WINNE JOHAN (BE)
DU PREZ FILIP (BE)
WO2021105127A1 | 2021-06-03 |
EP0654465A1 | 1995-05-24 | |||
CN113461908A | 2021-10-01 | |||
EP1024159A1 | 2000-08-02 |
LEIBLERAND, SCIENCE, vol. 334, no. 6058, 2011, pages 965 - 968
DU PREZ, MACROMOLECULES, vol. 53, no. 7, 2020, pages 2485 - 2495
ODRIOZOLA, MATER. HORIZONS, vol. 3, no. 3, 2016, pages 241 - 247
WU, CHEMICAL ENGINEERING JOURNAL, vol. 368, 2019, pages 61 - 70
Claims 1. A method for preparing a composition comprising an epoxy-based covalent adaptable network comprising the steps of a) contacting at least one compound A with at least one compound B, hereby obtaining a mixture comprising a curing agent, with the at least one compound A having a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)-, with a’ being an integer equal or greater than 2 and with Rx for each functional group being independently selected from the group consisting of H and C1-C4 alkyls, with each of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- belonging to a pair of functional groups comprising a first functional group and a second functional group, whereby the number of atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group ranges between 2 and 8, and whereby in case the at least one compound A comprises a pair of functional groups having a functional group of the type –(C=O)- as first and as second functional group, the at least one compound A comprises a cyclic carboxylic acid anhydride with the first and the second functional groups belonging to the carboxylic acid functional group of the at least one compound A, and with the at least one compound B having b’ primary amine functional groups, with b’ being an integer equal or greater than 2, with each of the b’ primary amine functional groups belonging to a pair of functional groups comprising a first primary amine functional group and a second primary amine functional group, whereby the number of atoms between the first primary amine functional group and the second primary amine functional group is at least 5, each of the of b’ primary amine functional groups being directly connected to a primary carbon atom, wherein during step a) dynamic bonds are formed by reaction of at least part of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with at least part of the b’ primary amine functional groups, b) contacting the mixture obtained in step a) with at least one compound C, hereby obtaining an epoxy-derived covalent adaptable network, with the at least one compound C having c’ epoxide functional groups, with c’ being an integer equal or greater than 2, wherein during step b) permanent bonds are formed by reaction of at least part of the least c’ epoxide functional groups with an active hydrogen atom of a functional group capable of reacting with an epoxide functional group present in the mixture. wherein - ∑ nj b'j being equal or greater than ∑ ni a'i - the ratio ranging between 0.5 and 1.5, and - the ratio being equal or greater than 0.4 in case or the ratio being equal or greater than 0.4 in case x<∑ nk c'k with ni being the number of mmol of compound Ai with functionality a ′ i , nj being the number of mmol of compound Bj with functionality b ′ j , nk being the number of mmol of compound Ci with functionality c′ k, x being the total number of active hydrogen atoms of all functional groups capable of reacting with an epoxide functional group present at the start of step b). 2. The method according to claim 1, wherein the number of atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group of a pair of a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- is 2, 3 or 4. 3. The method according to any one of the preceding claims, wherein at least part of the atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group of a pair of functional groups of the type -C(=O)ORx and/or of the type -C(=O)- is part of cyclic structure, the cyclic structure optionally being substituted. 4. The method according to any one of the preceding claims, wherein the at least one compound A has a’ functional groups of the type -C(=O)ORx with each of the a’ functional groups of the type -C(=O)ORx belonging to a pair of functional groups comprising a first functional group and a second functional group. 5. The method according to any one of the preceding claims, wherein at least part of the atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group of a pair of functional groups of the type -C(=O)ORx comprises a linear saturated or unsaturated hydrocarbon, optionally one of the atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group being substituted. 6. The method according to any one of the preceding claims, wherein the first primary amine functional group and the second primary amine functional group of a pair of b’ primary amine functional groups are linked by a clinking moiety comprising or consisting of a group selected from the group consisting of C6-40alkyl, C6-24alkenyl, C6-40alkynyl, C6-24aryl, C6-24cycloalkyl, C6-24arylC1-40alkyl; wherein one or more of the carbon atoms in the backbone of the alkyl, alkenyl, alkynyl, aryl or cycloalkyl may be replaced by a heteroatom independently selected from O, S, N and Si and wherein the alkyl, alkenyl, alkynyl, aryl or cycloalkyl may be unsubstituted or further substituted. 7. The method according to any one of the preceding claims, wherein the functional group comprising at least one active hydrogen atom and being capable of reacting with an epoxide functional group is selected from the group consisting of primary amine functional groups, secondary amine functional groups, alcohol functional groups, thiol functional groups and -C(=O)OH functional groups. 8. The method according to any one of the preceding claims, wherein at least one compound E is present in step a), with the at least one compound E comprising e’ primary amine functional and not comprising a pair of b’ primary amine functional group, with e’ being an integer equal or greater than 1, the at least one compound E being present in an amount of maximum 10 wt% of the total amount of the at least one compound B, wherein during step a) dynamic bonds are formed by reaction of at least part of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with at least part of the b’ primary amine functional groups of the at least one compound B and optionally by reaction of at least part of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with at least part of the e’ primary amine functional groups of the at least one compound E. 9. The method according to any one of the preceding claims, wherein at least one compound D is present in the mixture of step b), with the at least one compound D having at d’ functional groups having at least one active hydrogen atom capable of reacting with an epoxide functional group, with d’ being an integer equal or greater than 1, the at least one compound D being present in an amount of maximum 10 wt% of the mixture at the start of step b). 10. The method according to any one of the preceding claims, wherein the functional group comprising at least one active hydrogen atom and being capable of reacting with an epoxide functional group comprises a b’ functional group of the at least one compound B that has not reacted with one of the a’ functional group of the at least one compound A or comprises a b’’ additional functional group of the at least one compound B or comprises an e’ functional group of the at least one compound E or comprises a d’ functional group of the at least compound D present in the mixture at the start of step b). 11. A composition comprising an epoxy-derived covalent adaptable network obtainable by the method described in any one of claims 1 to 10. |
[0087] Hence, in preferred embodiments the method described herein is provided wherein the at least one compound C is a compound selected from the group consisting of diglycidyl ethers, triglycidyl ethers, diglycidyl amines, triglycidyl amines, diglycidyl isocyanurates and triglycidyl isocyanurates, more preferably a compound selected from the group consisting of Tris(4- hydroxyphenyl)methane triglycidyl ether; Trimethylolpropane triglycidyl ether; Bisphenol A diglycidyl ether; Bisphenol F diglycidyl ether; Bisphenol C diglycidyl ether; Bisphenol E diglycidyl ether; Bisphenol BP diglycidyl ether; Bisphenol FC diglycidyl ether; Bisphenol Z diglycidyl ether; 1,6- Hexanediol diglycidyl ether; 1,4-Butanediol diglycidyl ether; Triglycidylisocyanuraat; Hydrogenated Bisphenol A diglycidyl ether; Hydrogenated Bisphenol F diglycidyl ether; Hydrogenated Bisphenol C diglycidyl ether; Hydrogenated Bisphenol E diglycidyl ether; Hydrogenated Bisphenol BP diglycidyl ether; Hydrogenated Bisphenol FC diglycidyl ether; Hydrogenated Bisphenol Z diglycidyl ether; 1,6-Naphthalenediol diglycidyl ether; Neopentyl glycol diglycidyl ether; Poly(propylene glycol) diglycidyl ether; 4,4’-Methylenebis(N,N-diglycidylaniline); and N,N-diglycidyl-4-glycidyloxyaniline. [0088] In particular embodiments of the present invention, the at least one compound C is an epoxidized polydiene or a co-polymer thereof, an epoxidized vegetable oil or a co-polymer thereof or an epoxidized terpene or a co-polymer thereof, preferably an epoxidized cycloterpene, most preferably an epoxidized cyclic monoterpene. Preferred epoxidized polydienes are epoxidized natural rubbers, epoxidized poly(1,4-butadiene) and epoxidized styrene-butadiene rubber. Preferred epoxidized vegetable oils are epoxidized soy bean oil, epoxidized castor oil, epoxidized sunflower oil and epoxidized linseed oil. Preferred epoxidized terpenes are epoxidized limonene, epoxidized terpineol, epoxidized humulene, epoxidized myrcene. epoxidized linalool, epoxidized citronellol and epoxidized pinene. [0089] It is clear that the at least one compound C may comprise other functional groups than the c’ epoxide functional groups, as for example one or more amine functional group, one or more alcohol functional groups, one or more thiol functional groups and/or one or more -C(=O)ORx functional groups, with Rx being selected from the group consisting of H and C1-C4 alkyls, preferably methyl or ethyl. COMPOUND D [0090] As mentioned above, the at least one compound D has a number of d’ additional functional groups. d’ is an integer equal or greater than 1, for example 2, 3, 4 or 5. [0091] The d’ additional functional groups comprise functional groups capable of reacting with an epoxide functional group and comprising at least one active hydrogen atom. [0092] Examples of d’ additional functional groups comprise primary amine functional groups, secondary amine functional groups, alcohol functional groups, thiol functional groups and - C(=O)OH functional groups. [0093] In a preferred example compound D comprises poly(oxy(methyl-1,2-ethanediyl) : [0094] Other examples of compound D comprise polyethyleneglycol (PEG)-based diols and triols and polypropyleneglycol (PPG)-based diols and triols. [0095] Compound D can be chosen to reduce or increase the viscosity and curing rate of the mixture. COMPOUND E [0096] As mentioned above, the at least one compound E has a number of e’ primary amine functional groups. e’ is an integer equal or greater than 1, for example 2, 3, 4 or 5. Preferably, e’ is equal to 1. [0097] Compound E does not comprise a pair of functional groups comprising a first primary amine functional group and a second primary amine functional groups, whereby the number of atoms between the first primary amine functional group and the second primary amine functional group is at least 5. [0098] Preferred compounds E comprise one primary amine functional groups. In case compound E comprises more than one e’ primary amine functional groups, these primary amine functional groups can be the same or can be different. [0099] The at least one compound E may further comprise additional functional groups (other than the e’ primary functional groups). Additional functional groups are referred to as e’’ additional functional groups. Such e’’ additional functional groups comprise for example functional groups capable of reacting with an epoxide functional group and comprising at least one active hydrogen atom. Examples of e’’ additional functional groups comprise secondary amine functional groups, alcohol functional groups, thiol functional groups and -C(=O)OH functional groups. [00100] Preferred examples of compound E comprise N-aminoethylpiperazine, N-methyl-1,3- diaminopropane and N-ethyl-N-methylpropane-1,3-diamine. [00101] In a first preferred method a compound A comprising a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- and a compound B comprising b’ primary amine functional groups are contacted in step a). At the start of step a), the combined molar amount of b’ primary amine functional groups (∑ n j b' j ) is greater (for example substantially greater) than the combined molar amount of a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- (∑ n i a' i ) so that in step b) b’ primary amine functional groups having active hydrogen atoms are present to react with the c’ epoxide functional groups of the at least one compound C. Such first preferred method comprises the steps of a) contacting at least one compound A with at least one compound B, hereby obtaining a mixture comprising or consisting of a curing agent, with the at least one compound A having a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)-, with a’ being an integer equal or greater than 2 and with Rx for each functional group being independently selected from the group consisting of H and C1-C4 alkyls and with compound A being a cyclic carboxylic acid anhydride in case compound A is having a’ functional groups of the type -C(=O)-, with each of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- belonging to a pair of functional groups comprising a first functional group and a second functional group, whereby the number of atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group ranges between 2 and 8, and with the at least one compound B having b’ primary amine functional groups, with b’ being an integer equal or greater than 2, with each of the b’ primary amine functional groups belonging to a pair of functional groups comprising a first primary amine functional group and a second primary amine functional group, whereby the number of atoms between the first primary amine functional group and the second primary amine functional group is at least 5, each of the of b’ primary amine functional groups being directly connected to a primary carbon atom, wherein during step a) dynamic bonds are formed by reaction of at least part of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with at least part of the b’ primary amine functional groups, b) contacting the mixture obtained in step a) with at least one compound C, hereby obtaining an epoxy-derived covalent adaptable network, with the at least one compound C having c’ epoxide functional groups, with c’ being an integer equal or greater than 2, wherein during step b) permanent bonds are formed by reaction of at least part of the least c’ epoxide functional groups with an active hydrogen atom of a functional group capable of reacting with an epoxide functional group present in the mixture. wherein - ∑ n j b' j being greater than ∑ n i a' i - the ratio ∑ ranging between 0.5 and 1.5, and - the ratio being equal or greater than 0.4 in case or the ratio being equal or greater than 0.4 in case x<∑ n k c' k with n i being the number of mmol (millimoles) of compound Ai with functionality a' i , n j being the number of mmol (millimoles) of compound Bj with functionality b' j , n k being the number of mmol (millimoles) of compound C i with functionality c' k , x being the total number of active hydrogen atoms of all functional groups capable of reacting with an epoxide functional group present at the start of step b). With x preferably being the total number of active hydrogen atoms of all b’ functional groups that have not reacted with an a’ primary amine functional group and that are capable of reacting with an epoxide functional group present at the start of step b). [00102] In a second preferred method a compound A comprising a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- and a compound B comprising b’ primary amine functional groups and b’’ additional functional groups are contacted in step a). The b’’ additional functional groups are capable of reacting with an epoxide functional group and comprise at least one active hydrogen atom. In step b) active hydrogen atoms of the b’ primary amine functional groups that have not reacted with an a’ functional group of the type -C(=O)ORx and/or of the type -C(=O)- as well as active hydrogen atoms of the b’’ additional functional groups react with the c’ epoxide functional groups of the at least one compound C. Such second preferred method comprises the steps of a) contacting at least one compound A with at least one compound B, hereby obtaining a mixture comprising or consisting of a curing agent, with the at least one compound A having a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with a’ being an integer equal or greater than 2 and with Rx for each functional group being independently selected from the group consisting of H and C1-C4 alkyls and with compound A being a cyclic carboxylic acid anhydride in case compound A is having a’ functional groups of the type -C(=O)-, with each of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- belonging to a pair of functional groups comprising a first functional group and a second functional group, whereby the number of atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group ranges between 2 and 8, and with the at least one compound B having b’ primary amine functional groups and having b’’ additional functional groups, with b’ being an integer equal or greater than 2 and b’’ being an integer equal or greater than 1, with each of the b’ primary amine functional groups belonging to a pair of functional groups comprising a first primary amine functional group and a second primary amine functional group, whereby the number of atoms between the first primary amine functional group and the second primary amine functional group is at least 5, each of the of b’ primary amine functional groups being directly connected to a primary carbon atom, with a b’’ additional functional groups being selected from the group consisting of primary amine functional groups, secondary amine functional groups, alcohol functional groups, thiol functional groups and -C(=O)OH functional groups, wherein during step a) dynamic bonds are formed by reaction of at least part of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with at least part of the b’ primary amine functional groups, b) contacting the mixture obtained in step a) with at least one compound C, hereby obtaining an epoxy-derived covalent adaptable network, with the at least one compound C having c’ epoxide functional groups, with c’ being an integer equal or greater than 2, wherein during step b) permanent bonds are formed by reaction of at least part of the least c’ epoxide functional groups with an active hydrogen atom of a functional group capable of reacting with an epoxide functional group present in the mixture. wherein - ∑ n j b' j being equal or greater than ∑ n i a' i - the ratio ranging between 0.5 and 1.5, and - the ratio being equal or greater than 0.4 in case or the ratio being equal or greater than 0.4 in case x<∑ n k c' k with n i being the number of mmol (millimoles) of compound Ai with functionality a' i , n j being the number of mmol (millimoles) of compound Bj with functionality b' j , n k being the number of mmol (millimoles) of compound C i with functionality c' k , x being the total number of active hydrogen atoms of all functional groups capable of reacting with an epoxide functional group present at the start of step b). With x preferably being the total number of active hydrogen atoms of all b’ functional groups that have not reacted with an a’ functional group of the type -C(=O)ORx and/or of the type -C(=O)- present at the start of step b) and of all b’’ additional functional groups present at the start of step b). [00103] In a third preferred method a compound A comprising a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)-, a compound B comprising b’ primary amine functional groups and optionally b’’ additional functional groups and a compound E comprising e’ primary amine functional groups and optionally e’’ additional functional groups are contacted in step a). The b’’ additional functional groups and/or the e’’ additional functional groups are preferably capable of reacting with an epoxide functional group and preferably comprise at least one active hydrogen atom. Such third preferred method comprises the steps of a) contacting at least one compound A with at least one compound B and with at least one compound E, hereby obtaining a mixture comprising or consisting of a curing agent, with the at least one compound A having a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with a’ being an integer equal or greater than 2 and with Rx for each functional group being independently selected from the group consisting of H and C1-C4 alkyls and with compound A being a cyclic carboxylic acid anhydride in case compound A is having a’ functional groups of the type -C(=O)-, with each of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- belonging to a pair of functional groups comprising a first functional group and a second functional group, whereby the number of atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group ranges between 2 and 8, and with the at least one compound B having b’ primary amine functional groups and optionally having b’’ additional functional groups, with b’ being an integer equal or greater than 2 and b’’ being an integer equal or greater than 0, with each of the b’ primary amine functional groups belonging to a pair of functional groups comprising a first primary amine functional group and a second primary amine functional group, whereby the number of atoms between the first primary amine functional group and the second primary amine functional group is at least 5, each of the of b’ primary amine functional groups being directly connected to a primary carbon atom. In case the at least one compound B comprises b’’ additional functional groups, such additional functional groups are preferably selected from the group consisting of primary amine functional groups, secondary amine functional groups, alcohol functional groups, thiol functional groups and -C(=O)OH functional groups, with the at least one compound E having e’ primary amine functional groups and optionally comprising e’’ additional functional groups, with e’ being an integer equal or greater than 1 and e’’ being an integer equal or greater than 0, and with compound E not comprising a pair of functional groups comprising a first primary amine functional group and a second primary amine functional groups, whereby the number of atoms between the first primary amine functional group and the second primary amine functional group is at least 5. wherein during step a) dynamic bonds are formed by reaction of at least part of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with at least part of the b’ primary amine functional groups of the at least one compound D and optionally also by reaction of at least part of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with at least part of the e’ primary amine functional groups of the at least one compound E, b) contacting the mixture obtained in step a) with at least one compound C, hereby obtaining an epoxy-derived covalent adaptable network, with the at least one compound C having c’ epoxide functional groups, with c’ being an integer equal or greater than 2, wherein during step b) permanent bonds are formed by reaction of at least part of the least c’ epoxide functional groups with an active hydrogen atom of a functional group capable of reacting with an epoxide functional group present in the mixture. wherein - ∑ n j b' j being equal or greater than ∑ n i a' i - the ratio ranging between 0.5 and 1.5, and - the ratio being equal or greater than 0.4 in case or the ratio being equal or greater than 0.4 in case x<∑ n k c' k with n i being the number of mmol (millimoles) of compound Ai with functionality a' i , n j being the number of mmol (millimoles) of compound Bj with functionality b' j , n k being the number of mmol (millimoles) of compound C i with functionality c' k , x being the total number of active hydrogen atoms of all functional groups capable of reacting with an epoxide functional group present at the start of step b). With x preferably being the total number of active hydrogen atoms of all b’ functional groups that have not reacted with an a’ functional group of the type -C(=O)ORx and/or of the type -C(=O)- present at the start of step b), the total number of active hydrogen atoms of all b’’ additional functional groups present at the start of step b) and the total number of active hydrogen atoms of all e’ functional groups that have not reacted with an a’ functional group of the type -C(=O)ORx and/or of the type - C(=O)- present at the start of step b) and the total number of active hydrogen atoms of all e’’ additional functional groups present at the start of step b). [00104] In a fourth preferred method a compound A comprising a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- and a compound B comprising b’ primary amine functional groups and optionally b’’ additional functional groups are contacted in step a). The b’’ additional functional groups are preferably capable of reacting with an epoxide functional group and preferably comprise at least one active hydrogen atom. In step b) at least one compound D is added to the start mixture. The at least one compound D comprises one or more d’ additional functional group. The d’ additional functional groups are capable of reacting with an epoxide functional group and comprise at least one active hydrogen atom. In step b) the active hydrogen atoms of the d’ additional functional groups may react with the c’ epoxide functional groups of the at least one compound C. It is clear that also active hydrogen atoms of the b’ primary amine functional groups that have not reacted with an a’ functional group of the type -C(=O)ORx and/or of the type -C(=O)- as well as active hydrogen atoms of the b’’ additional functional groups can react with the c’ epoxide functional groups of the at least one compound C. Such fourth preferred method comprises the steps of a) contacting at least one compound A with at least one compound B, hereby obtaining a mixture comprising or consisting of a curing agent, with the at least one compound A having a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with a’ being an integer equal or greater than 2 and with Rx for each functional group being independently selected from the group consisting of H and C1-C4 alkyls and with compound A being a cyclic carboxylic acid anhydride in case compound A is having a’ functional groups of the type -C(=O)-, with each of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- belonging to a pair of functional groups comprising a first functional group and a second functional group, whereby the number of atoms between the carbonyl group of the first functional group and the carbonyl group of the second functional group ranges between 2 and 8, and with the at least one compound B having b’ primary amine functional groups and having b’’ additional functional groups, with b’ being an integer equal or greater than 2 and b’’ being an integer equal or greater than 0, with each of the b’ primary amine functional groups belonging to a pair of functional groups comprising a first primary amine functional group and a second primary amine functional group, whereby the number of atoms between the first primary amine functional group and the second primary amine functional group is at least 5, each of the of b’ primary amine functional groups being directly connected to a primary carbon atom. In case the at least one compound B comprises b’’ additional functional groups, such additional functional groups are preferably selected from the group consisting of primary amine functional groups, secondary amine functional groups, alcohol functional groups, thiol functional groups and -C(=O)OH functional groups wherein during step a) dynamic bonds are formed by reaction of at least part of the a’ functional groups of the type -C(=O)ORx and/or of the type -C(=O)- with at least part of the b’ primary amine functional groups, b) contacting the mixture obtained in step a) further comprising at least one compound D with at least one compound C, hereby obtaining an epoxy-derived covalent adaptable network, with the at least one compound C having c’ epoxide functional groups, with c’ being an integer equal or greater than 2, with the at least one compound D having d’ additional functional groups, with d’ being an integer equal or greater than 1 and with the d’ additional functional groups being selected from the group consisting of primary amine functional groups, secondary amine functional groups, alcohol functional groups, thiol functional groups and -C(=O)OH functional groups, wherein during step b) permanent bonds are formed by reaction of at least part of the least c’ epoxide functional groups with an active hydrogen atom of a functional group capable of reacting with an epoxide functional group present in the mixture. wherein - ∑ n j b' j being equal or greater than ∑ n i a' i - the ratio ranging between 0.5 and 1.5, and - the ratio being equal or greater than 0.4 in case or the ratio being equal or greater than 0.4 in case x<∑ n k c' k with n i being the number of mmol (millimoles) of compound Ai with functionality a' i , n j being the number of mmol (millimoles) of compound Bj with functionality b' j , n k being the number of mmol (millimoles) of compound C i with functionality c' k , x being the total number of active hydrogen atoms of all functional groups capable of reacting with an epoxide functional group present at the start of step b). With x preferably being the total number of active hydrogen atoms of all b’ functional groups that have not reacted with an a’ functional group of the type -C(=O)ORx and/or of the type -C(=O)- present at the start of step b), the total number of active hydrogen atoms of all b’’ additional functional groups present at the start of step b) and the total number of active hydrogen atoms of all d’ functional groups present at the start of step b). [00105] According to a second aspect of the present invention, a composition comprising an epoxy- based covalent adaptable network is provided. The composition is obtainable by the above- described method. [00106] According to a third aspect of the present invention, the use of a composition comprising an epoxy-based covalent adaptable network, preferably an epoxy-based covalent adaptable network obtainable by the above-described method is provided. The composition comprising the epoxy-based covalent adaptable network is for example used as adhesive or coating. [00107] In particular embodiments the composition comprising the epoxy-based covalent adaptable network is used as encapsulation material of electronic components. Brief description of the drawings [00108] The present invention will be discussed in more detail below, with reference to the attached drawings, in which: - Figure 1 shows the synthesis strategy of a polyamide resin (example 1) starting from methyl ester of dicarboxylic acid, trifunctional amine tris(2-aminoethyl)amine (TREN) as a cross- linker and bifunctional Priamine 1074 as a chain extender to obtain a polyamide resin; - Figure 2 shows the synthesis strategy of a composition (example 2) comprising an epoxy- based covalent adaptable network according to the present invention starting from methyl ester of dicarboxylic acid, trifunctional amine tris(2-aminoethyl)amine (TREN) and 1,4- Butanediol diglycidyl ether; - Figure 3 shows the thermal stability of example 1 and example 2 by depicting the isothermal TGA measurement measured at 200 °C of the composition of example 1 and at 200 °C and 250 °C of the composition of example 2 for 120 minutes; - Figure 4 depicts the relaxation time as a function of temperature to display the difference in dynamic behavior of example 1 and example 2; - Figure 5 and Figure 6 depict the non-normalized stress-relaxation data of respectively example 1 and example 2 at different temperatures; - Figure 7 shows the thermal stability (isothermal TGA) of examples 007B, 009A and 009B at 200 °C for 120 minutes; - Figure 8 shows the thermal stability (isothermal TGA) of examples 011B, 011C and 018K at 200 °C for 120 minutes; - Figure 9 shows the thermal stability (isothermal TGA) of examples 012A and 016B at 250 °C for 120 minutes; - Figure 10 shows the thermal stability (isothermal TGA) of examples 024B, 026A and 026B at 250 °C for 120 minutes; - Figure 11a, 11b and 11c show respectively the synthesis strategy, the stress-relaxation behavior and the shear-viscosity plot of example 007B; - Figure 12 to 22 show the synthesis strategy, the stress-relaxation behavior and the shear- viscosity plot of examples 009A, 009B, 011B, 011C, 018K, 012A, 16D, 024B, 026A, 026B and 027B; - Figure 23a, 23b and 23c show respectively creep data, shear viscosity plot (obtained from stress-relaxation measurement) and zero-shear viscosity plot (obtained from creep measurement) of example 016C; - Figure 24 shows the frequency sweep data of example 024B. Description of embodiments [00109] The present invention will be described with respect to particular embodiments and with reference to certain drawings; but the invention is not limited thereto but only by the claims. The drawings are only schematic and are non-limiting. The size of some of the elements in the drawing may be exaggerated and not drawn to scale for illustrative purposes. The dimensions and the relative dimensions do not correspond to actual reductions to practice of the invention. [00110] When referring to the endpoints of a range, the endpoint values of the range are included. [00111] When describing the invention, the terms used are construed in accordance with the following definitions, unless indicated otherwise. [00112] The term ‘and/or’ when listing two or more items, means that any one of the listed items can by employed by itself or that any combination of two or more of the listed items can be employed. [00113] A number of compositions were synthesized and evaluated using the characterisation procedures given below. [00114] Thermogravimetric analyses (TGA) were performed on a Mettler-Toledo TGA/SDTA 851e instrument. Isothermal thermogravimetric measurements were performed under nitrogen atmosphere at 200 °C or 250 °C for 120 minutes with a heating rate of 10 °K.min -1 . [00115] A Mettler Toledo instrument 1/700 was used to perform differential scanning calorimetry (DSC) measurements under nitrogen atmosphere with a heating rate of 10 K.min -1 and a cooling rate of 10 K.min -1 . Several cycles of measurements were performed from -50 °C to 150 °C. The glass transition temperature (Tg) was determined at the second cycle. [00116] Attenuated total reflection Fourier Transform Infrared (ATR-FTIR) analysis were realized on a Perkin-Elmer Spectrum1000 FTIR infrared spectrometer equipped with a diamond ATR probe. [00117] The networks were (re)processed using compression molding. Samples were cut or grinded to small pieces of roughly 1 to 2 mm diameter size and placed in a steel mold. The mold was transferred to a heated plate press at 200 °C or 250 °C for 15 min to 90 min at 2 to 4 metric ton of pressure. The samples were removed after cooling the mold to ~ 80 to 100 °C. [00118] Stress-relaxation experiments were performed using an Anton-Paar MCR 302 rheometer with a plate diameter of 8 mm and on samples having a diameter of 8 mm and a thickness of 1 mm. Then stress-relaxation experiments were performed using a shear strain of 0.5% and a constant force of 1 N. By fitting the relaxation modulus data to a single exponential decay (Single Maxwell according to equation (1): (1) a relaxation time can be obtained and related to the shear viscosity according to equation (2): (2) with the shear modulus The initial relaxation modulus was obtained from the stress- relaxation data at 1 s. Monitoring the as a function of temperature allows to determine the flow capacity or dynamic behavior of the epoxy-derived covalent adaptable network. Moreover, by plotting ln -1 as a function of 1000/T (K ), an activation energy could be obtained from the slope of the (linear part of the) curve. [00119] Frequency sweep experiments were performed using an Anton-Paar MCR rheometer using a strain of 0.5% while a normal force of 1 N was applied and a frequency range from 0.01 to 100 rad·s −1 was screened by following the evolution of G′ and G″ at a constant temperature. Subsequently the same process was repeated at different temperatures from high to low. [00120] Creep experiments at different temperatures (50 to 120 °C, with intervals of 10 °C) were also performed on an Anton-Paar MCR rheometer using an applied force of 1 N. A 2000 Pa shear stress (σ in Pa) was applied for 5000 s, and the shear strain was monitored as a function of time. From the slope of the steady-state region (4000 s to 5000 s), creep rate values were calculated and related to the zero-shear viscosity according to equation (3): (3). Monitoring the as a function of temperature allows to determine the flow capacity or dynamic behavior of the epoxy-derived covalent adaptable network. Moreover, by plotting ln as a func -1 tion of 1000/T (K ), an activation energy could be obtained from the slope of the (linear part of the) curve. Examples [00121] A polyamide resin (example 1) was synthesized following the synthesis strategy shown in Figure 1. A composition (example 2) comprising an epoxy-based covalent adaptable network according to the present invention was synthesized following the synthesis strategy shown in Figure 2. Details of the synthesis of example 1 and example 2 are given below. [00122] Figure 11 to 22 show the synthesis strategy, the stress-relaxation behavior and the shear- viscosity plot of particular examples. In a shear viscosity plot in function of 1000/T (in K -1 ) is plotted. Example 1 [00123] Dimethyl glutarate (1.83 g, 11.4 mmol, 1 equiv), TREN (0.67 g, 4.57 mmol, 0.4 equiv), and Priamine 1074 (2.5 g, 4.57 mmol, 0.4 equiv) were mixed in a 20 mL polypropylene cup using a DAC 150.1 FVZ speed mixer (typical conditions of mixing: 2 min with a speed of 2500 rpm). Then, the cup was placed in an oven at 100 °C for 24 h to initiate the network formation. Hereafter, the network was further cured for 24 h at 100 °C under vacuum. Example 2 [00124] Dimethyl glutarate (0.79 g, 4.92 mmol, 1 equiv) and Priamine 1074 (3.5 g, 6.40 mmol, 1.3 equiv) were mixed in a 20 mL polypropylene cup first using a DAC 150.1 FVZ speed mixer (typical conditions of mixing: 2 min with a speed of 2500 rpm). Then, the cup was placed in an oven at 80 °C for 24 h to prepare the dynamic curing agent. Next, 1,4-butanediol diglycidyl ether (0.59 g, 2.95 mmol, 0.6 equiv) was added to the mixture and speed mixing was repeated until a homogeneous viscous liquid was obtained. Hereafter, the network was heated in an oven at 80 °C for 4 h to initiate curing. Subsequently, the network was cured for 24 h at 100 °C under vacuum. [00125] Figures 3-6, described herein earlier, show selected results of the characterisations performed on example 1 (comparative example) and example 2 (example according to the present invention). As can be observed from Figure 3, the weight loss of a composition according to the present invention is considerably lower even at a temperature of 250 °C. Figure 4 shows that example 1 has a higher thermal stability and higher processing temperature than example 2. Figure 5 and Figure 6 show the relaxation modulus (in Pa) in function of the relaxation time (in s). Further examples [00126] A range of a composition comprising an epoxy-based covalent adaptable network according to the present invention were synthesised according to the method of the present invention starting from varying combinations of the compounds A, B, C and E given in respectively in Table 3, Table 4, Table 5 and Table 6. The formulations of a number of examples are given in Table 7, Table 8 and Table 9. Table 3 : examples of compound A Table 4 : examples of compound B
Table 5 examples of compound C Table 6 example of compound E [00127] Figures 7-10, described herein earlier, display the thermal stability based on the composition depicted in Table 7. Examples comprising a fraction of fatty amine (Priamine 1074) show a higher thermal stability. [00128] Figures 11-22 show the synthesis strategy, the stress-relaxation behavior and the shear- viscosity plot of particular examples. Starting from varying combinations of the compounds A, B, C and E, an optimal balance between cross-linking density and material flow is depicted. Materials with a large variation in glass transition temperature (T g ) were obtained. Despite resulting in highly cross-linked networks a sharp decrease in viscosity (i.e. activation energy values above 200 kJ.mol -1 ) could be obtained in a relatively short temperature range. The observed decrease in viscosity is both a result of reversible chain-cleavage (loss in modulus) and exchange of the dissociated intermediates (relaxation). As a result, these epoxy-derived covalent adaptable networks only show sufficient (re)processability at higher temperatures. [00129] Figure 23 shows the results of the creep experiments and corresponding viscosity plot compared to the stress-relaxation data of particular examples. A drastic difference between dynamic behavior is observed at 200 °C to 250 °C (high activation energy or sharp decrease in viscosity obtained from high temperature stress-relaxation) and at 60 °C to 120 °C (low activation energy or low decrease in viscosity obtained from low temperature creep experiment). [00130] Figure 24 displays the result of frequency sweep experiments of particular examples. Prolonged heating at higher temperatures did not result in significant degradation or decrease in material properties, since going from 250 °C to 190 °C resulted in a recovery of cross-linking density with high plateau storage moduli values between 10 6 and 10 7 Pa Table 7 Table 8 Table 9
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