Dispersing resin, universal color paste used for impregnating coating and preparation method therefor

Abstract

The present application relates to a dispersing resin, a universal color paste used for impregnating coating, and a preparation method therefor. The dispersing resin is prepared from a raw material including: diol, polyol, aromatic dicarboxylic acid, anhydride, maleic anhydride, polymerization inhibitor, reactive diluent, and azeotropic solvent.

Claims

1. A method for preparing a dispersing resin, wherein the dispersing resin is prepared from a raw material including by weight parts: 10-30 parts of diol, 5-20 parts of polyol, 10-30 parts of aromatic dicarboxylic acid and anhydride, 5-25 parts of maleic anhydride, 0.01-0.1 parts of polymerization inhibitor, 20-60 parts of reactive diluent, and 1-10 parts of azeotropic solvent; the method comprising: Step 1: introducing an inert gas into a reaction kettle, adding the diol, the polyol, the aromatic dicarboxylic acid and the anhydride into the reaction kettle, heating to a temperature of 180° C. under stirring and refluxing for 2-3 hours; Step 2: heating to a temperature of 210-220° C. and performing distillation to remove excess water; Step 3: lowering the temperature to 80° C., adding the maleic anhydride, the polymerization inhibitor and the azeotropic solvent into the kettle, heating to a temperature range of 190-200° C., shutting off the inert gas, recycling the azeotropic solvent and collecting water in a water separator, while detecting the acid value in the reaction system until reaching an acid value of lower than 10 mgKOH/g; Step 4: performing vacuum distillation after collecting the water to remove the azeotropic solvent; and Step 5: lowering the temperature to 90° C., adding the reactive diluent, and stirring for 20-40 min to provide a finished product.

Description

DESCRIPTION OF THE EMBODIMENTS

(1) The present application will be further described in detail below in connection with examples.

(2) Materials

(3) TABLE-US-00001 Material Purity Manufacturer Neopentyl glycol Technical purity I Guangzhou Henghu Trade Co., Ltd Ethylene glycol Technical purity I Zhengzhou Shengba Chemical Products Co., Ltd Glycerol Technical purity I Jinan Sanxiao Chemical Co., Ltd Isophthalic acid Technical purity I Jinan Aoxing Chemical Co., Ltd Maleic anhydride Technical purity I Jinan Tengbo Chemical Co., Ltd P-benzoquinone Technical purity I Nanjing lanbai Chemical Co., Ltd Xylene Technical purity I Ningbo Minxin Chemical Co., Ltd Styrene Technical purity I Nantong Taichang Chemical Raw Material Co., Ltd DPP Red Technical purity I Shenzhen Daxing Chemical Co., Ltd Wollastonite 800 mesh Yuyao Jushi New Material Co., Ltd Titanium white 800 mesh Henan Sanwei Chemical Products Co., Ltd Calcium carbonate 800 mesh Lingshou Yuncheng Mineral Products Co., Ltd Precipitated barium 800 mesh Zhejiang Changxing Hongyue Nonmetal sulfate Materials Co., Ltd Phthalo blue Technical purity I Zhengzhou Baixiang Chemical Co., Ltd Phthalo green Technical purity I Zhengzhou Baixiang Chemical Co., Ltd Permanent violet Technical purity I Zhengzhou Zhongrun Chemical Products Co., Ltd SL3012 electrical Technical purity I Zhuzhou Shilin Polymer Co., Ltd device pouring sealant

EXAMPLES

Example 1 Preparation of a Dispersing Resin

(4) Step 1: introducing nitrogen gas into a reaction kettle, sequentially adding 20 kg neopentyl glycol, 5 kg ethylene glycol, 5 kg glycerol, and 20 kg isophthalic acid into the kettle, heating to a temperature of 180° C. under stirring and refluxing for 2 hours;

(5) Step 2: heating to a temperature of 220° C. and performing distillation to remove excess water;

(6) Step 3: lowering the temperature to 80° C., adding 15 kg maleic anhydride, 0.02 kg p-benzoquinone and 6 kg xylene into the kettle, heating to a temperature range of 190-200° C., shutting off the nitrogen gas, recycling xylene, and collecting water in a water separator, while detecting the acid value in the reaction system until reaching an acid of lower than 10 mgKOH/g;

(7) Step 4: performing vacuum distillation after collecting the water to remove the xylene; and

(8) Step 5: lowering the temperature to 90° C., adding 35 kg styrene, stirring for 30 min to dissolve unsaturated resin completely in the styrene, filtering, and filling.

Example 2

(9) Example 2 differs from Example 1 in that 25 kg neopentyl glycol was added into the reaction kettle as a total amount of diol in Step 1.

Example 3

(10) Example 3 differs from Example 1 in that 25 kg ethylene glycol was added into the reaction kettle as a total amount of diol in Step 1.

Example 4

(11) Example 4 differs from Example 1 in that 10 kg neopentyl glycol was added into the reaction kettle as a total amount of diol in Step 1.

Example 5

(12) Example 5 differs from Example 1 in that 30 kg neopentyl glycol was added into the reaction kettle as a total amount of diol in Step 1.

Example 6

(13) Example 6 differs from Example 1 in that 20 kg styrene was added into the reaction kettle as a total amount of reactive diluent in Step 5.

Example 7

(14) Example 7 differs from Example 1 in that 60 kg styrene was added into the reaction kettle as a total amount of reactive diluent in Step 5.

Example 8

(15) Example 8 differs from Example 1 in that 10 kg glycerol was added into the reaction kettle as a total amount of polyol in Step 1.

Example 9

(16) Example 9 differs from Example 1 in that 20 kg glycerol was added into the reaction kettle as a total amount of polyol in Step 1.

Example 10

(17) Example 10 differs from Example 1 in that a total amount of 5 kg maleic anhydride was added in Step 3.

Example 11

(18) Example 11 differs from Example 1 in that a total amount of 25 kg maleic anhydride was added in Step 3.

Example 12 Preparation of a Dispersing Resin

(19) Step 1: introducing nitrogen gas into a reaction kettle, sequentially adding 15 kg neopentyl glycol, 10 kg ethylene glycol, 10 kg glycerol, and 25 kg isophthalic acid into the kettle, heating to a temperature of 180° C. under stirring and refluxing for 2 hours;

(20) Step 2: heating to a temperature of 220° C. and performing distillation to remove excess water;

(21) Step 3: lowering the temperature to 80° C., adding 10 kg maleic anhydride and 0.01 kg p-benzoquinone into the kettle, heating to a temperature range of 190-200° C., shutting off the nitrogen gas, adding 7 kg xylene, recycling the xylene and collecting water in a water separator, while detecting the acid value in the reaction system until reaching an acid of lower than 10 mgKOH/g;

(22) Step 4: performing vacuum distillation after collecting the water to remove the xylene; and

(23) Step 5: lowering the temperature to 90° C., adding 40 kg styrene, stirring for 30 min to dissolve unsaturated resin completely in the styrene, filtering, and filling.

Example 13 Preparation of a Dispersing Resin

(24) Step 1: introducing nitrogen gas into a reaction kettle to remove oxygen, sequentially adding 18 kg neopentyl glycol, 7 kg ethylene glycol, 10 kg glycerol, and 25 kg isophthalic acid into the kettle, heating to a temperature of 180° C. under stirring and refluxing for 2 hours;

(25) Step 2: heating to a temperature of 220° C. and performing distillation to remove excess water;

(26) Step 3: lowering the temperature to 80° C., adding 8 kg maleic anhydride, 0.02 kg p-benzoquinone, and 5 kg xylene into the kettle, heating to a temperature range of 190-200° C., shutting off the nitrogen gas, recycling xylene and collecting water in a water separator, while detecting the acid value in the reaction system until reaching an acid of lower than 10 mgKOH/g;

(27) Step 4: performing vacuum distillation after collecting the water to remove the xylene; and

(28) Step 5: lowering the temperature to 90° C., adding 40 kg styrene, stirring for 30 min to dissolve unsaturated resin completely in the styrene, filtering, and filling.

Example 14 Preparation of a Dispersing Resin

(29) Step 1: introducing nitrogen gas into a reaction kettle to remove oxygen, sequentially adding 15 kg neopentyl glycol, 10 kg ethylene glycol, 8 kg glycerol, and 15 kg isophthalic acid into the kettle, heating to a temperature of 180° C. under stirring and refluxing for 2 hours;

(30) Step 2: heating to a temperature of 220° C. and performing distillation to remove excess water;

(31) Step 3: lowering the temperature to 80° C., adding 12 kg maleic anhydride, 0.02 kg p-benzoquinone and 5 kg xylene into the kettle, heating to a temperature range of 190-200° C., shutting off the nitrogen gas, recycling xylene and collecting water in a water separator, while detecting the acid value in the reaction system until reaching an acid of lower than 10 mgKOH/g;

(32) Step 4: performing vacuum distillation after collecting the water to remove the xylene; and

(33) Step 5: lowering the temperature to 90° C., adding 35 kg styrene, stirring for 30 min to dissolve unsaturated resin completely in the styrene, filtering, and filling.

Example 15

(34) A universal color paste used for a impregnating coating was prepared from 20 kg dispersing resin prepared in Example 1, 20 kg titanium white, and 60 kg styrene. The preparation method includes: introducing nitrogen gas into a reaction kettle, adding 20 kg dispersing resin prepared in Example 1 under stirring, adding 60 kg styrene and then 20 kg titanium white at a speed of 1 kg/min, filtering and filling to obtain the universal color paste used for a impregnating coating.

Example 16

(35) Example 16 differs from Example 15 in that, 5 kg wollastonite and 5 kg titanium white were used in replace of 10 kg titanium white used in Example 15.

Example 17

(36) Example 17 differs from Example 15 in that, 3.333 kg wollastonite, 3.333 kg titanium white and 3.333 kg calcium carbonate were used in replace of 10 kg titanium white used in Example 15.

Example 18

(37) Example 18 differs from Example 15 in that, 2.5 kg wollastonite, 2.5 kg titanium white, 2.5 kg calcium carbonate and 2.5 kg precipitated barium sulfate were used in replace of 10 kg titanium white used in Example 15.

Example 19

(38) A universal color paste used for a impregnating coating was prepared from 20 kg dispersing resin prepared in Example 1, 20 kg Phthalo blue and 60 kg styrene. The preparation method comprises: introducing nitrogen gas into a reaction kettle, adding 20 kg dispersing resin prepared in Example 1 under stirring, adding 60 kg styrene and then 20 kg Phthalo blue at a speed of 1 kg/min, filtering and filling to obtain the universal color paste A used for a impregnating coating.

Example 20

(39) Example 20 differs from Example 19 in that 10 kg Phthalo blue and 10 kg DPP were used in replace of 20 kg Phthalo blue used in Example 19.

Example 21

(40) Example 21 differs from Example 19 in that 6.667 kg Phthalo blue, 6.667 kg DPP, and 6.667 kg Phthalo green were used in replace of 20 kg Phthalo blue used in Example 19.

Example 22

(41) Example 22 differs from Example 19 in that 5 kg Phthalo blue, 5 kg DPP, 5 kg Phthalo green and 5 kg permanent violet were used in replace of 20 kg Phthalo blue used in Example 19.

COMPARISON EXAMPLES

Comparison Example 1

(42) Comparison Example 1 differs from Example 1 in that 4 kg glycerol was added into the reaction kettle in Step 1 as a total amount of polyol.

Comparison Example 2

(43) Comparison Example 2 differs from Example 1 in that 25 kg glycerol was added into the reaction kettle in Step 1 as a total amount of polyol.

Comparison Example 3

(44) Comparison Example 3 differs from Example 1 in that 8 kg isophthalic acid was added into the reaction kettle in Step 1 as a total amount of aromatic dicarboxylic acid and anhydride.

Comparison Example 4

(45) Comparison Example 4 differs from Example 1 in that 35 kg isophthalic acid was added into the reaction kettle in Step 1 as a total amount of aromatic dicarboxylic acid and anhydride.

Comparison Example 5

(46) Comparison Example 5 differs from Example 1 in that 10 kg styrene was added in Step 5 as a total amount of reactive diluent.

Comparison Example 6

(47) Comparison Example 6 differs from Example 1 in that 70 kg styrene was added in Step 5 as a total amount of reactive diluent.

Comparison Example 7

(48) Comparison Example 7 differs from Example 1 in that 8 kg neopentyl glycol was added into the reaction kettle in Step 1 as a total amount of diol.

Comparison Example 8

(49) Comparison Example 8 differs from Example 1 in that 40 kg neopentyl glycol was added into the reaction kettle in Step 1 as a total amount of diol.

Comparison Example 9

(50) Comparison Example 9 differs from Example 1 in that 4 kg maleic anhydride was added in Step 3.

Comparison Example 10

(51) Comparison Example 10 differs from Example 1 in that 30 kg maleic anhydride was added in Step 3.

Comparison Example 11

(52) A universal color paste used for a impregnating coating was prepared from 20 kg dispersing resin prepared in Comparison Example 1, 20 kg titanium white, and 60 kg styrene. The preparation method comprises: introducing nitrogen gas into a reaction kettle, adding 20 kg dispersing resin prepared in Comparison Example 1 under stirring, adding 60 kg styrene and then 20 kg titanium white at a speed of 1 kg/min, filtering and filling to obtain the universal color paste used for a impregnating coating.

Comparison Example 12

(53) A universal color paste used for a impregnating coating was prepared from 20 kg dispersing resin prepared in Comparison Example 1, 20 kg DPP, and 60 kg styrene. The preparation method comprises: introducing nitrogen gas into a reaction kettle, adding 20 kg dispersing resin prepared in Comparison Example 1 under stirring, adding 60 kg styrene and then 20 kg DPP at a speed of 1 kg/min, filtering and filling to obtain the universal color paste used for a impregnating coating.

(54) 1. Performance Test

(55) The dispersing resins prepared according to Examples 1-14 of the present application and Comparison Examples 1-10 were prepared into universal color pastes, and tested regarding relevant performances thereof for evaluating the obtained dispersing resins. The universal color pastes were made by the following steps.

(56) Step 1: premixing the dispersing resins, the pigments and the reactive diluent at a high speed of stirring for 30 min to provide a semi-finished product; and

(57) Step 2: sand grinding the semi-finished products while monitoring the fineness thereof, stopping the grinding when the fineness was <5 μm, and measuring the viscosity of the semi-finished color pastes.

(58) The pigments can be selected according to actual needs. For example, an inorganic pigment can be selected from the group consisting of titanium white, wollastonite, calcium carbonate, boron nitride, ferric yellow, precipitated barium sulfate, etc. An organic pigment can be selected from the group consisting of Phthalo blue, Phthalo green, DPP Red, and permanent violet. The weight parts or proportions of the universal color paints can be selected based on the kinds of the pigments, for example, being as follow:

(59) TABLE-US-00002 Dispersing resin 20-30 parts 20-35 parts Organic pigment 10-20 parts / Inorganic pigment / 25-45 parts Reactive diluent 50-65 parts 20-30 parts

(60) The performances of the universal color paints were evaluated by dispersivity of pigments, viscosity of the color pastes, and the time stability of the color pastes. Color pastes were prepared by using the dispersing resins prepared according to Examples 1-14 and Comparison Examples 1-10, and were tested regarding the appearance, viscosity and fineness thereof at the beginning and after high temperature storage (30 days at 50° C.) and the longest storage period of individual color pastes before having a change in appearance when being stored at high temperature (50° C.). In particular, the appearance was evaluated via naked eyes; the viscosity was measured by using Brookfield Viscometer; and the fineness was measured by using QXD-50 single-groove grindometer available from Xiandai Environment.

(61) 2. Thermal Shock Test

(62) Example Samples 1-14 and Comparison Samples 1-10 were prepared from 5 weight parts of the universal color pastes prepared from the dispersing resins prepared from Examples 1-14 and Comparison Examples 1-10 and 25 weight parts of SL3012 electrical device pouring sealant.

(63) 40 groups of test samples were prepared, each group of which included Example Samples 1-14 and Comparison Samples 1-10, and was subjected to the thermal shock test individually. The number of the thermal shock was increased gradually from the 1.sup.st group to the 40.sup.th group.

(64) Firstly, the test samples were pre-treated, that is, being placed under a normal test atmosphere until reaching a stable temperature.

(65) Secondly, initial detection was performed, that is, the test samples were compared with standard requirements, and the samples meeting the requirements were directly placed into a thermal shock chamber.

(66) Then, each group of the test samples was subjected to a thermal shock test for one time, which included:

(67) Step 1) placing the test samples into the chamber, raising the temperature in the chamber, and keeping the temperature for some time until the test samples reached a stable temperature;

(68) Step 2) performing a low temperature shock, including transferring the test samples to a low temperature shock chamber at −40° C. within 5 min and keeping them in the chamber for 1 hour or until the test samples reached a stable temperature;

(69) Step 3) performing a high temperature shock, including transferring the test samples to a high temperature shock chamber at 150° C. within 5 min and keeping them in the chamber for 1 hour or until the test samples reached a stable temperature;

(70) 4) repeating the thermal shock from Step 1) to Step 3) for desired times. It is to be noted that the time can be slightly adjusted according to the size of the samples or the volume of the space.

(71) Secondly, the test samples were removed from the chamber, and placed under a normal test atmosphere so as to reach a stable temperature.

(72) Finally, the test samples were detected regarding a cracking.

(73) Table 1 shows whether the samples suffer from crack after being subjected to thermal shocks from −40° C. to 150° C.

(74) 3. Glass Transition Temperature (Tg) of the Test Samples

(75) Glass transition temperature (Tg) refers to the transition temperature between glass state and rubber state of polymer materials. When the temperature is below Tg, the material is in glassy state in which the molecular chain and the chain segments can not move; while above Tg, the material is in rubber state in which the chain segments are moving. Mechanical and electrical properties of the material will change suddenly at Tg. Thus, Tg is an important indicator for the heat resistance of the material. The Tg values of the samples are listed in the last column of Table 3.

(76) Test Method

(77) TABLE-US-00003 TABLE 1 Performances of the color paste compositions prepared in Examples 1-7 Example 1 Example 2 Example 3 Example 4 Example 5 Example 6 Example 7 Acid value mgK0H/g  9  8  8  4  9  6  6 Viscosity after dilution 2200  2000  2000  1600  2100  2400  1100  Dispersion resin 20 parts 20 parts 20 parts 20 parts 20 parts 20 parts 20 parts DPP Red 20 parts 20 parts 20 parts 20 parts 20 parts 20 parts 20 parts Styrene 60 parts 60 parts 60 parts 60 parts 60 parts 60 parts 60 parts Initial appearance Normal Normal Normal Normal Normal Normal Normal Fineness (μm) <5 <5 <5 <5 <5 <5 <5 Initial viscosity Normal Normal Normal Normal Normal Normal Normal Appearance after storage Normal Normal Normal Normal Normal Normal Normal Fineness after storage <5 μm <5 μm <5 μm <5 μm <5 μm <5 μm <5 μm Viscosity after storage Normal Normal Normal Normal Normal Normal Normal Longest storage period 192  168  172  162  160  176  155  1-10 shocks No No No No No No No 10-20 shocks No No No No No No No 20-30 shocks No No No No No No No 30-40 shocks No No No No No No No Crackings during shock 88 69 72 63 59 57 63 Tg/° C.  131.6  118.9  116.5  109.5  112.3  113.6  103.6

(78) TABLE-US-00004 TABLE 2 Performance of the of the color paste compositions prepared in Examples 8-14 Example 8 Example 9 Example 10 Example 11 Example 12 Example 13 Example 14 Acid value mgK0H/g  6  4  7  4  6  5  4 Viscosity after dilution 1600  1400  1900  1300  1800  2000  160  Dispersing resin 20 parts 20 parts 20 parts 20 parts 20 parts 20 parts 20 parts DPP Red 20 parts 20 parts 20 parts 20 parts 20 parts 20 parts 20 parts Styrene 60 parts 60 parts 60 parts 60 parts 60 parts 60 parts 60 parts Initial appearance Normal Normal Normal Normal Normal Normal Normal Fineness (μm) <5 <5 <5 <5 <5 <5 <5 Initial viscosity Normal Normal Normal Normal Normal Normal Normal Appearance after storage Normal Normal Normal Normal Normal Normal Normal Fineness after storage <5 μm <5 μm <5 μm <5 μm <5 μm <5 μm <5 μm Viscosity after storage Normal Normal Normal Normal Normal Normal Normal Longest storage period 165  170  158  177  189  185  188  1-10 shocks No No No No No No No 10-20 shocks No No No No No No No 20-30 shocks No No No No No No No 30-40 shocks No No No No No No No Crackings during shock 72 67 71 69 85 83 85 Tg  117.3  113.3  103.8  115.3  128.9  127.5  128.5

(79) TABLE-US-00005 TABLE 3 Performance of the color paste compositions prepared in Comparison Examples 1-5 Comparison Comparison Comparison Comparison Comparison Example 1 Example 2 Example 3 Example 4 Example 5 Acid value mgK0H/g  4  5  6  4  6 Viscosity after 1700  1800  1600  1400  2400  dilution Dispersing resin 20 parts 20 parts 20 parts 20 parts 20 parts DPP Red 20 parts 20 parts 20 parts 20 parts 20 parts Styrene 60 parts 60 parts 60 parts 60 parts 60 parts Initial appearance Normal Normal Normal Normal Normal Fineness (μm) <5 <5 <5 <5 <5 Initial viscosity Normal Normal Normal Normal Normal Appearance after Severe Flocculation Severe Flocculation Severe storage settlement settlement settlement Fineness after >50 μm >20 μm >50 μm >20 μm >50 μm storage Viscosity after Thickening Severe Thickening Severe Thickening storage thickening thickening Longest storage 36 41 45 43 36 period 1-10 shocks No Yes No No No 10-20 shocks Yes / Yes Yes Yes 20-30 shocks / / No / / 30-40 shocks / / / / / Crackings during 13  8 16 13 11 shock Tg ° C.   87.6   84.1   91.2   88.5   92.3

(80) TABLE-US-00006 TABLE 4 Performance of the color paste compositions prepared in Comparison Example 6-10 Comparison Comparison Comparison Comparison Comparison Example 6 Example 7 Example 8 Example 9 Example 10 Acid value mgK0H/g  7  5  7  7  4 Viscosity after 900  1700  2000  1600  1800  dilution Dispersing resin 20 parts 20 parts 20 parts 20 parts 20 parts DPP Red 20 parts 20 parts 20 parts 20 parts 20 parts Styrene 60 parts 60 parts 60 parts 60 parts 60 parts Initial appearance Normal Normal Normal Normal Normal Fineness (μm) <5 <5 <5 <5 <5 Initial viscosity Normal Normal Normal Normal Normal Appearance after Severe Severe Flocculation Severe Flocculation storage settlement settlement settlement Fineness after >50 μm >50 μm >20 μm >50 μm >20 μm storage Viscosity after Thickening Thickening Severe Thickening Severe storage thickening thickening Longest storage 33 38 39 46 43 period 1-10 shocks Yes Yes Yes No Yes 10-20 shocks / / / Yes / 20-30 shocks / / / / / 30-40 shocks / / / / / Crackings during  7  9  6 15  8 shock Tg   90.5   88.9   87.6   93.2   92.5

(81) TABLE-US-00007 TABLE 5 Testing parameters of Example Samples 1-14 and Comparison Samples 1-10 1-10 10-20 20-30 Crackings Tg/ shocks shocks shocks during shock ° C. Example Sample 1 Yes Yes Yes 76 111.6 Example Sample 2 Yes Yes Yes 63 101.9 Example Sample 3 Yes Yes Yes 61 107.5 Example Sample 4 Yes Yes Yes 59 103.5 Example Sample 5 Yes Yes Yes 61 102.3 Example Sample 6 Yes Yes Yes 59 103.6 Example Sample 7 Yes Yes Yes 63 103.6 Example Sample 8 Yes Yes Yes 69 107.3 Example Sample 9 Yes Yes Yes 67 103.3 Example Sample 10 Yes Yes Yes 71 103.8 Example Sample 11 Yes Yes Yes 69 105.8 Example Sample 12 Yes Yes Yes 73 109.9 Example Sample 13 Yes Yes Yes 74 110.5 Example Sample 14 Yes Yes Yes 71 108.8 Comparison Example Yes Yes No 53 86.6 Sample 1 Comparison Example No Yes No 45 84.1 Sample 2 Comparison Example Yes Yes No 48 91.2 Sample 3 Comparison Example Yes Yes No 46 88.5 Sample 4 Comparison Example Yes Yes No 51 92.3 Sample 5 Comparison Example No Yes No 48 90.5 Sample 6 Comparison Example No Yes No 46 88.9 Sample 7 Comparison Example No Yes No 43 87.6 Sample 8 Comparison Example Yes Yes No 47 93.2 Sample 9 Comparison Example Yes Yes No 48 92.5 Sample 10

(82) TABLE-US-00008 TABLE 6 Testing parameters of Example Samples 15-22 and Comparison Samples 11-12 Acid value Fineness Appearance Longest and Viscosity Initial and Initial after storage storage after dilution appearance viscosity and Fineness period Comparison 4 mgK0H/g Normal Normal; <5 Severe  35 days Example 11 1700 mPas μm settlement; >50 μm Comparison 5 mgK0H/g Normal Normal; <5 Severe  42 days Example 12 1800 mPas μm settlement; >20 μm Example 15 9 mgK0H/g Normal Normal; <5 Normal; <5 188 days 2200 mPas μm μm Example 16 9 mgK0H/g Normal Normal; <5 Normal; <5 185 days 2200 mPas μm μm Example 17 9 mgK0H/g Normal Normal; <5 Normal; <5 195 days 2200 mPas μm μm Example 18 9 mgK0H/g Normal Normal; <5 Normal; <5 192 days 2200 mPas μm μm Example 19 9 mgK0H/g Normal Normal; <5 Normal; <5 187 days 2200 mPas μm μm Example 20 9 mgK0H/g Normal Normal; <5 Normal; <5 188 days 2200 mPas μm μm Example 21 9 mgK0H/g Normal Normal; <5 Normal; <5 190 days 2200 mPas μm μm Example 22 9 mgK0H/g Normal Normal; <5 Normal; <5 183 days 2200 mPas μm μm

(83) From Table 1 and Table 4, it can be seen that, the dispersing resins prepared in Examples 4 and 5 are superior in performance to those prepared in Comparison Examples 7 and 8, which shows that 10-30 weight parts of the diols in the product will be preferable. The dispersing resin prepared in Example 1 is superior in performance to those prepared in Examples 2-5, which shows that 20 weight parts of neopentyl glycol and 5 weight parts of ethylene glycol are preferable.

(84) From Table 1, Table 4 and Table 5, it can be seen that the thermal shock resistance and the heat resistance of the pouring sealants prepared from the dispersing resins prepared in Example 4 and Example 5 are superior to those of the pouring sealants prepared from the dispersing resins prepared in Comparison Example 7 and Comparison Example 8. Therefore, preparing an electrical device pouring sealant from the dispersing resins according to the present application can improve the toughness and heat resistance of the pouring sealant. In particular, 20 weight parts of neopentyl glycol and 5 weight parts of ethylene glycol as a diol are preferable in the product.

(85) From Table 1, Table 3 and Table 4, it can be seen that the dispersing resins prepared in Example 1, Example 6 and Example 7 are superior in performance to those prepared in Comparison Example 5 and Comparison Example 6. Therefore, 20-60 weight parts of reactive diluent in the product is preferable. The dispersing resin prepared in Example 1 is superior in performance to those prepared in Comparison Example 6 and Comparison Example 7. Therefore, 35 weight parts of styrene as reactive diluent in the product is preferable.

(86) From Table 1, Table 4 and Table 5, it can be seen that the thermal shock resistance and the heat resistance of the pouring sealants prepared from the dispersing resins prepared in Example 1, Example 6 and Example 7 are superior to those of the pouring sealants prepared from the dispersing resins prepared in Comparison Example 5 and Comparison Example 6. Therefore, preparing an electrical device pouring sealant from the dispersing resins according to the present application can improve the toughness and heat resistance of the pouring sealant. In particular, 35 weight parts of styrene as a reactive diluent is preferable in the product.

(87) From Table 1, Table 2 and Table 3, it can be seen that the dispersing resins prepared in Example 1, Example 8 and Example 9 are superior in performance to those prepared in Comparison Example 1 and Comparison Example 2. Therefore, 5-20 weight parts of polyol in the product is preferable. The dispersing resin prepared in Example 1 is superior in performance to those prepared in Comparison Example 8 and Comparison Example 9. Therefore, 5 weight parts of glycerol as polyol in the product is preferable.

(88) From Table 1, Table 4 and Table 5, it can be seen that the thermal shock resistance and the heat resistance of the pouring sealants prepared from the dispersing resins prepared in Example 1, Example 8 and Example 9 are superior to those of the pouring sealants prepared from the dispersing resins prepared in Comparison Example 1 and Comparison Example 2. Therefore, preparing an electrical device pouring sealant from the dispersing resins according to the present application can improve the toughness and heat resistance of the pouring sealant. In particular, 5 weight parts of glycerol as a polyol is preferable in the product.

(89) From Table 1, Table 2 and Table 3, it can be seen that the dispersing resins prepared in Example 1, Example 10 and Example 11 are superior in performance to those prepared in Comparison Example 1 and Comparison Example 2. Therefore, 5-25 weight parts of maleic anhydride in the product is preferable. The dispersing resin prepared in Example 1 is superior in performance to those prepared in Comparison Example 10 and Comparison Example 11. Therefore, 15 weight parts of maleic anhydride in the product is preferable.

(90) From Table 1, Table 4 and Table 5, it can be seen that the thermal shock resistance and the heat resistance of the pouring sealants prepared from the dispersing resins prepared in Example 1, Example 10 and Example 11 are superior to those of the pouring sealants prepared from the dispersing resins prepared in Comparison Example 1 and Comparison Example 2. Therefore, preparing an electrical device pouring sealant from the dispersing resins according to the present application can improve the toughness and heat resistance of the pouring sealant. In particular, 15 weight parts of maleic anhydride is preferable in the product.

(91) From Table 1 and Table 2, the performance of the dispersing resin prepared in Example 1 is similar to those prepared in Example 12, Example 13 and Example 14. Therefore, the formulations provided in Example 12, Example 13 and Example 14 can provide good quality product.

(92) From Table 1, Table 4 and Table 5, it can be seen that the thermal shock resistance and the heat resistance of the pouring sealants prepared from the dispersing resins prepared in Example 1 are similar to those of the pouring sealants prepared from the dispersing resins prepared in Example 12, Example 13 and Example 14. Therefore, the formulations provided in Example 12, Example 13 and Example 14 can provide good quality product, and the heat resistance and the thermal shock resistance of the electrical device pouring sealants prepared by these products are improved.

(93) From Table 6, it can be seen that the universal color pastes prepared in Examples 15-22 have a better storage performance than those prepared in Comparison Example 11 and Comparison Example 12. Therefore, the dispersing resins provided by the present application has excellent compatibility, and can be mixed with a plurality of organic pigments to prepare universal color pastes having good storage performance.