations

















BYK 10
DBTDL



CEP-
Binder
Binder
HDI
wt %
1 wt %
Thinner


Example
(ID)
(g)
(g)
(g)
(g)
(g)
















CEP-16
From
40.1
30.7
0.47
1.03
15.1



Example 16


CEP-17
From
40.0
33.0
0.48
1.07
>12.5



Example 17


CEP-18
From
40.0
32.5
0.48
1.06
17.7



Example 18









Characterization of the Clear Coats

The clearcoat formulations (from table 13) are barcoat applied on degreased Q-panel, optionally on basecoated Q-panel. The panels are dried at room temperature after a preliminary stoving at 60° C. for 30 min. Clear coats have been characterized among others by measuring the Koenig hardness development (see table 14).









TABLE 14







Clear coats, drying (curing) properties











CEP-16
CEP-17
CEP-18











1°/Koenig Hardness (Degreased Q panels) (sec)












 6 hours
8
10
11



24 hours
10
11
47



 7 days
18
20
94







2°/Koenig Hardness (Basecoated Q panels) (sec)












 6 hours
7
8
7



24 hours
8
8
14



 7 days
12
13
34










Example 19
Preparation for Vacuum Infusion of Composite Structures

A. resin for vacuum infusion of large structures such as yacht and wind turbines was prepared by mixing 27.7 part by weight of curing agent blend and 100 part of epoxy resins blend described here:


Epoxy resins blend: 850 part by weight Epikote 828 and 150 part of glycidyl neononanoate, GE9S.


Curing Agent blend: 650 part by weight of Jeffamine D230 and 350 part by weight of Isophorone diamine (IPDA).


Jeffamine D230 is a polyoxyalkyleneamines available from Huntsman Corporation. Epikote 828 is an epoxy resin available from Momentive Specialty Chemicals


Example 20
Example of Trowellable Floor and Patching Compound

The ingredients presented in the table 15 below were mixed for the preparation of a trowellable flooring compound









TABLE 15







Preparation of a trowellable flooring compound











Weight





(parts)
Volume (parts)
Supplier














BASE





COMPONENT


EPIKOTE
63.2
126.3
Momentive


828LVEL
11.1
22.3


GE9S


Byk A530
4.8
13.4
Byk Chemie







Mix the additives into the EPIKOTE resin before filler addition










Total
79.1
162.0



FILLERS


Sand 1-2 mm
582.3
496.4
SCR Sibelco


Sand 0.2-0.6 mm
298.4
254.4
SCR Sibelco


Total
880.7
750.8







Disperse into the base component using a concrete mixer










CURING AGENT





COMPONENT


EPIKURE F205
40.2
87.2
Momentive


Total
40.2
87.2







Mix the curing agent well with the EPIKOTE resin base


and Fillers before application










Total formulation
1000.0
1000.0









Example 21
Formulation for a Water Based Self-Leveling Flooring

The ingredients presented in the table 16 below were mixed for the preparation of a waterbased self leveling flooring system.









TABLE 16







Preparation of a waterbased self leveling flooring system











Weight





(parts)
Supplier
Comment














CURING AGENT





COMPONENT (A)


EPIKURE 8545-W-52
164.00
Momentive


(HEW = 320 g/eq)


EPIKURE 3253
4.00
Momentive
Accelerator


BYK 045
5.00
BYK CHEMIE
defoamer


Antiterra 250
4.00
BYK CHEMIE
Dispersing


Byketol WS
5.00
BYK CHEMIE
Wetting agent


Bentone EW (3% in water)
20.00
Elementis
Anti-settling







Mix the additive into the EPIKURE curing agents before filler addition










Titanium dioxide 2056
50.00
KronosTitan








Disperse the pigment for 10 minutes at 2000 rpm.










EWO-Heavy Spar
195.00
Sachtleben
Barium sulphate




Chemie


Quartz powder W8
98.00
Westdeutsche




Quarzwerke







Disperse fillers at 2000 rpm for 10 minutes










Water
55.00




Sand 0.1-0.4 mm
400.00
Euroquarz


Total component A
1000.00


RESIN COMPONENT (B)


EPIKOTE 828LVEL
81.00
Momentive


GE9S
19.00







Mix (B) into (A)









Total formulation A + B
1081.00



















Formulation characteristics



















Fillers + Pigment/Binder ratio
3.9
by weight



PVC
37.7
% v/v



Density
1.9
g/ml



Water content
12.5
% m/m









Claims
  • 1. A composition of α,α-branched alkane carboxylic glycidyl esters from butene oligomers, comprising a glycidyl ester mixture of neo-acid derived from a dimer (C9) or trimer (C13) of butene having both blocked isomers and highly branched isomers wherein a sum of a concentration of blocked isomers and the concentration of highly branched isomers of the glycidyl ester mixture is 55% weight or less based on the weight of the composition, wherein the glycidyl ester mixture comprises 2,2-dimethyl heptanoic acid glycidyl ester in 4 to 10 weight %, 2-methyl 2-ethyl hexanoic acid glycidyl ester in 40 to 70 weight % and 2-methyl 2-ethyl 3-methyl pentanoic acid glycidyl esters (sum of stereoisomers) in 10 to 25 weight % based on the weight of the composition.
  • 2. A binder composition for paints or adhesives comprising the composition of claim 1 as a reactive diluent or as monomer.
  • 3. A resin comprising the composition of claim 1 wherein the resin is selected from the group consisting of a polyester polyol resin, an acrylic polyol resin, a polyether polyol resin or an epoxy resin.
  • 4. A composition of α,α-branched alkane carboxylic glycidyl esters from butene oligomers, comprising a glycidyl ester mixture of neo-acid derived from a dimer (C9) or trimer (C13) of butene having both blocked isomers and highly branched isomers wherein a sum of a concentration of blocked isomers and the concentration of highly branched isomers of the glycidyl ester mixture is 55% weight or less based on the weight of the composition, wherein the glycidyl ester mixture comprises 2,2-dimethyl heptanoic acid glycidyl ester in 5 to 10 weight %, 2-methyl 2-ethyl hexanoic acid glycidyl ester in 45 to 65 weight % and 2-methyl 2-ethyl 3-methyl pentanoic acid glycidyl esters (sum of stereoisomers) in 12 to 22 weight % based on the weight of the composition.
  • 5. A binder composition for paints or adhesives comprising the composition of claim 4 as a reactive diluent or as monomer.
  • 6. A resin comprising the composition of claim 4 wherein the resin is selected from the group consisting of a polyester polyol resin, an acrylic polyol resin, a polyether polyol resin or an epoxy resin.
  • 7. A composition of α,α-branched alkane carboxylic glycidyl esters from butene oligomers, comprising a glycidyl ester mixture of neo-acid derived from a dimer (C9) or trimer (C13) of butene having both blocked isomers and highly branched isomers wherein a sum of a concentration of blocked isomers and the concentration of highly branched isomers of the glycidyl ester mixture is 55% weight or less based on the weight of the composition, wherein the glycidyl ester mixture comprises 2,2-dimethyl heptanoic acid glycidyl ester in 6 to 9 weight %, 2-methyl 2-ethyl hexanoic acid glycidyl ester in 47 to 61 weight % and 2-methyl 2-ethyl 3-methyl pentanoic acid glycidyl esters (sum of stereoisomers) in 14 to 21 weight % based on the weight of the composition.
  • 8. A binder composition for paints or adhesives comprising the composition of claim 7 as a reactive diluent or as monomer.
  • 9. A resin comprising the composition of claim 7 wherein the resin is selected from the group consisting of a polyester polyol resin, an acrylic polyol resin, a polyether polyol resin or an epoxy resin.
Parent Case Info

This application is a continuation application of co-pending U.S. patent application Ser. No. 13/997,413, filed Aug. 9, 2013, which application claims benefit to PCT Application No. PCT/EP2011/006580, filed Dec. 16, 2011, which claims benefit to European Patent Application No. 10015959.9, filed Dec. 22, 2010, of which the entire contents of all applications are incorporated by reference herein.