CN113421968A - Flexible perovskite solar cell material with high photoelectric conversion rate and method - Google Patents

Abstract

The invention relates to a flexible perovskite solar cell material with high photoelectric conversion rate and a method thereof, wherein the flexible perovskite solar cell material comprises the following components in parts by mass: the first step is as follows: weighing raw materials of each component according to a formula ratio; the second step is that: putting lead halide and methylamine halide into a solvent for mixing, then adding a nano modifier and uniformly stirring to obtain a solution I; the third step: dissolving lead oleate and methane chloride into acetone, then dropwise adding hydrogen chloride to obtain a solution II, mixing the solution II and the solution I, uniformly stirring, covering the solution on a polyimide substrate material, and performing heat treatment to form a perovskite thin film material; according to the invention, the invisible absorptivity of the prepared solar cell material in sunlight is enhanced by adding the carbon black and the graphene, so that the blanking of photoelectric conversion of solar cell equipment is improved, and the service performance of the solar cell material is increased.

Description

Flexible perovskite solar cell material with high photoelectric conversion rate and method

Technical Field

The invention relates to the technical field of solar cell materials, in particular to a flexible perovskite solar cell material with high photoelectric conversion rate and a method.

Background

With the continuous development and progress of society and science and technology, solar technology is gradually developed and popularized, solar battery equipment is utilized to convert light energy into electric energy, and an effect of protecting the environment can be achieved.

Disclosure of Invention

The present invention is directed to a flexible perovskite solar cell material with high photoelectric conversion rate and a method thereof, so as to solve the problems mentioned in the background art

In order to achieve the purpose, the invention provides the following technical scheme: a flexible perovskite solar cell material with high photoelectric conversion rate comprises the following components in parts by mass:

lead halide: 20-40 parts;

halogenated methylamine: 8 parts of a mixture;

nano modifier: 0.5-1 part;

solvent: 8-10 parts;

and (3) lead oleate: 18-32 parts;

methane chloride: 8 parts of a mixture;

hydrogen chloride: 3-5 parts;

carbon black: 20-30 parts of a solvent;

graphene: 10-20 parts;

hydrochloric acid: 18-28 parts;

polyimide (I): 1 part.

Preferably, the solvent is prepared by mixing dimethyl silicone oil and C1-C4 alcoholic solution.

Preferably, the nano modifier is nano titanium dioxide.

Preferably, the preparation method of the flexible perovskite solar cell material with high photoelectric conversion rate comprises the following steps:

the first step is as follows: weighing raw materials of each component according to a formula ratio;

the second step is that: putting lead halide and methylamine halide into a solvent for mixing, then adding a nano modifier and uniformly stirring to obtain a solution I;

the third step: dissolving lead oleate and methane chloride into acetone, then dropwise adding hydrogen chloride to obtain a solution II, mixing the solution II and the solution I, uniformly stirring, covering the solution on a polyimide substrate material, and performing heat treatment to form a perovskite thin film material;

the fourth step: sequentially adding graphene and carbon black into hydrochloric acid, and reacting and mixing to obtain a mixture;

the fifth step: and (3) immersing the perovskite thin film material obtained in the third step into the mixture, carrying out micro-boiling heating for 2-3h, then cooling and depositing, and naturally airing to obtain the solar cell material.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, the invisible absorptivity of the prepared solar cell material in sunlight is enhanced by adding the carbon black and the graphene, so that the blanking of photoelectric conversion of solar cell equipment is improved, and the service performance of the solar cell material is increased.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The invention provides a technical scheme that: a flexible perovskite solar cell material with high photoelectric conversion rate comprises the following components in parts by mass:

lead halide: 20-40 parts;

halogenated methylamine: 8 parts of a mixture;

nano modifier: 0.5-1 part;

solvent: 8-10 parts;

and (3) lead oleate: 18-32 parts;

methane chloride: 8 parts of a mixture;

hydrogen chloride: 3-5 parts;

carbon black: 20-30 parts of a solvent;

graphene: 10-20 parts;

hydrochloric acid: 18-28 parts;

polyimide (I): 1 part.

The solvent is prepared by mixing dimethyl silicone oil and C1-C4 alcoholic solution.

The nano modifier is nano titanium dioxide.

A preparation method of a flexible perovskite solar cell material with high photoelectric conversion rate comprises the following steps:

the first step is as follows: weighing raw materials of each component according to a formula ratio;

the second step is that: putting lead halide and methylamine halide into a solvent for mixing, then adding a nano modifier and uniformly stirring to obtain a solution I;

the third step: dissolving lead oleate and methane chloride into acetone, then dropwise adding hydrogen chloride to obtain a solution II, mixing the solution II and the solution I, uniformly stirring, covering the solution on a polyimide substrate material, and performing heat treatment to form a perovskite thin film material;

the fourth step: sequentially adding graphene and carbon black into hydrochloric acid, and reacting and mixing to obtain a mixture;

the fifth step: immersing the perovskite thin film material obtained in the third step into the mixture, heating for 2-3h by micro boiling, then cooling, depositing, and naturally drying to obtain a solar cell material;

example 1:

a preparation method of a flexible perovskite solar cell material with high photoelectric conversion rate comprises the following steps:

the first step is as follows: weighing raw materials of each component according to a formula ratio;

the second step is that: putting lead halide and methylamine halide into a solvent for mixing, then adding a nano modifier and uniformly stirring to obtain a solution I;

the third step: dissolving lead oleate and methane chloride into acetone, then dropwise adding hydrogen chloride to obtain a solution II, mixing the solution II and the solution I, uniformly stirring, covering the solution on a polyimide substrate material, and carrying out heat treatment to form the perovskite thin film material.

Example 2:

a preparation method of a flexible perovskite solar cell material with high photoelectric conversion rate comprises the following steps:

the first step is as follows: weighing raw materials of each component according to a formula ratio;

the second step is that: putting lead halide and methylamine halide into a solvent for mixing, then adding a nano modifier and uniformly stirring to obtain a solution I;

the third step: dissolving lead oleate and methane chloride into acetone, then dropwise adding hydrogen chloride to obtain a solution II, mixing the solution II and the solution I, uniformly stirring, covering the solution on a polyimide substrate material, and performing heat treatment to form a perovskite thin film material;

the fourth step: sequentially adding graphene and carbon black into hydrochloric acid, and reacting and mixing to obtain a mixture;

the fifth step: and (3) immersing the perovskite thin film material obtained in the third step into the mixture, carrying out micro-boiling heating for 2-3h, then cooling and depositing, and naturally airing to obtain the solar cell material.

	Example 1	Example 2
			Flexibility	High strength	High strength
Photoelectric conversion rate	Is low in	Height of

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (4)

1. A flexible perovskite solar cell material with high photoelectric conversion rate is characterized in that: the composition comprises the following components in parts by mass:

lead halide: 20-40 parts;

halogenated methylamine: 8 parts of a mixture;

nano modifier: 0.5-1 part;

solvent: 8-10 parts;

and (3) lead oleate: 18-32 parts;

methane chloride: 8 parts of a mixture;

hydrogen chloride: 3-5 parts;

carbon black: 20-30 parts of a solvent;

graphene: 10-20 parts;

hydrochloric acid: 18-28 parts;

polyimide (I): 1 part.

2. The high photoelectric conversion rate flexible perovskite solar cell material as claimed in claim 1, wherein: the solvent is prepared by mixing dimethyl silicone oil and C1-C4 alcoholic solution.

3. The high photoelectric conversion rate flexible perovskite solar cell material as claimed in claim 1, wherein: the nano modifier is nano titanium dioxide.

4. A method for preparing a high photoelectric conversion rate flexible perovskite solar cell material according to any one of claims 1 to 3, which is characterized by comprising the following steps:

the first step is as follows: weighing raw materials of each component according to a formula ratio;

the second step is that: putting lead halide and methylamine halide into a solvent for mixing, then adding a nano modifier and uniformly stirring to obtain a solution I;

the third step: dissolving lead oleate and methane chloride into acetone, then dropwise adding hydrogen chloride to obtain a solution II, mixing the solution II and the solution I, uniformly stirring, covering the solution on a polyimide substrate material, and performing heat treatment to form a perovskite thin film material;

the fourth step: sequentially adding graphene and carbon black into hydrochloric acid, and reacting and mixing to obtain a mixture;

the fifth step: and (3) immersing the perovskite thin film material obtained in the third step into the mixture, carrying out micro-boiling heating for 2-3h, then cooling and depositing, and naturally airing to obtain the solar cell material.