CN106189020A - A kind of degradable photoelectric material used for solar batteries - Google Patents
A kind of degradable photoelectric material used for solar batteries Download PDFInfo
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Abstract
The invention discloses a kind of degradable photoelectric material used for solar batteries, in units of weight, it is made up of following raw material: acrylic resin 32 56 parts, hydracrylic acid valeric acid copolyesters 18 34 parts, VCz 12 20 parts, bentonite 10 18 parts, calcium stearate 8 15 parts, sodium silicate 8 12 parts, corn stalk fiber 69 parts, polylactic acid 7 12 parts, dehydroactic acid 68 parts, degradation agent 57 parts, synthetics 6 10 parts, starch adesive 46 parts, antibacterial 23 parts, stabilizer I 12 parts, ultraviolet absorber 12 parts.The degradable photoelectric material toxicity used for solar batteries of the present invention is little, and environmental pollution is little, degradable, and photoelectric transformation efficiency is high, and production cost is low, beneficially popularization and application.
Description
[technical field]
The invention belongs to technical field of new energies and solar cell material lead for technology, be specifically related to a kind of used for solar batteries
Degradable photoelectric material.
[background technology]
The energy of shortage has had a strong impact on life and the development of restriction society of people.Abundant solar energy is important cleaning energy
Source, is the energy that can freely utilize of inexhaustible, nexhaustible, pollution-free, cheap, the mankind.The first oil crisis it
After, various countries competitively carry out answering of cleaning and the applied researcies of regenerative resource, especially solar energy such as solar energy, water energy, wind energy
The most extensive with research.
Solar energy does not has any nonstaining property as a kind of green energy resource to environment, and its source is simple, it may be said that
It is that it is inexhaustible in the existence time limit of the mankind.Solar energy is not only the disposable energy, or cleaning energy
Source, its aboundresources, generally exist, without transporting, also can freely use, the most important thing is environment is not had any pollution.Too
Sun also can have the advantage not available for other generation modes many because of the particularity of solar energy by battery: without geographical restrictions, no
Consume fuel, scale is changeable, motility is big, pollution-free, noiselessness, safe and reliable, the construction period is short, safeguard simply,
There is the probability of large-scale application.So a lot of experts go solar energy to exploitation as the alternative energy, it is desirable to too
Sun can be brought benefit to the mankind.Nowadays the solar energy used have greatly by solar cell conversion get.Because
Solaode has sensing to light, it is possible to the luminous energy being radiated at its surface is converted to electric energy.At present, in the effort of relevant expert
Under, solaode is own through having moved towards commercialization and industrialization.
Solaode is the important device realizing opto-electronic conversion, and the most important principle wherein used is exactly photoproduction volt
Specially good effect is answered, so solaode is also referred to as photovoltaic cell.When sunlight or other light good fortune are mapped on semi-conducting material,
Valence-band electrons can absorb the photon energy of a part, and electronics is stimulated after obtaining energy and transits to conduction band, thus can be in valence band
Form a hole, and conduction band has more an electronics, form electron hole pair.Due to when P-type semiconductor and N type quasiconductor phase
Forming P-N junction during contact, the diffusion of many sons in P-type semiconductor and formation space-charge region, N-type semiconductor contact position, and can go out
The built in field being pointed to p-type by N-type of an existing continuous enhancing, thus produce the drift current of few son.Diffusion electricity when many sons
When the drift current of stream and few son is equal, form dynamic equilibrium.Therefore solaode plays the photoelectric material of pivotal role
Decide the efficiency of solar energy.More and more deep for solar cell material research at present, mostly it is devoted to improve solar energy
The photoelectric transformation efficiency of battery, but the various motor material serious environment pollution containing the heavy metal element such as chromium, stannum, the discarded sun
The recovery of energy battery is good problem to study, is therefore badly in need of exploitation novel degradable photoelectric material.
[summary of the invention]
The present invention provides a kind of degradable photoelectric material used for solar batteries, is difficult to degrade solving existing photoelectric material, contains
The heavy metal element serious environment pollution such as chromium, stannum, and the recycling high in cost of production problem of discarded solaode.The present invention
Degradable photoelectric material toxicity used for solar batteries little, environmental pollution is little, degradable, and photoelectric transformation efficiency is high, produces into
This is low, beneficially popularization and application.
For solve above technical problem, the present invention by the following technical solutions:
A kind of degradable photoelectric material used for solar batteries, in units of weight, is made up of following raw material: acrylic resin
32-56 part, hydracrylic acid valeric acid copolyesters 18-34 part, VCz 12-20 part, bentonite 10-18 part, calcium stearate 8-
15 parts, sodium silicate 8-12 part, corn stalk fiber 6-9 part, polylactic acid 7-12 part, dehydroactic acid 6-8 part, degradation agent 5-7 part, conjunction
Become agent 6-10 part, starch adesive 4-6 part, antibacterial 2-3 part, stabilizer I 1-2 part, ultraviolet absorber 1-2 part;
Described degradation agent, in units of weight, is made up of following raw material: ammonium phosphate 2-2.4 part, amino trimethylene ethylphosphonic acid 1.2-
1.6 parts, ethylenediamine tetramethylenephosphonic acid 1-1.4 part, dodecyl dimethyl benzyl ammonium bromide 0.6-1.2 part, titanium dioxide 0.2-0.4
Part;
Described synthetics, in units of weight portion, is made up of following raw material: propellant 0.6-1.2 part, coupling agent 1-1.8 part, phase
Hold agent 0.8-1.4 part, regulator 0.6-1 part, hardening agent 0.6-1 part, flocculation agent 1-1.5 part, plasticizer 1-1.4 part, stabilizer
II 0.2-0.4 part, terminator 0.2-0.3 part;
Described propellant is aerogel generating agent, and described coupling agent is epoxy silane class coupling agent, and described compatilizer is maleic acid
Acid anhydride grafting compatilizer, described regulator is processing aids acrylic resin, and described hardening agent is 701 powder hardening agents, described coacervation
Agent is aluminium polychlorid;
Described starch adesive, in units of weight portion, is made up of following raw material: starch 1.2-1.8 part, dimethyl adipate 1-
1.6 parts, amide dimethyl butyrate 0.8-1.2 part, barium hydroxide 0.4-0.6 part, epoxychloropropane 0.6-0.8 part;
The preparation method of described degradable photoelectric material used for solar batteries, comprises the following steps:
S1: add polylactic acid, dehydroactic acid after acrylic resin, hydracrylic acid valeric acid copolyesters, VCz mixing,
Rotating speed is that under 80-150r/min, stirring is warming up to 78 DEG C, keeps temperature-resistant lower continuation to stir 3-5min by 80-150r/min,
Prepare suspension;
S2: the suspension prepared to step S1 adds bentonite, calcium stearate, sodium silicate, corn stalk fiber, synthetics, control
Temperature processed is 135-150 DEG C, stirs 1-3h, prepare miscible fluid I under rotating speed is 100-200r/min;
The preparation method of described synthetics, comprises the following steps:
S21: propellant, coupling agent, compatilizer mixing are warming up to 120-135 DEG C, react under rotating speed is 200-300r/min
40-60 min, prepares material I;
S22: be warming up to 150-160 DEG C after adding regulator, hardening agent, flocculation agent mixing in the material I that step S21 prepares,
Under rotating speed is 300-400r/min, reacts 150-180 min, prepares material II;
S23: be cooled to 110-120 after adding plasticizer, stabilizer II, terminator mixing in the material II that step S22 prepares
DEG C, under rotating speed is 200-300r/min, reacts 60-90 min, prepares synthetics;
S3: add degradation agent, starch adesive, antibacterial after the miscible fluid I that step S2 prepares is cooled to 42-45 DEG C, stablize
Agent I, ultraviolet absorber, be placed in ultrasonic response still, reacts 20-30min under power 100-300W, and warp is 65-in temperature
It is dried at 78 DEG C, prepares the degradable photoelectric material used for solar batteries of moisture content≤7%;
The preparation method of described starch adesive, comprises the following steps:
S31: compound concentration is the starch slurry I of 30-35Be ';
S32: it is the dimethyl adipate of 3%-5%, amide dimethyl butyrate that the para arrowroot slurry I in step S31 adds concentration, so
After be 35-38 DEG C in temperature, speed of agitator be carry out under 60-80r/min cross-linked graft reaction 1-1.5h, prepare slurry II;
S33: add barium hydroxide and epoxychloropropane in the slurry II of step S32, be then 40-45 DEG C in temperature, stirring
Rotating speed is to carry out cross-linking reaction 0.4-0.6h under 60-80r/min, prepares slurry III;
S34: the slurry III of step S33 carried out pre-gelatinized and is dried at temperature is 105-125 DEG C, preparing moisture content≤8%
Material IV;
S35: the material IV of step S34 is pulverized, crosses 100-120 mesh sieve, prepare starch adesive.
Further, described plasticizer is dioctyl adipate.
Further, described stabilizer II is fat acids stabilizer.
Further, described terminator is styrene.
Further, described antibacterial is isothiazolone derivative.
Further, described stabilizer I is light stabilizer 783.
Further, described ultraviolet absorber is ESCALOL 567.
The method have the advantages that
(1) the degradable photoelectric material toxicity used for solar batteries of the present invention is little, and environmental pollution is little, degradable, is a kind of ring
Guarantor's type photoelectric material;
(2) heat decomposition temperature of the degradable photoelectric material used for solar batteries of the present invention is high, reaches more than 560 DEG C, uses soil
Earth landfill method buries the degradable photoelectric material used for solar batteries of the present invention, and after 1 year, degradation rate reaches more than 89%;
(3) the degradable photoelectric material used for solar batteries of the present invention has dual electric conductivity, and photoelectric transformation efficiency is high, and
And weight is relatively light, production cost is low.
[detailed description of the invention]
For ease of being more fully understood that the present invention, being illustrated by following example, these embodiments belong to the protection of the present invention
Scope, but it is not intended to protection scope of the present invention.
In an embodiment, described degradable photoelectric material used for solar batteries, in units of weight, by following raw material system
Become: acrylic resin 32-56 part, hydracrylic acid valeric acid copolyesters 18-34 part, VCz 12-20 part, bentonite 10-18
Part, calcium stearate 8-15 part, sodium silicate 8-12 part, corn stalk fiber 6-9 part, polylactic acid 7-12 part, dehydroactic acid 6-8 part,
Degradation agent 5-7 part, synthetics 6-10 part, starch adesive 4-6 part, antibacterial 2-3 part, stabilizer I 1-2 part, ultraviolet absorber
1-2 part;
Described degradation agent, in units of weight, is made up of following raw material: ammonium phosphate 2-2.4 part, amino trimethylene ethylphosphonic acid 1.2-
1.6 parts, ethylenediamine tetramethylenephosphonic acid 1-1.4 part, dodecyl dimethyl benzyl ammonium bromide 0.6-1.2 part, titanium dioxide 0.2-0.4
Part;
Described synthetics, in units of weight portion, is made up of following raw material: propellant 0.6-1.2 part, coupling agent 1-1.8 part, phase
Hold agent 0.8-1.4 part, regulator 0.6-1 part, hardening agent 0.6-1 part, flocculation agent 1-1.5 part, plasticizer 1-1.4 part, stabilizer
II 0.2-0.4 part, terminator 0.2-0.3 part;
Described propellant is aerogel generating agent, and described coupling agent is epoxy silane class coupling agent, and described compatilizer is maleic acid
Acid anhydride grafting compatilizer, described regulator is processing aids acrylic resin, and described hardening agent is 701 powder hardening agents, described coacervation
Agent is aluminium polychlorid, and described plasticizer is dioctyl adipate, and described stabilizer II is fat acids stabilizer, described terminator
For styrene;
Described starch adesive, in units of weight portion, is made up of following raw material: starch 1.2-1.8 part, dimethyl adipate 1-
1.6 parts, amide dimethyl butyrate 0.8-1.2 part, barium hydroxide 0.4-0.6 part, epoxychloropropane 0.6-0.8 part;
Described antibacterial is isothiazolone derivative;
Described stabilizer I is light stabilizer 783;
Described ultraviolet absorber is ESCALOL 567;
The preparation method of described degradable photoelectric material used for solar batteries, comprises the following steps:
S1: add polylactic acid, dehydroactic acid after acrylic resin, hydracrylic acid valeric acid copolyesters, VCz mixing,
Rotating speed is that under 80-150r/min, stirring is warming up to 78 DEG C, keeps temperature-resistant lower continuation to stir 3-5min by 80-150r/min,
Prepare suspension;
S2: the suspension prepared to step S1 adds bentonite, calcium stearate, sodium silicate, corn stalk fiber, synthetics, control
Temperature processed is 135-150 DEG C, stirs 1-3h, prepare miscible fluid I under rotating speed is 100-200r/min;
The preparation method of described synthetics, comprises the following steps:
S21: propellant, coupling agent, compatilizer mixing are warming up to 120-135 DEG C, react under rotating speed is 200-300r/min
40-60 min, prepares material I;
S22: be warming up to 150-160 DEG C after adding regulator, hardening agent, flocculation agent mixing in the material I that step S21 prepares,
Under rotating speed is 300-400r/min, reacts 150-180 min, prepares material II;
S23: be cooled to 110-120 after adding plasticizer, stabilizer II, terminator mixing in the material II that step S22 prepares
DEG C, under rotating speed is 200-300r/min, reacts 60-90 min, prepares synthetics;
S3: add degradation agent, starch adesive, antibacterial after the miscible fluid I that step S2 prepares is cooled to 42-45 DEG C, stablize
Agent I, ultraviolet absorber, be placed in ultrasonic response still, reacts 20-30min under power 100-300W, and warp is 65-in temperature
It is dried at 78 DEG C, prepares the degradable photoelectric material used for solar batteries of moisture content≤7%;
The preparation method of described starch adesive, comprises the following steps:
S31: compound concentration is the starch slurry I of 30-35Be ';
S32: it is the dimethyl adipate of 3%-5%, amide dimethyl butyrate that the para arrowroot slurry I in step S31 adds concentration, so
After be 35-38 DEG C in temperature, speed of agitator be carry out under 60-80r/min cross-linked graft reaction 1-1.5h, prepare slurry II;
S33: add barium hydroxide and epoxychloropropane in the slurry II of step S32, be then 40-45 DEG C in temperature, stirring
Rotating speed is to carry out cross-linking reaction 0.4-0.6h under 60-80r/min, prepares slurry III;
S34: the slurry III of step S33 carried out pre-gelatinized and is dried at temperature is 105-125 DEG C, preparing moisture content≤8%
Material IV;
S35: the material IV of step S34 is pulverized, crosses 100-120 mesh sieve, prepare starch adesive.
Embodiment 1
A kind of degradable photoelectric material used for solar batteries, in units of weight, is made up of following raw material: acrylic resin 45
Part, hydracrylic acid valeric acid copolyesters 25 parts, VCz 16 parts, bentonite 15 parts, calcium stearate 12 parts, sodium silicate 10 parts,
Corn stalk fiber 8 parts, polylactic acid 10 parts, dehydroactic acid 7 parts, degradation agent 6 parts, synthetics 8 parts, starch adesive 5 parts, antibacterial
Agent 2.5 parts, stabilizer I 1.5 parts, ultraviolet absorber 1.5 parts;
Described degradation agent, in units of weight, is made up of following raw material: 2.2 parts of ammonium phosphate, amino trimethylene ethylphosphonic acid 1.4 parts,
Ethylenediamine tetramethylenephosphonic acid 1.2 parts, dodecyl dimethyl benzyl ammonium bromide 0.9 part, titanium dioxide 0.3 part;
Described synthetics, in units of weight portion, is made up of following raw material: propellant 0.9 part, coupling agent 1.4 parts, compatilizer 1.2
Part, regulator 0.8 part, hardening agent 0.8 part, flocculation agent 1.2 parts, plasticizer 1.2 parts, stabilizer II 0.3 parts, terminator 0.2 part;
Described propellant is aerogel generating agent, and described coupling agent is epoxy silane class coupling agent, and described compatilizer is maleic acid
Acid anhydride grafting compatilizer, described regulator is processing aids acrylic resin, and described hardening agent is 701 powder hardening agents, described coacervation
Agent is aluminium polychlorid, and described plasticizer is dioctyl adipate, and described stabilizer II is fat acids stabilizer, described terminator
For styrene;
Described starch adesive, in units of weight portion, is made up of following raw material: starch 1.5 parts, dimethyl adipate 1.3 parts,
Amide dimethyl butyrate 1 part, barium hydroxide 0.5 part, epoxychloropropane 0.7 part;
Described antibacterial is isothiazolone derivative;
Described stabilizer I is light stabilizer 783;
Described ultraviolet absorber is ESCALOL 567;
The preparation method of described degradable photoelectric material used for solar batteries, comprises the following steps:
S1: add polylactic acid, dehydroactic acid after acrylic resin, hydracrylic acid valeric acid copolyesters, VCz mixing,
Rotating speed is that under 120r/min, stirring is warming up to 78 DEG C, keeps temperature-resistant lower continuation to stir 4min by 120r/min, prepares suspended
Liquid;
S2: the suspension prepared to step S1 adds bentonite, calcium stearate, sodium silicate, corn stalk fiber, synthetics, control
Temperature processed is 140 DEG C, stirs 2h, prepare miscible fluid I under rotating speed is 150r/min;
The preparation method of described synthetics, comprises the following steps:
S21: propellant, coupling agent, compatilizer mixing are warming up to 128 DEG C, react 50 min under rotating speed is 250r/min, system
Obtain material I;
S22: be warming up to 155 DEG C after adding regulator, hardening agent, flocculation agent mixing in the material I that step S21 prepares, turning
Speed, for reacting 170 min under 350r/min, prepares material II;
S23: be cooled to 115 DEG C after adding plasticizer, stabilizer II, terminator mixing in the material II that step S22 prepares,
Rotating speed is to react 75 min under 50r/min, prepares synthetics;
S3: by step S2 prepare miscible fluid I be cooled to 43 DEG C after add degradation agent, starch adesive, antibacterial, stabilizer I,
Ultraviolet absorber, is placed in ultrasonic response still, reacts 25min under power 200W, through being dried at temperature is 72 DEG C, prepares
Moisture content is the degradable photoelectric material used for solar batteries of 7%;
The preparation method of described starch adesive, comprises the following steps:
S31: compound concentration is the starch slurry I of 32Be ';
S32: the para arrowroot slurry I in step S31 adds dimethyl adipate, the amide dimethyl butyrate that concentration is 4%, then
Being 36 DEG C in temperature, speed of agitator is to carry out cross-linked graft reaction 1.2h under 70r/min, prepares slurry II;
S33: add barium hydroxide and epoxychloropropane in the slurry II of step S32, is then 42 DEG C in temperature, speed of agitator
For carrying out cross-linking reaction 0.5h under 70r/min, prepare slurry III;
S34: the slurry III of step S33 carrying out pre-gelatinized and is dried at temperature is 115 DEG C, prepared moisture content is the material of 8%
Ⅳ;
S35: the material IV of step S34 is pulverized, crosses 110 mesh sieve, prepare starch adesive.
Embodiment 2
A kind of degradable photoelectric material used for solar batteries, in units of weight, is made up of following raw material: acrylic resin 32
Part, hydracrylic acid valeric acid copolyesters 18 parts, VCz 12 parts, bentonite 10 parts, calcium stearate 8 parts, sodium silicate 8 parts, jade
Rice stalk fibre 6 parts, polylactic acid 7 parts, dehydroactic acid 6 parts, degradation agent 5 parts, synthetics 6 parts, starch adesive 4 parts, antibacterial 2
Part, stabilizer I 1 parts, ultraviolet absorber 1 part;
Described degradation agent, in units of weight, is made up of following raw material: 2 parts of ammonium phosphate, amino trimethylene ethylphosphonic acid 1.2 parts, second
Diamidogen tetracarboxylic acid 1 part, dodecyl dimethyl benzyl ammonium bromide 0.6 part, titanium dioxide 0.2 part;
Described synthetics, in units of weight portion, is made up of following raw material: propellant 0.6 part, coupling agent 1 part, compatilizer 0.8
Part, regulator 0.6 part, hardening agent 0.6 part, flocculation agent 1 part, plasticizer 1 part, stabilizer II 0.2 parts, terminator 0.2 part;
Described propellant is aerogel generating agent, and described coupling agent is epoxy silane class coupling agent, and described compatilizer is maleic acid
Acid anhydride grafting compatilizer, described regulator is processing aids acrylic resin, and described hardening agent is 701 powder hardening agents, described coacervation
Agent is aluminium polychlorid, and described plasticizer is dioctyl adipate, and described stabilizer II is fat acids stabilizer, described terminator
For styrene;
Described starch adesive, in units of weight portion, is made up of following raw material: starch 1.2 parts, dimethyl adipate 1 part, two
Methylbutyryl amine 0.8 part, barium hydroxide 0.4 part, epoxychloropropane 0.6 part;
Described antibacterial is isothiazolone derivative;
Described stabilizer I is light stabilizer 783;
Described ultraviolet absorber is ESCALOL 567;
The preparation method of described degradable photoelectric material used for solar batteries, comprises the following steps:
S1: add polylactic acid, dehydroactic acid after acrylic resin, hydracrylic acid valeric acid copolyesters, VCz mixing,
Rotating speed is that under 80r/min, stirring is warming up to 78 DEG C, keeps temperature-resistant lower continuation to stir 5min by 80r/min, prepares suspension;
S2: the suspension prepared to step S1 adds bentonite, calcium stearate, sodium silicate, corn stalk fiber, synthetics, control
Temperature processed is 135 DEG C, stirs 3h, prepare miscible fluid I under rotating speed is 100r/min;
The preparation method of described synthetics, comprises the following steps:
S21: propellant, coupling agent, compatilizer mixing are warming up to 120 DEG C, react 60 min under rotating speed is 200r/min, system
Obtain material I;
S22: be warming up to 150 DEG C after adding regulator, hardening agent, flocculation agent mixing in the material I that step S21 prepares, turning
Speed, for reacting 180 min under 300r/min, prepares material II;
S23: be cooled to 110 DEG C after adding plasticizer, stabilizer II, terminator mixing in the material II that step S22 prepares,
Rotating speed is to react 90 min under 200r/min, prepares synthetics;
S3: by step S2 prepare miscible fluid I be cooled to 42 DEG C after add degradation agent, starch adesive, antibacterial, stabilizer I,
Ultraviolet absorber, is placed in ultrasonic response still, reacts 30min under power 100W, through being dried at temperature is 65 DEG C, prepares
Moisture content is the degradable photoelectric material used for solar batteries of 6%;
The preparation method of described starch adesive, comprises the following steps:
S31: compound concentration is the starch slurry I of 30Be ';
S32: the para arrowroot slurry I in step S31 adds dimethyl adipate, the amide dimethyl butyrate that concentration is 3%, then
Being 35 DEG C in temperature, speed of agitator is to carry out cross-linked graft reaction 1.5h under 60r/min, prepares slurry II;
S33: add barium hydroxide and epoxychloropropane in the slurry II of step S32, is then 40 DEG C in temperature, speed of agitator
For carrying out cross-linking reaction 0.6h under 60r/min, prepare slurry III;
S34: the slurry III of step S33 carrying out pre-gelatinized and is dried at temperature is 105 DEG C, prepared moisture content is the material of 7%
Ⅳ;
S35: the material IV of step S34 is pulverized, crosses 100 mesh sieve, prepare starch adesive.
Embodiment 3
A kind of degradable photoelectric material used for solar batteries, in units of weight, is made up of following raw material: acrylic resin 56
Part, hydracrylic acid valeric acid copolyesters 34 parts, VCz 20 parts, bentonite 18 parts, calcium stearate 15 parts, sodium silicate 12 parts,
Corn stalk fiber 9 parts, polylactic acid 12 parts, dehydroactic acid 8 parts, degradation agent 7 parts, synthetics 10 parts, starch adesive 6 parts, anti-
Microbial inoculum 3 parts, stabilizer I 2 parts, ultraviolet absorber 2 parts;
Described degradation agent, in units of weight, is made up of following raw material: 2.4 parts of ammonium phosphate, amino trimethylene ethylphosphonic acid 1.6 parts,
Ethylenediamine tetramethylenephosphonic acid 1.4 parts, dodecyl dimethyl benzyl ammonium bromide 1.2 parts, titanium dioxide 0.4 part;
Described synthetics, in units of weight portion, is made up of following raw material: propellant 1.2 parts, coupling agent 1.8 parts, compatilizer 1.4
Part, regulator 1 part, hardening agent 1 part, flocculation agent 1.5 parts, plasticizer 1.4 parts, stabilizer II 0.4 parts, terminator 0.3 part;
Described propellant is aerogel generating agent, and described coupling agent is epoxy silane class coupling agent, and described compatilizer is maleic acid
Acid anhydride grafting compatilizer, described regulator is processing aids acrylic resin, and described hardening agent is 701 powder hardening agents, described coacervation
Agent is aluminium polychlorid, and described plasticizer is dioctyl adipate, and described stabilizer II is fat acids stabilizer, described terminator
For styrene;
Described starch adesive, in units of weight portion, is made up of following raw material: starch 1.8 parts, dimethyl adipate 1.6 parts,
Amide dimethyl butyrate 1.2 parts, barium hydroxide 0.6 part, epoxychloropropane 0.8 part;
Described antibacterial is isothiazolone derivative;
Described stabilizer I is light stabilizer 783;
Described ultraviolet absorber is ESCALOL 567;
The preparation method of described degradable photoelectric material used for solar batteries, comprises the following steps:
S1: add polylactic acid, dehydroactic acid after acrylic resin, hydracrylic acid valeric acid copolyesters, VCz mixing,
Rotating speed is that under 150r/min, stirring is warming up to 78 DEG C, keeps temperature-resistant lower continuation to stir 3min by 150r/min, prepares suspended
Liquid;
S2: the suspension prepared to step S1 adds bentonite, calcium stearate, sodium silicate, corn stalk fiber, synthetics, control
Temperature processed is 150 DEG C, stirs 1h, prepare miscible fluid I under rotating speed is 200r/min;
The preparation method of described synthetics, comprises the following steps:
S21: propellant, coupling agent, compatilizer mixing are warming up to 135 DEG C, react 60 min under rotating speed is 300r/min, system
Obtain material I;
S22: be warming up to 160 DEG C after adding regulator, hardening agent, flocculation agent mixing in the material I that step S21 prepares, turning
Speed is reaction 150min under 400r/min, prepares material II;
S23: be cooled to 120 DEG C after adding plasticizer, stabilizer II, terminator mixing in the material II that step S22 prepares,
Rotating speed is to react 60 min under 300r/min, prepares synthetics;
S3: by step S2 prepare miscible fluid I be cooled to 45 DEG C after add degradation agent, starch adesive, antibacterial, stabilizer I,
Ultraviolet absorber, is placed in ultrasonic response still, reacts 20min under power 300W, through being dried at temperature is 78 DEG C, prepares
Moisture content is the degradable photoelectric material used for solar batteries of 5%;
The preparation method of described starch adesive, comprises the following steps:
S31: compound concentration is the starch slurry I of 35Be ';
S32: the para arrowroot slurry I in step S31 adds dimethyl adipate, the amide dimethyl butyrate that concentration is 5%, then
Being 38 DEG C in temperature, speed of agitator is to carry out cross-linked graft reaction 1h under 80r/min, prepares slurry II;
S33: add barium hydroxide and epoxychloropropane in the slurry II of step S32, is then 45 DEG C in temperature, speed of agitator
For carrying out cross-linking reaction 0.4h under 80r/min, prepare slurry III;
S34: the slurry III of step S33 carrying out pre-gelatinized and is dried at temperature is 125 DEG C, prepared moisture content is the material of 5%
Ⅳ;
S35: the material IV of step S34 is pulverized, crosses 120 mesh sieve, prepare starch adesive.
The degradable photoelectric material used for solar batteries of embodiment 1-3 is carried out thermogravimetric analysis (TG) and differential scanning amount
Heat analyzes the test of (DSC), and the rate of heat addition is 20 DEG C/min, and thermogravimetric analysis (TG) heat decomposition temperature result see table.
Using soil-burial method, claim the degradable photoelectric material of certain mass and the soil mixing of certain mass, note is total
Quality;Then being placed in environment by the pedotheque being mixed with degradable photoelectric material, each a period of time claims its quality, records matter
Amount change, Mass lost amount obtains degradation rate than original degradable photoelectric material quality, when the degradation rate in following table is 1 year
Degradability.
Embodiment | Heat decomposition temperature (DEG C) | Optoelectronic transformation efficiency (%) | Degradability (%) |
1 | 575.78 | 15.63 | 91.23 |
2 | 564.12 | 12.89 | 89.35 |
3 | 589.34 | 17.82 | 93.47 |
As seen from the above table, the heat decomposition temperature of the degradable photoelectric material used for solar batteries of the present invention is high, reaches 560 DEG C
Above, using soil-burial method to bury the degradable photoelectric material used for solar batteries of the present invention, after 1 year, degradation rate reaches 89%
Above.
Above content it cannot be assumed that the present invention be embodied as be confined to these explanation, technology belonging to the present invention is led
For the those of ordinary skill in territory, without departing from the inventive concept of the premise, it is also possible to make some simple deduction or replace,
All should be considered as belonging to the scope of patent protection that the present invention is determined by the claims submitted to.
Claims (7)
1. a degradable photoelectric material used for solar batteries, it is characterised in that in units of weight, by following raw material system
Become: acrylic resin 32-56 part, hydracrylic acid valeric acid copolyesters 18-34 part, VCz 12-20 part, bentonite 10-18
Part, calcium stearate 8-15 part, sodium silicate 8-12 part, corn stalk fiber 6-9 part, polylactic acid 7-12 part, dehydroactic acid 6-8 part,
Degradation agent 5-7 part, synthetics 6-10 part, starch adesive 4-6 part, antibacterial 2-3 part, stabilizer I 1-2 part, ultraviolet absorber
1-2 part;
Described degradation agent, in units of weight, is made up of following raw material: ammonium phosphate 2-2.4 part, amino trimethylene ethylphosphonic acid 1.2-
1.6 parts, ethylenediamine tetramethylenephosphonic acid 1-1.4 part, dodecyl dimethyl benzyl ammonium bromide 0.6-1.2 part, titanium dioxide 0.2-0.4
Part;
Described synthetics, in units of weight portion, is made up of following raw material: propellant 0.6-1.2 part, coupling agent 1-1.8 part, phase
Hold agent 0.8-1.4 part, regulator 0.6-1 part, hardening agent 0.6-1 part, flocculation agent 1-1.5 part, plasticizer 1-1.4 part, stabilizer
II 0.2-0.4 part, terminator 0.2-0.3 part;
Described propellant is aerogel generating agent, and described coupling agent is epoxy silane class coupling agent, and described compatilizer is maleic acid
Acid anhydride grafting compatilizer, described regulator is processing aids acrylic resin, and described hardening agent is 701 powder hardening agents, described coacervation
Agent is aluminium polychlorid;
Described starch adesive, in units of weight portion, is made up of following raw material: starch 1.2-1.8 part, dimethyl adipate 1-
1.6 parts, amide dimethyl butyrate 0.8-1.2 part, barium hydroxide 0.4-0.6 part, epoxychloropropane 0.6-0.8 part;
The preparation method of described degradable photoelectric material used for solar batteries, comprises the following steps:
S1: add polylactic acid, dehydroactic acid after acrylic resin, hydracrylic acid valeric acid copolyesters, VCz mixing,
Rotating speed is that under 80-150r/min, stirring is warming up to 78 DEG C, keeps temperature-resistant lower continuation to stir 3-5min by 80-150r/min,
Prepare suspension;
S2: the suspension prepared to step S1 adds bentonite, calcium stearate, sodium silicate, corn stalk fiber, synthetics, control
Temperature processed is 135-150 DEG C, stirs 1-3h, prepare miscible fluid I under rotating speed is 100-200r/min;
The preparation method of described synthetics, comprises the following steps:
S21: propellant, coupling agent, compatilizer mixing are warming up to 120-135 DEG C, react under rotating speed is 200-300r/min
40-60 min, prepares material I;
S22: be warming up to 150-160 DEG C after adding regulator, hardening agent, flocculation agent mixing in the material I that step S21 prepares,
Under rotating speed is 300-400r/min, reacts 150-180 min, prepares material II;
S23: be cooled to 110-120 after adding plasticizer, stabilizer II, terminator mixing in the material II that step S22 prepares
DEG C, under rotating speed is 200-300r/min, reacts 60-90 min, prepares synthetics;
S3: add degradation agent, starch adesive, antibacterial after the miscible fluid I that step S2 prepares is cooled to 42-45 DEG C, stablize
Agent I, ultraviolet absorber, be placed in ultrasonic response still, reacts 20-30min under power 100-300W, and warp is 65-in temperature
It is dried at 78 DEG C, prepares the degradable photoelectric material used for solar batteries of moisture content≤7%;
The preparation method of described starch adesive, comprises the following steps:
S31: compound concentration is the starch slurry I of 30-35Be ';
S32: it is the dimethyl adipate of 3%-5%, amide dimethyl butyrate that the para arrowroot slurry I in step S31 adds concentration, so
After be 35-38 DEG C in temperature, speed of agitator be carry out under 60-80r/min cross-linked graft reaction 1-1.5h, prepare slurry II;
S33: add barium hydroxide and epoxychloropropane in the slurry II of step S32, be then 40-45 DEG C in temperature, stirring
Rotating speed is to carry out cross-linking reaction 0.4-0.6h under 60-80r/min, prepares slurry III;
S34: the slurry III of step S33 carried out pre-gelatinized and is dried at temperature is 105-125 DEG C, preparing moisture content≤8%
Material IV;
S35: the material IV of step S34 is pulverized, crosses 100-120 mesh sieve, prepare starch adesive.
Degradable photoelectric material the most used for solar batteries, it is characterised in that described plasticizer is for oneself
Adipate.
Degradable photoelectric material the most used for solar batteries, it is characterised in that described stabilizer II is
Fat acids stabilizer.
Degradable photoelectric material the most used for solar batteries, it is characterised in that described terminator is benzene
Ethylene.
Degradable photoelectric material the most used for solar batteries, it is characterised in that described antibacterial is different
Thiazolinone derivative.
Degradable photoelectric material the most used for solar batteries, it is characterised in that described stabilizer I is
Light stabilizer 783.
Degradable photoelectric material the most used for solar batteries, it is characterised in that described ultraviolet absorber
For ESCALOL 567.
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CN101218707A (en) * | 2005-07-07 | 2008-07-09 | 日本化药株式会社 | Sealing agent for photoelectric converter and photoelectric converter using same |
CN104377305A (en) * | 2014-11-13 | 2015-02-25 | 无锡中洁能源技术有限公司 | Degradable photoelectric material and preparing method for degradable photoelectric material |
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CN101218707A (en) * | 2005-07-07 | 2008-07-09 | 日本化药株式会社 | Sealing agent for photoelectric converter and photoelectric converter using same |
CN104377305A (en) * | 2014-11-13 | 2015-02-25 | 无锡中洁能源技术有限公司 | Degradable photoelectric material and preparing method for degradable photoelectric material |
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