前苏联专利SU1466650A3 Method of producing polymer film material

专利PDF首页>>前苏联专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
A method of obtaining a macromolecular material that conducts electric current on its surface by way of the surface introduction of conducting complexes in crystalline form is described, which is characterized in that it involves subjecting the surface of a non-conducting polymeric material containing an addition of an electron donor and/or acceptor in an amount of 0.2-5% by weight to the action of an organic solvent, a mixture of organic solvents or their vapours, possibly containing an addition of an electron acceptor or donor in an amount of 0.1-4.0% by weight. Compounds with low molecular weight and capable of forming high-conductance, charge-transfer complexes are used as electron donors and acceptors. The material thus obtained finds application e.g. in electronics.
公开号:SU1466650A3
申请号:SU843775306
申请日:1984-08-08
公开日:1989-03-15
发明作者:Крышевский Мариан；Ешка Еремияш；Юланьский Яцек；Трач Адам
申请人:Польска Акадэмия Наук,Цэнтрум Бадань Мольэкульарных И Макромольэкульарных (Инопредприятие)；
IPC主号:

专利说明:

The invention relates to methods for producing modified polymeric materials having surface conductivity of electric current.
The purpose of the invention is the reduction of the specific surface resistance of the material.
The proposed method provides for the introduction into the material during its formation from a solution of an electron donor tetratiofulvalene of the formula (57) The invention relates to the production of polymer film materials having surface conductivity. The invention allows to reduce the specific surface resistance of the material due to the fact that the surface of the material formed from a solution of polycarbonate or polymethyl methacrylate containing 0.3-5 wt.h. a donor, tetratiofulvalene or tetrathionaphthacene and / or an electron acceptor, tetracyanoquinodimethane, is treated with an organic solvent or its vapors. An electron donor or acceptor can be used in the method for surface treatment in the form of a 0.1-0.2% solution in an organic solvent.
S — S ojojojo s — s and / or electron acceptor - tetracyanoquinodimethane of the formula
SU .... 1466650
or tetratiotetracene formulas
After the formation of the product, it is exposed to organic solvents or their vapors, which may contain the addition of an acceptor or electron donor, if one of them was not introduced into the materials during its formation.
The type of organic solvents used is not critical since they are removed in the process immediately after use. . drying the surface. They are selected depending on the type of polymer material.
To improve the properties of the conductive layer, for example, its mechanical strength, the organic solvent may also contain a certain amount of polymer. This may be the polymer from which the material is made or some other polymer.
The inventive method of high-molecular material possessing ₂ 0 giving the surface conduction of electric current, characterized by a low surface resistivity of about 10 · ² - June ¹⁰ ohms. The resistance can be controlled by the content of the donor and / or electron acceptor, as well as by the process parameters. In addition, the material is characterized by a weak dependence of conductivity on temperature in a wide 3Q range of its changes, and the complex formed in the polymer material, which has the ability to transfer electric charge, has a crystalline structure and is highly resistant to atmospheric factors and light, and also has no tendency to diffusion from the polymer. The thickness of the current-conducting surface layer of the polymer material obtained by the proposed method can be different and in some cases, for example with very thin films, it can equal the whole thickness of the film, as a result of which Films with bulk conductivity can be obtained.
Due to the use of different concentrations and combinations of donors and / or acceptors, different organic solvents, or mixtures or vapors on different fragments and sides of the surface of the polymer material being treated (for example, on different surfaces of the object), the proposed method allows to obtain surfaces having different electrical properties , i.e. having different conductivity in different parts, different resistance, gradient changing along the surface, and different anisotropic conductivity.
A polymer material having surface conductivity of an electric current obtained by the proposed method can be widely used. It can be used to remove electric charges, shield electromagnetic radiation, or to produce conductive or high-resistance flat wires, as well as films that conduct in one direction, suitable for use in capacitors, solar panels, electrochemical and semiconductor cells.
Example 1. 100 m.h. polycarbonate is dissolved in 2500 wt.h. chlorobenzene at. 370 K, then add 1 wt.h. tetratiofulvalene and 1 part by weight tetracyanoquinodimethane and also dissolved at the same temperature. The solution thus prepared is poured onto a glass tile having a temperature of 360 K. A film of a thickness of 20 μm is obtained, which has a uniform yellow color and does not conduct electric current. Thus, the obtained starting material is kept in saturated vapors of ethylene chloride at 300 Kiv for Gmin. As a result, the film changes its color to grayish, and crystals of a complex with the ability to transfer electric charge appear under the microscope in its surface layer. The specific surface resistance of the obtained material is 10 ⁴ Ohms at room temperature.
Example 2. 100 parts by weight polycarbonate is dissolved in 4000 parts by weight chlorobenzene at 370 K, then add 2 parts by weight tetracyanoquinodimethane and also dissolved at the same temperature. The solution thus prepared is poured onto a polyester film having a temperature of 370 K. After evaporation of the solution, a 10 μm thick film remains on the surface of the polyester film, which has a uniform yellow color, does not conduct electric current, and adheres well to the polyester. The surface of the material previously obtained in this way is moistened with a 0.2% solution of tetratiofulvalen in a solvent mixture of chlorobenzene h-heptane in a ratio of 1: 3 and after 5 seconds it is dried with hot air. As a result, the surface layer of the material changes color to grayish, or crystals of the conducting complex visible under the microscope appear in it. The specific surface resistance of the material thus obtained is 310 * Ohm at room temperature.
Example 3. 100 parts by weight polymethyl methacrylate is dissolved in 2500 wt.h. o-dichlorobenzene at 400 K, and then add 1 wt.h. tetratiofulvalene and 1 part by weight tetracyanoquinodimethane and also dissolved at the same temperature. The solution thus prepared is poured onto a glass tile having a temperature of 390 K. A film of 30 μm thick is obtained, having a uniform yellow color, not conducting electric current.
One side of the initial film thus obtained is subjected to saturated vapors of ethylene chloride at 300 K for 0.5 min, and then dried in a stream of warm air. As a result, the surface resistance of the film reaches 10 ^ 0m at room temperature. After that, the second side of the film is exposed to saturated vapors of methyl ethyl ketone for 1 min at 300 K and dried in a stream of warm air. As a result, the surface resistance of this side of the film reached 4–10 ² Ω at room temperature, almost constant (+ 2%) to a temperature of 330 K, but increasing along with a decrease in temperature to 80 K by about 12%.
Example 4. 100 wt.h. polycarbonate is dissolved in 2500 wt.h. o-dichlorobenzene at 430 K, after which 0.19 parts by weight are added. tetratiotetracene and 0.11 parts by weight tetracyanoquinodimethane and also dissolved at the same temperature. The solution thus prepared is poured onto a glass plate with a temperature of 420 K. A film of 20 | cm thick is obtained with a uniform green-yellow color, which does not conduct electric current. The material previously obtained in this way is then placed in dioxane vapors with a temperature of 300 K
1.5
1466650 ⁶ for 2 min. As a result, the film changes color to a slightly grayish.
The surface resistivity is 10 ohms at room temperature.
Example 5. 100 parts by weight polycarbonate is dissolved in 2500 wt.h. chlorobenzene at 400 K, after which 0.2 wt.h. tetratiotetracene, which also dissolve at this temperature. The solution thus prepared is then poured onto a glass plate with a temperature of 390 K. A film 32 [m thick with a uniform green color, not conducting electric current, is obtained. One side of the thus obtained film is then moistened with a 0.1% solution of tetracyanoquinodimethane in a solvent mixture of acetonitrile chlorobenzene in a ratio of 4: 1. After drying with hot air, the film changes color to grayish and has a surface resistivity of 4. x 10 ^b Ohm at room temperature.
Example 6. 100 parts by weight polycarbonate is dissolved in 2500 wt.h. o-dichlorobenzene at 440 K, after which 2.5 wt.h. tetratiofulvalene and 2.5 parts by weight tetracyanoquinodimethane and also dissolved at this temperature. The solution thus prepared is poured onto a glass plate with a temperature of 390 K. A film of 25 mm in thickness is obtained. A uniform yellow color that does not conduct electric current. The material previously obtained in this way is placed in chloroform vapor for 2 s. As a result, the film changes color to grayish, and its surface specific resistance is 2 x 10 ^ Ohm.
Example 7. 100 m.h. polycarbonate is dissolved in 2500 wt.h. o-dichlorobenzene at 400 K, after which 1 wt.h. tetracyanoquinondimethane, also soluble at the above temperature. The solution thus prepared is poured onto a glass plate at 380 K. A white ginseng is obtained with a thickness of 30 μm yellow, which does not conduct electric current. One surface of the film is wetted with a 0.15% solution of tetratiofulfalene in acetone. After drying hot
Ί with air, 'Fg'yka changes color to grayish. It exhibits electrical conductivity with a specific surface resistance of the order of 5 x 10 ⁴ Ohms at room temperature.
By a known method, which includes introducing a donor and electron acceptors into the polycarbonate or polymethyl methacrylate (without treating the surface of the material with a solvent), a material having only bulk conductivity is obtained. The measured surface resistivity of 15 materials was 10 ¹¹ - 10® Ohm depending on the conditions of their production.

权利要求:
Claims (1)
[1]
Claim
A method for producing a polymer film material by forming it from a polymer solution — polycarbonate or polymethyl methacrylate, containing 0.2 to 2.0 parts by weight. a donor of tetratiofulvalen or tetratiotetracene, or an electron acceptor of tetracyanoquinodimethane or 0.3 • 5.0 wt.h. mixtures thereof per 100 parts by weight polymer, characterized in that, in order to reduce the specific surface resistance of the material, after the formation of the material, its surface is treated respectively with a 0.1 - 0.2% solution in an organic solvent of an acceptor or electron donor, or with an organic solvent or its vapor.

类似技术:

公开号 | 公开日 | 专利标题

EP0686662B2|2006-05-24|Conductive coatings

US4803011A|1989-02-07|Electrically conducting films comprising at least one monomolecular layer of an organic charge transfer complex

SU1466650A3|1989-03-15|Method of producing polymer film material

JP2519551B2|1996-07-31|Conductive polymer-method for producing thin layers

CZ281256B6|1996-07-17|Modified carbon black and process for producing thereof

DE2431143C2|1982-04-15|Process for making dielectric films

Hadek et al.1971|Electrical Properties of 7, 7', 8, 8'-Tetracyanoquinodimethane Salts of Ionene Polymers and Their Model Compounds

Agrawal et al.1993|High temperature electrical conductivity of solution-cast bbl films

Burda et al.1983|Highly anisotropic conductive materials: polymers doped with crystalline charge-transfer complexes

US4886685A|1989-12-12|Layer elements and their production

JP3215423B2|2001-10-09|Manufacturing method of conductive polymer

RU2035803C1|1995-05-20|Process of manufacture of conductive polymer coat on substrate

SE450062B|1987-06-01|PREPARATION OF AN ELECTRICALLY LEADING LAYER FROM A WATER SOLUTION CONTAINING A WATER SOLUBLE POLYMER AND A PYROLE

US4622266A|1986-11-11|Moldable electrically conductive polymer compositions

EP0147871A2|1985-07-10|Method of manufacturing high-molecular electrically conducting material

Khare et al.1994|Spontaneous current emission in metal‐ferrocene‐doped ethyl cellulose‐metal systems

Bazarov et al.1995|Conductivity of the granular metal films obtained by high dose ion implantation into PMMA

Chand et al.1997|Space-charge distributed relaxations in vacuum-deposited polyvinyl fluoride films

Pillai et al.1981|Thermally stimulated discharge current studies in cellulose acetate

Jeszka1993|Formation and Properties of Polyiodide Crystalline Networks Inconductive Polymer Composites

Nakamura et al.1987|Electrical properties of iodine-doped nickel | films

Kita et al.1986|Dielectric properties of polymers containing dispersed TCNQ salts

DE2246255C2|1982-07-01|Electrophotographic recording material

Pethig et al.1975|High field electrical conduction in some organic charge-transfer complexes

JP2678830B2|1997-11-19|Method for producing polymer composite in which organic fine particles are dispersed

同族专利:

公开号 | 公开日

CS603584A2|1988-08-16|

DE3466827D1|1987-11-19|

BG45703A3|1989-07-14|

JPS6071642A|1985-04-23|

HU194288B|1988-01-28|

EP0134026B1|1987-10-14|

DD222150A5|1985-05-08|

PL138395B1|1986-09-30|

EP0134026A1|1985-03-13|

CS262419B2|1989-03-14|

HUT40813A|1987-02-27|

PL243360A1|1985-02-13|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US4026905A|1972-12-26|1977-05-31|Monsanto Company|Electrically conducting organic salts|

JPS5548402B2|1976-07-02|1980-12-05|

DE3069926D1|1979-07-10|1985-02-21|Japan Synthetic Rubber Co Ltd|Doped polyacetylenes and their production|FR2564231B1|1984-05-10|1986-09-05|Commissariat Energie Atomique|ELECTRICALLY CONDUCTIVE FILMS COMPRISING AT LEAST ONE MONOMOLECULAR LAYER OF AN ORGANIC COMPLEX WITH LOAD TRANSFER AND THEIR MANUFACTURING METHOD|

DE3619606A1|1986-06-11|1987-12-17|Basf Ag|METHOD FOR PRODUCING AN ELECTRICALLY CONDUCTIVE SURFACE LAYER ON PLASTIC BODIES|

JP2520247B2|1987-02-12|1996-07-31|日本カ−リツト株式会社|Method of making surface transparent conductive|

DD301547A7|1987-04-09|1993-03-04|Leipzig Tech Hochschule|METHOD FOR PRODUCING CONDUCTIVE STRUCTURES IN POLY |

法律状态:

优先权:

申请号 | 申请日 | 专利标题

PL1983243360A|PL138395B1|1983-08-09|1983-08-09|Process for manufacturing surface conducting macromolecular material|

[返回顶部]