Patent Description:
In a 3D inkjet printing process, for example, when printing an object having a suspended structure, a suspended part below the suspended structure of the object needs a printing support structure so that a target object can be printed; after the target object is formed, the support structure needs to be removed from the target object without affecting the surface accuracy of the target object. Therefore, the support structure not only needs to have sufficient mechanical strength to support the target object, but also needs to be easily removed from the target object.

The types of existing support materials can be divided into a mechanically removable support material, a water-soluble support material, a water-swellable support material, an alkali-soluble support material and the like according to the removal mode of the support structure; where for the mechanically removable support material, in the process of removing the support structure, the target object can be damaged due to the impact action of a mechanical force ,and the support structure in fine holes is difficult to be removed; for the water-soluble support material and the water-swellable support material, they have slow dissolution rate and swelling rate in water, respectively, especially when the support structure has a large volume, the removal rate of the support structure is slow; for the alkali-soluble support material, in the process of removing the support structure, the alkali-soluble support material quickly reaches saturation over time, and the removal rate of the support structure is slowed down, and thus the alkali solution needs to be replaced frequently, thereby, on one hand, increasing the removal cost of the support structure, and on the other hand, causing environmental pollution due to use of a large amount of alkali solution.

It is known that the Chinese invention patent <CIT> discloses a support material composition, which includes a non-curable water-miscible polymer, a first water-miscible curable material, and at least, a second water-miscible curable material; where the second water-miscible curable material is selected to interfere with the interaction of a plurality of molecules between a plurality of polymer chains formed after exposure of the first water-miscible material to the curing energy. In the known prior art, by using the second curable material to interfere with the polymer reaction of the first curable material, the crosslinking degree of the polymer is reduced, so that the support structure formed by light-curing can be easily and effectively removed in the alkaline solution, reducing the dissolution time, increasing the dissolution rate, and not damaging the mechanical properties of the support material. However, due to the fact that the molecular structure of the second water-miscible curable material contains an unsaturated double bond, the unsaturated double bond can also participate in the light-curing reaction in the light-curing reaction process, which has a certain influence on the dissolution rate in the alkali solution when increasing the mechanical strength of the light-cured product.

<CIT> discloses a composition for photocurable support materials for inkjet 3D modeling, containing a water-soluble ethylenically unsaturated monomer that contains an ionic group and a counter ion; and the content of water in <NUM>% by mass of this composition for photocurable support materials is <NUM>% by mass or less. It is preferable that this composition for photocurable support materials for inkjet 3D modeling additionally contains a photopolymerization initiator.

<CIT> discloses a photocurable support material composition for an inkjet 3D printer, comprising a water-soluble ethylenically unsaturated monomer containing an ionic group and a counter ion, and comprising a photopolymerization initiator. The ionic group is preferably at least one selected from a group consisting of carboxylic acid group, phosphoric acid group, and sulfonic acid group. The counter ion is preferably at least one selected from a group consisting of sodium ion, potassium ion, and ammonium ion.

<CIT> discloses novel support material formulations, characterized as providing a cured support material with improved dissolution rate, while maintaining sufficient mechanical strength. The formulations comprise a water-miscible non-curable polymer, a first water-miscible, curable material and a second, water-miscible material that is selected capable of interfering with intermolecular interactions between polymeric chains formed upon exposing the first water-miscible material to curing energy.

<CIT> discloses formulations usable as support material in additive manufacturing such as 3D inkjet printing and which feature a viscosity of no more than 50cPs at <NUM>. The formulations are composed of at least one hydrophilic curable material which provides, when hardened, a material that is dissolvable or swellable in an aqueous solution; and at least one non-curable material that is capable of being swelled by said hardened material formed of said at least one curable material.

Therefore, how to provide a support material composition, a light-cured product of which has an increased dissolution rate in an alkaline solution while having increased support strength, has become a problem to be solved.

The present application is defined in appended set of claims. The present application provides a composition for 3D inkjet printing, including a specific functional reaction-promoting material, which is used in combination with a light-curable bulk material. The composition has significantly improved conversion rate of light-curing reaction, and the light-cured product of the composition has a significantly improved dissolution rate in alkaline solution while having an enhanced support strength.

The present application provides a method for preparing a composition for 3D inkjet printing, which can effectively prepare a composition for 3D inkjet printing.

The present application further provides a 3D inkjet printing device, including an inkjet print head that is capable of performing printing by using the composition for 3D inkjet printing.

The present application further provides a 3D inkjet printing method, which is capable of printing, by the 3D inkjet printing device, a support structure, using the composition for 3D inkjet printing of the support structure.

The present application further provides a support structure, which is printed using the composition for 3D inkjet printing of the support structure by the 3D inkjet printing device.

The composition for 3D inkjet printing of the support structure provided by the present application includes the following components based on a total weight of the composition: <NUM>-<NUM> parts by weight of a light-curable bulk material, <NUM>-<NUM> parts by weight of a functional reaction-promoting material represented by the general formula (I) mentioned below, a non-curable water-miscible material, a photoinitiator and an auxiliary agent, where the functional reaction-promoting material contains carboxyl group and reactive hydrogen in a molecular structure thereof and the reactive hydrogen can react with a peroxy free radical.

In a solution of the present application, the reactive hydrogen refers to hydrogen on a carbon atom closest to a functional group, and if COOH is a functional group and R<NUM> and R<NUM> are selected from hydrogen, the hydrogen is reactive hydrogen; and if R<NUM> is a functional group, hydrogen on a carbon atom connected to R<NUM> is also reactive hydrogen.

In the present application, the functional reaction-promoting material has a structure represented by the following general formula (I):
<CHM>
in which, R<NUM>, R<NUM>, R<NUM> and R<NUM> are independently selected from at least one of the group consisting of hydrogen, hydroxyl, carboxyl, alkoxy, aryloxy, nitrogen-containing heterocyclic ring, oxygen-containing heterocyclic ring and benzene ring, and when R<NUM> is hydrogen, at least one of R<NUM> and R<NUM> is selected from hydrogen; n and m are independently selected from an integer greater than or equal to <NUM>, and n≤<NUM> and m≤<NUM>.

In a solution of the present application, the functional reaction-promoting material having the structure represented by general formula (I) can be obtained by a conventional method in the art, for example, it can be synthesized according to the method described in <CIT> or is commercially available.

Further, at least one of R<NUM>, R<NUM>, R<NUM> and R<NUM> is hydrogen.

Further, in the general formula (I), n≤<NUM>, and m≤<NUM>.

More further, the alkoxy group is a C1-<NUM> low level alkoxy group.

Specifically, Table <NUM> lists some of specific structures of the functional reaction-promoting material, but the functional reaction-promoting material used in the composition of the present application is not limited to those in Table <NUM>, all functional reaction-promoting materials meeting the structure of the general formula (I) in the present application are within the protection scope of the present application.

In another specific embodiment of the present application, the functional reaction-promoting material is <NUM>-<NUM> parts by weight. When the weight of the functional reaction-promoting material is within the range, the conversion rate of the light-curing reaction of the light-curable bulk material is up to <NUM>-<NUM>%.

Further, the non-curable water-miscible material is <NUM>-<NUM> parts by weight, the photoinitiator is <NUM>-<NUM> parts by weight, and the auxiliary agent is <NUM>-<NUM> parts by weight.

Further, the light-curable bulk material is a (meth)acrylate compound and/or a (meth)acrylamide compound.

In a specific embodiment of the present application, the (meth)acrylate compound is a monofunctional (meth)acrylate compound and/or a multifunctional (meth)acrylate compound.

Further, the monofunctional (meth)acrylate compound is selected from one or more of glycidyl methacrylate (molecular weight <NUM>), <NUM>-(acryloyloxy)-<NUM>-hydroxypropyl methacrylate (molecular weight <NUM>), <NUM>-(methacryloyloxy)ethyl <NUM>-hydroxybutyrate (molecular weight <NUM>), hydroxyethyl acrylate (molecular weight <NUM>), <NUM>-hydroxybutyl acrylate (molecular weight <NUM>), polyethylene glycol (<NUM>) monoacrylate (molecular weight <NUM>), polyethylene glycol (<NUM>) monoacrylate (molecular weight <NUM>), methoxypolyethylene glycol (<NUM>) monoacrylate (molecular weight <NUM>), and methoxy polyethylene glycol (<NUM>) monoacrylate (molecular weight <NUM>).

More further, the multifunctional (meth)acrylate compound is selected from one or more of pentaerythritol tetraacrylate (molecular weight <NUM>), pentaerythritol triacrylate (molecular weight <NUM>), polyethylene glycol (<NUM>) diacrylate (molecular weight <NUM>), polyethylene glycol (<NUM>) diacrylate (molecular weight <NUM>), and polyethylene glycol (<NUM>) diacrylate (molecular weight <NUM>).

Further, the (meth)acrylamide compound is selected from one or more of acryloylmorpholine (molecular weight <NUM>), dimethylacrylamide (molecular weight <NUM>), diethylacrylamide (molecular weight <NUM>), dimethylaminopropyl acrylamide (molecular weight <NUM>) and hydroxyethyl acrylamide (molecular weight <NUM>).

In another specific embodiment of the present application, based on the total weight of the composition, a proportion of the monofunctional compounds with a molecular weight greater than or equal to <NUM> in the light-curable bulk material is <NUM>-<NUM> parts by weight, and a proportion of the compounds with a molecular weight greater than <NUM> and less than <NUM> in the light-curable bulk material is <NUM>-<NUM> parts by weight. In a solution of the present application, the solubility of the light-cured product of the composition in the alkaline solution is better by controlling the proportions of the compounds with different molecular weight ranges in the light-curable bulk material.

Further, based on the total weight of the composition, the multifunctional (meth)acrylate compound in the light-curable bulk material accounts for <NUM>-<NUM> parts by weight.

In another specific embodiment of the present application, the light-curable bulk material is selected from at least one of a (meth)acrylate compound and a (meth)acrylamide compound, molecular weights of which are greater than or equal to <NUM>, and is selected from at least one of a (meth)acrylate compound and a (meth) acrylamide compound, molecular weights of which are greater than <NUM> and less than <NUM>.

Further, the composition has a viscosity of <NUM>-<NUM> mPa. s (<NUM>-<NUM> cps) and a surface tension of <NUM>-<NUM> mN/m at <NUM>, and has a viscosity of <NUM>-<NUM> mPa. s (<NUM>-<NUM>) and a surface tension of <NUM>-<NUM> mN/m at <NUM>-<NUM>.

In one specific embodiment of the present application, the composition is obtained by mixing the components under the condition of avoiding light-induced polymerization reaction of the components.

In the solution of the present application, the non-curable water-miscible material is a polyol.

In the light-curing reaction process of the composition, the non-curable water-miscible material is infiltrated into a net-like structure formed by a light-curing reaction, so that the dissolution rate of the product, which is formed by light-curing of the composition, in water or alkaline solution is further improved. The "water-miscible material" is liquid itself and is at least partially soluble in water or dispersed in water, further for example at least <NUM>% of its molecules are soluble in water when contacted (e.g. mixed) with water.

Further, the polyol may be one or more selected from polyol <NUM>, polyol <NUM>, ethylene oxide-tetrahydrofuran copolymer (EO/THF copolymer), polypropylene glycol, polyglycerol, <NUM>,<NUM>-propylene glycol, tripropylene glycol monomethyl ether, dipropylene glycol monomethyl ether, triethylene glycol dimethyl ether, polyethylene glycol monomethyl ether (<NUM>), polyethylene glycol (<NUM>) and polyethylene glycol (<NUM>).

In embodiments of the present application, the photoinitiator is a free radical photoinitiator.

Further, the free radical photoinitiator can be one or more selected from the group consisting of benzoin ethyl ether, benzoin α,α-dimethyldibenzoylketal, α,α-diethoxyacetophenone, <NUM>-hydroxy-<NUM>-methyl-phenylacetone-<NUM>, <NUM>-hydroxy-cyclohexylphenyl ketone, <NUM>-isopropyl thioxanthone, <NUM>-hydroxy-<NUM>- methyl-p-hydroxyethyl ether phenyl acetone-<NUM>, <NUM>-methyl-<NUM>-[<NUM>-methylthiophenyl]-<NUM>-morpholinyl-<NUM>-acetone, [<NUM>-benzyl-<NUM>-dimethylamino-<NUM>- (<NUM>-morpholinophenyl) butanone-<NUM>], benzoyl formate, <NUM>,<NUM>,<NUM>-trimethylphenylacyl-ethoxy-phenylphosphine oxide, <NUM>,<NUM>,<NUM>-trimethylphenylacyl-diphenylphosphine oxide, phenyl bis (<NUM>,<NUM>,<NUM>-trimethylbenzoyl) phosphine oxide and <NUM>-p-toluenemercapto benzophenone.

Further, the auxiliary agent is selected from a surfactant and/or a polymerization inhibitor.

The surfactant added in the composition for 3D inkjet printing of the support structure has certain solubility in water or an aqueous solution, and the main function of the surfactant is to adjust the surface tension of the composition to enable the composition to be normally used for printing, while improving the fluidity of the composition and the wetting performance of the composition to the substrate. The main function of adding the polymerization inhibitor is to prevent the polymerization reaction of free radicals in the composition and improve the storage stability of the composition, and the polymerization inhibitor is preferably a product that both improves the storage stability and has no influence on the light-curing reaction of the composition.

More further, the surfactant is selected from at least one of polyether-modified siloxane and non-silicone-based polyether. The polyether-modified siloxane can be, for example, various polyether-modified siloxane surfactants on the market, for example, it can be at least one under the trade names of BYK <NUM>, BYK <NUM>, BYK <NUM> and the like from BYK company, can be at least one under the trade names of TEGO wet <NUM>, TEGO Glide <NUM> and the like from TEGO company, and can be at least one under the trade names of AFCONA-<NUM>, AFCONA-<NUM>, AFCONA-<NUM>, AFCONA-<NUM> and the like from AFCONA company. The non-silicone-based polyether can be various non-silicone-based polyether surfactants on the market, for example, it can be at least one under the trade names of BYK800D or the like from BYK company, can be at least one under the trade names of TEGO WET <NUM>, TEGO Airex <NUM>, TEGO Airex <NUM> and the like from TEGO company, and can be at least one under the trade names of AFCONA-<NUM>, AFCONA-<NUM> and the like from AFCONA company.

Still further, the polymerization inhibitor can be at least one under the trade names of GENORAD*<NUM>, GENORAD*<NUM>, GENORAD*<NUM>, GENORAD*<NUM> and the like from Genorad, can be at least one under the trade names of Tinuvin234, Tinuvin770, Irganox245, Cyanogen S100, Cyanogen <NUM> and the like from BASF, can be at least one under the trade names of Irgastab UV10, Irgastab UV 22D and the like from Ciba, can be at least one of MEHQ and the like from Amarico, US, and can be <NUM> polymerization inhibitor and the like from Shanghai Boer Chemical Reagent Co.

The application further provides a method for preparing the composition for 3D inkjet printing of the support structure, which includes performing the following steps under the condition of avoiding light-induced polymerization reaction of the components of the composition:.

Further, in step <NUM>) of the method, the order of adding the components in the process of obtaining the first mixture is not limited.

Further, in step <NUM>) of the method, filtering can be carried out in a multiple filtering manner, especially in a stage-by-stage filtering manner. Specifically, the second mixture can be filtered at least twice by using microporous filter membrane, where a pore diameter of the microporous filter membrane adopted in a former filtration is greater than a pore diameter of the microporous filter membrane adopted in a latter filtration, and a pore diameter of the microporous filter membrane used in the last filtration is smaller than a pore diameter of a nozzle of a print head in the 3D inkjet printing device to ensure good printing fluency when making the support structure by the 3D inkjet printing, preventing clogging the nozzle of the print head.

In a specific implementation process of the application, the second mixture is treated in a two-stage filtration mode, where a first-stage filtration adopts a glass fiber membrane with a pore diameter of <NUM>-<NUM>, and a second-stage filtration adopts a polypropylene membrane with a pore diameter of <NUM>.

Further, the collected filtrate can be subjected to degassing treatment. Degassing treatment of the filtrate further ensures that the composition has very good fluency in the use, and avoids the interference of bubbles in the composition which can cause interruption of the printing line and thus affect the forming accuracy of the support structure.

Specifically, the operation mode of the degassing treatment can be reduced pressure degassing, atmospheric pressure degassing or heating degassing, or any two or more of these degassing modes can be selected. Generally, the time for the degassing treatment is controlled to be not more than <NUM> hours. In a specific implementation process of the present application, the time for the degassing treatment is generally controlled to be <NUM>-<NUM> hours.

The 3D inkjet printing device provided in the present application includes an inkjet print head, and the inkjet print head can perform printing using a composition for the 3D inkjet printing of the support structure.

According to the 3D inkjet printing method provided in the present application, a printing process includes printing a support structure, by the 3D inkjet printing device, using the composition for 3D inkjet printing of the support structure.

The present application further provides a support structure, which is printed by the 3D inkjet printing device using the composition for 3D inkjet printing of the support structure.

In a solution of the present application, the support structure includes any structure other than a target object in a printing process of the target object, and certainly, the composition provided in the present application can also be used for printing a target object that meets a requirement.

In the present application, a functional reaction-promoting material, whose molecular structure contains reactive hydrogen, is added to the composition. As a donor of the reactive hydrogen, the functional reaction-promoting material can reactivate free radicals which have been deactivated due to the influence of polymerization inhibition of oxygen, and/or convert free radicals which have been deactivated due to the influence of polymerization inhibition of oxygen, to obtain active alkoxy free radicals and active hydroxyl free radicals; and sufficient active free radicals under the irradiation of ultraviolet light enable the light-curable bulk material to sufficiently undergo light-curing reaction, so that the conversion rate of light-curing of the light-curable bulk material is improved, and thus the amount of the light-curable bulk material, which is needed to reach required supporting mechanical strength of the support structure at the same exposure time and intensity in the 3D inkjet printing process, is greatly reduced; the reduced amount of the light-curable bulk material in the composition for 3D inkjet printing of the support structure in the present application results in a greatly improved dissolution rate of the cured composition when the cured composition is placed in an alkaline solution. In the present application, the molecular structure of the functional reaction-promoting material contains a carboxyl group, the carboxyl group itself and the reaction product thereof can react with alkali in an alkaline solution to accelerate the dissolution rate of the composition of the light-cured support material in the alkaline solution; moreover, the molecular structure of the functional reaction-promoting material containing carboxyl group results in water solubility or hydrophility and better solubility in an alkaline solution.

The solution of the present application has the following advantages:.

The present example provides a composition for 3D inkjet printing of a support structure, and the composition has the following components as shown in Table <NUM>:.

The functional reaction-promoting material in Table <NUM> can be purchased from TIC Shanghai Development Co. or Sigma-Aldrich (Shanghai) Trade Co. The functional reaction-promoting material in the present example is purchased from TIC Shanghai Development Co.

The preparation method of the composition for 3D inkjet printing of the support structure is as follows:.

The functional reaction-promoting material in Table <NUM> can be purchased from Shanghai Ziyu Material Science and Technology Co. or Tokyo Chemical Industry Co. The functional reaction-promoting material in the present example is purchased from Shanghai Ziyu Material Science and Technology Co.

The preparation method of the composition for 3D inkjet printing of the support structure in the example is basically the same as that in Example <NUM>, except that the components used are correspondingly replaced, and a heating degassing mode is adopted in the step (<NUM>) of the preparation method, to heat the filtrate obtained in the step (<NUM>) to about <NUM> for degassing treatment, where the degassing time is <NUM> minutes.

The functional reaction-promoting material in Table <NUM> can be purchased from Nanjing Chemical Reagent Co. and Xiya Chemical Technology (Shandong) Co. The functional reaction-promoting material in the present example is purchased from Nanjing Chemical Reagent Co.

In the present example, the preparation method of the composition for 3D inkjet printing of the support structure is basically the same as that in Example <NUM>, except that the components used are correspondingly replaced, and in the step (<NUM>) of the preparation method, the specific time of reduced-pressure degassing is adjusted to be <NUM> hours.

The functional reaction-promoting material in Table <NUM> can be purchased from Shanghai Ziyu Material Science and Technology Co. and Tokyo Chemical Industry Co. The functional reaction-promoting material in the present example is purchased from Shanghai Ziyu Material Science and Technology Co.

In the present example, the preparation method of the composition for 3D inkjet printing of the support structure is basically the same as that in Example <NUM>, except that the components used are correspondingly replaced, and in step (<NUM>) of preparation method, the degassing treatment is carried out by standing at an atmospheric pressure, where the standing time is <NUM>.

The preparation method of the composition for 3D inkjet printing of the support structure in the present example is basically the same as that in Example <NUM>, except that the components used are correspondingly replaced, and in step (<NUM>) of the preparation method, a heating degassing mode is adopted, heating the filtrate obtained in the step (<NUM>) to about <NUM> for degassing treatment, where the degassing time is <NUM> minutes.

The present example provides a composition for 3D inkjet printing of the support structure, and the composition has the following components as shown in Table <NUM>:.

The functional reaction-promoting material in Table <NUM> can be purchased from Shanghai Ziyu Material Science and Technology Co. or TCI Europe. The functional reaction-promoting material in the present example is purchased from Shanghai Ziyu Material Science and Technology Co.

The preparation method of the composition for 3D inkjet printing of the support structure in the present example is basically the same as that in Example <NUM>, except that the components used for 3D inkjet printing of the support structure are correspondingly replaced.

The functional reaction-promoting material in Table <NUM> can be purchased from Shanghai Ziyu Material Science and Technology Co. or Simachem Corporation. The functional reaction-promoting material in the present example is purchased from Shanghai Ziyu Material Science and Technology Co.

The preparation method of the composition for 3D inkjet printing of the Support Structure in the present example is basically the same as that in Example <NUM>, except that the components used for 3D inkjet printing of the support structure are correspondingly replaced.

The present comparative example provides a composition for 3D inkjet printing of the support structure, and the composition has the following components:.

The preparation method of the composition for 3D inkjet printing of the support structure in Comparative Example <NUM> is basically the same as that of Example <NUM>, except that the components used for 3D inkjet printing of the support structure are correspondingly replaced.

The present example provides a 3D inkjet printing device, including an inkjet print head, where the inkjet print head can be used to print a support structure with the composition for 3D inkjet printing of the support structure according to any one of the foregoing examples. Further, a target object can also be printed on the support structure.

The present example provides a printing method for printing, by the 3D inkjet printing device of Example <NUM>, a support structure by using the composition for 3D inkjet printing of the support structure according to any one of Examples <NUM>-<NUM>.

Performance test on the composition for 3D inkjet printing of the support structure in the above examples and comparative example is conducted, where the test method is as follows, and the test results are shown in Table <NUM>.

The viscosity of the composition is tested using a DV-I Digital Viscometer.

The surface tension of the composition is tested by adopting a BZY-<NUM> full-automatic surface tension meter.

The composition in the present application is applied to a Sailner J5013D light-curing inkjet printer to print a cube sample (i.e., a product sample or a support structure sample after the composition is cured) with a size specification required in <CIT> Plastics-Determination of Bearing Strength, and the support strength of the sample is determined by a compression test carried out by a LLOYD tension meter of model LR5K PLUS, the test is operated under standard compression combined parameters and the support strength is expressed in MPa with respect to the cube described above.

The composition is applied to a Seine J501 3D light-curing inkjet printer, setting the temperature of the spray head to <NUM>-<NUM>, to print a cube with its length, width and height being <NUM> x <NUM> x <NUM>, and after printing is completed, the cube (which can be a product sample or a support structure sample after the composition is cured) is immersed in <NUM> of aqueous solution of sodium hydroxide with a weight ratio of <NUM>%, and then the time for the cube, such as the support structure sample, to be completely dissolved is recorded.

By utilizing the infrared spectrum analysis technology, an area of characteristic absorption peak of the C=C double bond of the composition at <NUM>-<NUM>-<NUM> before and after curing is determined (A1 before curing, and A2 after curing) and conversion rate of the light-curing reaction is determined by the formula C% = (A1-A2)/A1 * <NUM>%.

It can be seen that the composition in Examples <NUM>-<NUM> has a significantly improved conversion rate of light-curing reaction compared with the comparative example without adding a functional reaction-promoting material, and its light-cured product, i.e., the support structure, has a significantly improved dissolution rate in an alkaline solution while having increased support strength. The dissolution time of the printed support structure sample of <NUM> x <NUM> x <NUM> is less than or equal to <NUM> minutes in an alkaline solution.

On the premise of obtaining the same support strength of the cured product (i.e., the printed support structure), the amount of light-curable bulk material in the above-mentioned compositions is less, and the light-curing reaction rate is significantly improved.

Claim 1:
A composition for 3D inkjet printing of a support structure, wherein the composition comprises <NUM>-<NUM> parts by weight of a light-curable bulk material, <NUM>-<NUM> parts by weight of a functional reaction-promoting material, a non-curable water-miscible material, a photoinitiator and an auxiliary agent based on a total weight of the composition, the functional reaction-promoting material contains carboxyl group and reactive hydrogen in a molecular structure thereof, and the reactive hydrogen is capable of reacting with a peroxy free radical;
wherein the functional reaction-promoting material has a structure represented by the following general formula (I):
<CHM>
R<NUM>, R<NUM>, R<NUM> and R<NUM> are independently selected from at least one of the group consisting of hydrogen, hydroxyl, carboxyl, alkoxy, aryloxy, nitrogen-containing heterocyclic ring, oxygen-containing heterocyclic ring and benzene ring, and when R<NUM> is hydrogen, at least one of R<NUM> and R<NUM> is selected from hydrogen; and n and m are independently selected from an integer greater than or equal to <NUM>, n≤<NUM> and m≤<NUM>;
wherein the light-curable bulk material is a (meth) acrylate compound and/or a (meth) acrylamide compound.