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US2530956A - Electrographic recording - Google Patents

Electrographic recording Download PDF

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US2530956A
US2530956A US688739A US68873946A US2530956A US 2530956 A US2530956 A US 2530956A US 688739 A US688739 A US 688739A US 68873946 A US68873946 A US 68873946A US 2530956 A US2530956 A US 2530956A
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sheet
paper
impregnated
sheets
dye
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US688739A
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Robert B Gibney
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AT&T Corp
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Bell Telephone Laboratories Inc
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41MPRINTING, DUPLICATING, MARKING, OR COPYING PROCESSES; COLOUR PRINTING
    • B41M5/00Duplicating or marking methods; Sheet materials for use therein
    • B41M5/20Duplicating or marking methods; Sheet materials for use therein using electric current
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S101/00Printing
    • Y10S101/29Printing involving a color-forming phenomenon
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T428/00Stock material or miscellaneous articles
    • Y10T428/31504Composite [nonstructural laminate]
    • Y10T428/31725Of polyamide
    • Y10T428/31768Natural source-type polyamide [e.g., casein, gelatin, etc.]
    • Y10T428/31772Next to cellulosic
    • Y10T428/31775Paper

Definitions

  • This invention relates to electrochemical recording media and more particularly to the production of visible marks upon a paper by the passage of an electric current.
  • An object of the invention is to provide an improved form of electrographic recording medium which will provide clear stable marks of high definition when acted upon by high potential low density currents.
  • Another object is to provide an electrographic recording medium which is dry and requires no special preparation either before or after the recording process.
  • a further object is to provide an electrographic recording medium which is insensitive to light, stable in the atmosphere, and which may be handled with safety.
  • Electrographic papers using either type of reaction have had substantial disadvantages, the former being characterized by requirements of high current density while the latter types have been unsatisfactory due to auto-oxidation of the organic agents or the instability of the colored reaction products.
  • the recording process of the present invention overcomes the limitations referred to by utilizing ⁇ the principle that charged ions in a conducting solution will move between electrodes in that solution upon the application of a potential to the electrodes.
  • a composite recording sheet consisting of a dye impregnated marking sheet in close contact with a. record sheet. the combination being impregnated with a solid compound which is electrically conducting in the molten state.
  • the selection of dye and impregnant is such that the application of a high potential to point electrodes in ycontact with opposite sides of the composite sheet .will melt the solid and cause colored ions to migrate to the record sheet, thus producing a. characteristic mark.
  • Fig. l shows a cross-section of the recording Paper
  • Fig. 2 shows an enlarged cross-section of the paper and a pair of electrodes to which a high potential has been applied;
  • Fig. 3 shows a composite sheet in which the marking sheet carries two dyes to produce mirror images upon the two record sheets
  • Fig. fi shows a method oi making duplicate record sheets.
  • the dye or marking sheet i consists oi a tissue paper which has been impregnated with an orgarlic dye and a resistance lowering material which will melt to form a conducting liquid.
  • arecord sheet t oi a strong'white .paper which has been impregnated only with the resistance lowering material.
  • Fig. 2 shows in enlarged cross-sectional View the manner in which the marking action takes .place when the composite sheet 3 is placed between point electrodes as in a facsimile printer.
  • a sufficiently high potential to point electrodes t and 5 in contact with opposite sides of the sheet 3 enough current Will iow through the Volumes E and 1 to cause a rapid increase in temperature.
  • the melting point oi the impregna-nt is reached, it becomes highly conducting, thus providing an electrolytic medium.
  • the high potential gradient will cause the ionized dye molecules in the volume 6 in the marking sheet to move toward the electrode 5 which must be of the opposite Apolarity with respect to that of the colored dye ions.
  • current ceases to flow and the impregnant hardens, leaving a dye impregnated volume 'I in the record sheet.
  • Fig. 3 shows an enlarged cross-sectional view of an electrographic sheet which may be used to produce marks which are mirror images.
  • Composite sheet 8 is made up of two record sheets 9 and I0 on opposite Sides of the marking sheet II, al1 of which are impregnated with the resistance lowering material.
  • Marking sheet Il is impregnated also with two organic dyes, one forming color bearing ions, having a positive charge, the other forming color bearing ions having a negative charge.
  • the groups of ions will separate to move towards the oppositely charged electrodes and form images in volumes I2 and I3.
  • the record sheet bearing the inverted image may be useful in certain types of duplicating processes where a large number of copies are to be made.
  • Composite sheet I4 is made up of marking sheet I5 and record sheets I6 and I'I, impregnated as in the example of Fig. l.
  • a series of point electrodes such as those illustrated in Fig. 2 may be provided with means for switching the activating potential from electrode to electrode.
  • a typical example of such a device is shown in United States Patent 2,273,433, issued February l?, 1942 to E. Bruce, where an electron beam is caused to sweep a mosaic of conductors over which the electrographic paper moves. As the beam strikes a given conductor, a potential is applied across the paper producing a mark by the described process.
  • the paper has been shown to be sensitive and fast, capable of marking at the rate of several inches per second and with currents as low as 150 microamperes. It is to be understood that this example is by way of illustration only as the paper will function satisfactorily when used with the drum and point electrode of the usual facsimile receiver.
  • the impregnant In order to prepare the electrographic paper it is iirst necessary to select an impregnant which will function properly in conjunction with the volt-ampere characteristic of the printing device to be used.
  • the impregnant In operation, the impregnant must act both as a resistance lowering agent to facilitate the flow of current through the sheet and, after melting, as an electrclytic medium vfor the formation and movement of the color-bearing ions.
  • the resistance of the impregnated paper must be such that it will not materially limit the maximum current available, as in the case of the cathode ray device referred to above, where the paper-resistance may be of any value up to one megohm. Under such conditions the temperature of the region between the electrodes will reach a value which is limited only by the amount of current available from the printer and an impregnant must be chosen which will melt within that range.
  • a typical and satisfactory solution may be made up of the following proportions: one hundred grams of acetamide; ten grams of formamide; and suicient water to make up to a total of two hundred fty cubic centimeters. 'Ihe impregnant deposited from such a solution is, upon drying a solid solution of the amide components.
  • a base is selected for the record sheet which is sufficiently porous to be thoroughly penetrated by the impregnant.
  • a strong bond paper which will not tear when wetted to saturation may be used. Paper is by nature a porous, flexible, electrically insulating sheet, when dry. Paper is not necessary however as any material may be used which is suiilciently strong mechanically and which is capable of carrying the impregnant when deposited from solution.
  • Impregnation may be accomplished in any desired manner, for example, by passing the paper, if paper is used, continuously through the solution in strip form and rolling it so as to insure thorough impregnation and removal of air bubbles and excess impregnant. If it is found that r the impregnated paper dries too slowly for continuous processing, it is possible to utilize some other and more volatile solvent. Methyl alcohol may be used, but it then becomes necessary to use a relatively coarse and very absorbent material as the base. otherwise evaporation will take place with excessive rapidity and consequent crystallization in large needles on the surface of the sheet.
  • the preparation of the dye or marking sheet is very similar to the preparation of the record sheet described above.
  • the base may be much lighter, such as a tissure paper, but of such composition that it will absorb the impregnant and yet provide sufficient strength for processing.
  • the electrolytic impregnant used for the dye sheet should be the same as used for the record sheet, with the addition however for the proportions indicated of two to four grams of an organic dye.
  • Such ions are produced from any of the dye molecules which are in the form of salts and in which all of the salt radicals in any one molecule are salts of acid groups or salts of basic groups or in which the number of groups of acid salts and groups of basic salts are not equal.
  • oi dyes w- -ch have the aboveznentioned requisites further select may be made as to color, or as to the fern on of positive or negative color bearing ions, either of which will be dictated by the intended use of the elec-- trographic paper.
  • Victoria blue may be selected for an application which rc: .Ires a positively charged ion, while the dye known as methyl orange may be selected where a, negatively charged ion is necessary.
  • the marking sheet and record sheet be rolled together. This may best be accomplished just before the impregnant has fully dried in order that a maximum adhesion between the two sheets is secured with a minimum premature transfer of color.
  • the best conditions are dependent upon the matrix and impregnant used and should be determined by eX- periment. No special precautions are necessary for storage for reasonable periods of time, however for longer periods the prepared papers must be stored in sealed containers to prevent loss of the impregnant by sublimation. A few crystals of acetamide may be placed in the container if storage for extended intervals is contemplated.
  • An electrographic recording medium comprising two essentially dry paper sheets in face to face Contact, each impregnated with a mixture of acetamide and formamide in the proportions of about 100 parts of the former to 10 parts of the latter, one of said sheets being also impregnated with the dye, Victoria blue, in the proportion of about 2 parts of dye per 100 parts of acetamide.
  • An electrographic recording medium comprising two essentially dry paper sheets in face to face contact. each impregnated with a normally solid, saturated, fatty acid amide containing not more than three carbon atoms, one of said sheets being also impregnated with a salt-forming organic dye, soluble and ionizable in said amide in the molten state to form colored ions having a net electric charge.
  • An electrographic recording medium comprising two essentially dry paper sheets in face to face contact, each impregnated with a solid solution of saturated fatty acid amides containing not more than three carbon atoms, one of said sheets being also impregnated with a salt-forming organic dye, soluble and ionizable in said mixture of amides in the molten state to form colored ions having a net electric charge.
  • An electrographic recording medium comprising two essentially dry porous sheets in face to face Contact, each impregnated with a normally solid organic compound capable of melting locally at a point on the sheets to an electrically conducting liquid under the passage oi' a small electric current through the sheet at said point, said porous sheets being formed of a substance which imparts to the sheets in the unimpregnated state a resistivity higher than that oi Said organic compound in the solid state, one only of said sheets being also impregnated with an organic dye soluble in said organic compound in the molten state and ionizable in said molten organic compound to form color-bearing ions having a net electric charge.
  • An electrographic marking sheet comprising an essentially dry paper sheet containing an impregnant comprising acetamide, formamide and Victoria blue in the proportions of about parts acetainide, 10 parts formamide and 2 to 4 parts Victoria blue, said sheet being adapted lor electrographic recording by reason of its ability to form color-bearing ions and provide an electrolytic path for the movement of said ions to the medium to be marked.

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Description

Nov. 2l, 1950 R. B. GIBNEY 2,530,956
ELECTOGRAPHIC RECORDING Filed Aug. 6, 1946 MARK/N6 SHEET- IMPREGNTED WITH RES/SMNCE LOWER/N6 MATER/AL AND ORGANIC DYE WEA/ro@ R. B. G/BNEV Patented Nov. 2l, 1950 UNITED STATES PATENT OFFICE ELEoTRoGaAPHIc RECORDING Robert B. Gibney, Morristown, N. J., assignor to Bell Telephone Laboratories, Incorporated, New York, N. Y., a corporation of New York Application August 6, 1946, Serial No. 688,739
7 Claims. 1
This invention relates to electrochemical recording media and more particularly to the production of visible marks upon a paper by the passage of an electric current.
An object of the invention is to provide an improved form of electrographic recording medium which will provide clear stable marks of high definition when acted upon by high potential low density currents.
Another object is to provide an electrographic recording medium which is dry and requires no special preparation either before or after the recording process.
A further object is to provide an electrographic recording medium which is insensitive to light, stable in the atmosphere, and which may be handled with safety.
Methods of electrochemical recording are well known and, generally speaking, those methods depend upon either the electrolytic production of inorganic salts or metals or the electrolytic production of organic reaction products. Electrographic papers using either type of reaction have had substantial disadvantages, the former being characterized by requirements of high current density while the latter types have been unsatisfactory due to auto-oxidation of the organic agents or the instability of the colored reaction products.
Efforts to improve the known techniques have 1 been directed primarily toward nding more satisfactory agents for the second type of reaction. United States Patent 1,970,539, issued August 2l, i934 to V. Bausch describes an electrographic paper which depends upon the volatility I of certain of the amines or the light sensitivity of the diazo compounds to 'neutralize the active agent after marking to prevent the subsequent auto-oxidation and formation of colored products. United States Patent 2,367,113 issued January 9, 1945 to R. B. Gibney utilizes the electrolytic oxidation of the leuco bases in the presence of a weak acid in order to obtain a more stable colored product.
While the papers described in the referenced patents go far toward overcoming the disadvantages and shortcomings of the previously known techniques, they have certain limitations. Particularly, they are dependent upon the presence of moisture in order that the electrolytic action may take place, the primary agents tend to be light sensitive, and they require high current densities in order to obtain satisfactory marking speeds.
The recording process of the present invention overcomes the limitations referred to by utilizing `the principle that charged ions in a conducting solution will move between electrodes in that solution upon the application of a potential to the electrodes. According, there is provided a composite recording sheet consisting of a dye impregnated marking sheet in close contact with a. record sheet. the combination being impregnated with a solid compound which is electrically conducting in the molten state. The selection of dye and impregnant is such that the application of a high potential to point electrodes in ycontact with opposite sides of the composite sheet .will melt the solid and cause colored ions to migrate to the record sheet, thus producing a. characteristic mark.
Other features and aspects of the invention will be apparent from a consideration of the following detailed specification and appended claims taken in connection with the accompanying drawing, in which:
Fig. l shows a cross-section of the recording Paper;
Fig. 2 shows an enlarged cross-section of the paper and a pair of electrodes to which a high potential has been applied;
Fig. 3 shows a composite sheet in which the marking sheet carries two dyes to produce mirror images upon the two record sheets; and
Fig. fi shows a method oi making duplicate record sheets.
Referring to Fig. 1, there is shown a cross-sectional view of the composite electrographic paper. The dye or marking sheet i consists oi a tissue paper which has been impregnated with an orgarlic dye and a resistance lowering material which will melt to form a conducting liquid. In close contact is arecord sheet t oi a strong'white .paper which has been impregnated only with the resistance lowering material.
Fig. 2 shows in enlarged cross-sectional View the manner in which the marking action takes .place when the composite sheet 3 is placed between point electrodes as in a facsimile printer. Upon the application of a sufficiently high potential to point electrodes t and 5 in contact with opposite sides of the sheet 3 enough current Will iow through the Volumes E and 1 to cause a rapid increase in temperature. When the melting point oi the impregna-nt is reached, it becomes highly conducting, thus providing an electrolytic medium. rThe high potential gradient will cause the ionized dye molecules in the volume 6 in the marking sheet to move toward the electrode 5 which must be of the opposite Apolarity with respect to that of the colored dye ions. Upon removal of the potential, current ceases to flow and the impregnant hardens, leaving a dye impregnated volume 'I in the record sheet.
Fig. 3 shows an enlarged cross-sectional view of an electrographic sheet which may be used to produce marks which are mirror images. Composite sheet 8 is made up of two record sheets 9 and I0 on opposite Sides of the marking sheet II, al1 of which are impregnated with the resistance lowering material. Marking sheet Il is impregnated also with two organic dyes, one forming color bearing ions, having a positive charge, the other forming color bearing ions having a negative charge. During the marking process, the groups of ions will separate to move towards the oppositely charged electrodes and form images in volumes I2 and I3. The record sheet bearing the inverted image may be useful in certain types of duplicating processes where a large number of copies are to be made. Fig. 4 shows an electrographic sheet suitable for making duplicate copies of the recording. Composite sheet I4 is made up of marking sheet I5 and record sheets I6 and I'I, impregnated as in the example of Fig. l. By the use of relatively slow writing speeds and high potentials at electrodes I8 and I9, the color bearing ions from marking sheet I5 will pass through record sheet I6 into record sheet I'I thus producing identical copies.
In order to put the paper to its intended use, a series of point electrodes, such as those illustrated in Fig. 2 may be provided with means for switching the activating potential from electrode to electrode. A typical example of such a device is shown in United States Patent 2,273,433, issued February l?, 1942 to E. Bruce, where an electron beam is caused to sweep a mosaic of conductors over which the electrographic paper moves. As the beam strikes a given conductor, a potential is applied across the paper producing a mark by the described process. In actual use with 4such a device, the paper has been shown to be sensitive and fast, capable of marking at the rate of several inches per second and with currents as low as 150 microamperes. It is to be understood that this example is by way of illustration only as the paper will function satisfactorily when used with the drum and point electrode of the usual facsimile receiver.
In order to prepare the electrographic paper it is iirst necessary to select an impregnant which will function properly in conjunction with the volt-ampere characteristic of the printing device to be used. In operation, the impregnant must act both as a resistance lowering agent to facilitate the flow of current through the sheet and, after melting, as an electrclytic medium vfor the formation and movement of the color-bearing ions. The resistance of the impregnated paper must be such that it will not materially limit the maximum current available, as in the case of the cathode ray device referred to above, where the paper-resistance may be of any value up to one megohm. Under such conditions the temperature of the region between the electrodes will reach a value which is limited only by the amount of current available from the printer and an impregnant must be chosen which will melt within that range.
It has been found that certain of the acid amides are well adapted to meet the requirements for the impregnant. Acetamide, a normally solid crystalline compound melts at about '70 C. to form an electrically conducting liquid. In order to meet special requirements, propionamide may be used to obtain a higher melting point, while formamide, a normally liquid member of the series, may be added to the impregnant to lower the melting point and hence increase the speed of fusion. These three substances, propionamide, acetamide and formamide, constitute the entire group of saturated fatty acid amides containing not more than three carbon atoms. A typical and satisfactory solution may be made up of the following proportions: one hundred grams of acetamide; ten grams of formamide; and suicient water to make up to a total of two hundred fty cubic centimeters. 'Ihe impregnant deposited from such a solution is, upon drying a solid solution of the amide components.
A base is selected for the record sheet which is sufficiently porous to be thoroughly penetrated by the impregnant. A strong bond paper which will not tear when wetted to saturation may be used. Paper is by nature a porous, flexible, electrically insulating sheet, when dry. Paper is not necessary however as any material may be used which is suiilciently strong mechanically and which is capable of carrying the impregnant when deposited from solution.
Impregnation may be accomplished in any desired manner, for example, by passing the paper, if paper is used, continuously through the solution in strip form and rolling it so as to insure thorough impregnation and removal of air bubbles and excess impregnant. If it is found that r the impregnated paper dries too slowly for continuous processing, it is possible to utilize some other and more volatile solvent. Methyl alcohol may be used, but it then becomes necessary to use a relatively coarse and very absorbent material as the base. otherwise evaporation will take place with excessive rapidity and consequent crystallization in large needles on the surface of the sheet.
The preparation of the dye or marking sheet is very similar to the preparation of the record sheet described above. The base may be much lighter, such as a tissure paper, but of such composition that it will absorb the impregnant and yet provide sufficient strength for processing. The electrolytic impregnant used for the dye sheet should be the same as used for the record sheet, with the addition however for the proportions indicated of two to four grams of an organic dye.
The dye selected must have the following characteristics to fulll its required function:
It must have a salt-forming group.
It must, when ionized, form a colored ion the net charge of which is not zero. Such ions are produced from any of the dye molecules which are in the form of salts and in which all of the salt radicals in any one molecule are salts of acid groups or salts of basic groups or in which the number of groups of acid salts and groups of basic salts are not equal.
It must be soluble in acet e.
Of the groups oi dyes w- -ch have the aboveznentioned requisites further select may be made as to color, or as to the fern on of positive or negative color bearing ions, either of which will be dictated by the intended use of the elec-- trographic paper. For example, Victoria blue may be selected for an application which rc: .Ires a positively charged ion, while the dye known as methyl orange may be selected where a, negatively charged ion is necessary.
In order to complete the preparation of the paper it is necessary only that the marking sheet and record sheet be rolled together. This may best be accomplished just before the impregnant has fully dried in order that a maximum adhesion between the two sheets is secured with a minimum premature transfer of color. The best conditions are dependent upon the matrix and impregnant used and should be determined by eX- periment. No special precautions are necessary for storage for reasonable periods of time, however for longer periods the prepared papers must be stored in sealed containers to prevent loss of the impregnant by sublimation. A few crystals of acetamide may be placed in the container if storage for extended intervals is contemplated.
While the invention has been described and illustrated with reference io certain preferred embodiments, it is to be understood that a great latitude for substitution and alteration exists without departures from the scope of the invention as dened in the appended claims.
What is claimed is:
1. An electrographic recording medium comprising two essentially dry paper sheets in face to face Contact, each impregnated with a mixture of acetamide and formamide in the proportions of about 100 parts of the former to 10 parts of the latter, one of said sheets being also impregnated with the dye, Victoria blue, in the proportion of about 2 parts of dye per 100 parts of acetamide.
2. An electrographic recording medium comprising two essentially dry paper sheets in face to face contact. each impregnated with a normally solid, saturated, fatty acid amide containing not more than three carbon atoms, one of said sheets being also impregnated with a salt-forming organic dye, soluble and ionizable in said amide in the molten state to form colored ions having a net electric charge.
3. An article as described in claim 2 wherein the amide is acetamide.
4. An electrographic recording medium comprising two essentially dry paper sheets in face to face contact, each impregnated with a solid solution of saturated fatty acid amides containing not more than three carbon atoms, one of said sheets being also impregnated with a salt-forming organic dye, soluble and ionizable in said mixture of amides in the molten state to form colored ions having a net electric charge.
5. An electrographic recording medium comprising two essentially dry porous sheets in face to face Contact, each impregnated with a normally solid organic compound capable of melting locally at a point on the sheets to an electrically conducting liquid under the passage oi' a small electric current through the sheet at said point, said porous sheets being formed of a substance which imparts to the sheets in the unimpregnated state a resistivity higher than that oi Said organic compound in the solid state, one only of said sheets being also impregnated with an organic dye soluble in said organic compound in the molten state and ionizable in said molten organic compound to form color-bearing ions having a net electric charge.
6. An electrographic marking sheet comprising an essentially dry paper sheet containing an impregnant comprising acetamide, formamide and Victoria blue in the proportions of about parts acetainide, 10 parts formamide and 2 to 4 parts Victoria blue, said sheet being adapted lor electrographic recording by reason of its ability to form color-bearing ions and provide an electrolytic path for the movement of said ions to the medium to be marked.
7. An essentially dry paper sheet, for electrographic recording, impregnated with acetamide and formamide in the proportions of about 10 parts of acetamide to 1 part of formamide.
RGBERT B. GIBNEY.
REFERENCES CITED The following references are of record in the le of this patent:
UNITED STATES PATENTS Number Name Date 6,420 Morse May 1, 1849 1,865,708 Sherman et al. July 5, 1932 1,910,568 Snyder May 23, 1933 2,035,474 Hay Mar. 2l, 1936 2,229,091 Kline Jan. 21, 1941 2,290,945 Dahlen July 28, 1942 2,294,146 Wise Aug. 25, 1942 2,306,471 Solomon Dec. 29, 1942 2,358,839 Wagner Sept. 26, 1944 2,423,556 Feibelmann July 8, 1947 FOREIGN PATENTS Number Country Date 25,292 Great Britain of 1898 251,970 Great Britain of 1927 435,092 Germany of 1926 28,923 Holland of 1933

Claims (1)

1. AN ELECTROGRAPHIC RECORDING MEDIUM COMPRISING TWO ESSENTIALLY DRY PAPAER SHEETS IN FACE TO FACE CONTACT, EACH IMPREGNATED WITH A MIXTURE OF ACETAMIDE AND FORMAMIDE IN THE PROPORTIONS OF ABOUT 100 PARTS OF THE FORMER TO 10 PARTS OF THE LATTER, ONE OF SAID SHEETS BEING ALSO IM-
US688739A 1946-08-06 1946-08-06 Electrographic recording Expired - Lifetime US2530956A (en)

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Cited By (5)

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Publication number Priority date Publication date Assignee Title
US2662803A (en) * 1949-06-29 1953-12-15 Faximile Inc Recording method and apparatus
US2776252A (en) * 1953-04-23 1957-01-01 Faximile Inc Dry electrical recording medium
US2786807A (en) * 1953-04-23 1957-03-26 Faximile Inc Dry electrical recording medium
US2863033A (en) * 1954-11-29 1958-12-02 Gen Electric Temperature detector and method of making
US5538601A (en) * 1995-09-14 1996-07-23 Elcorsy Inc. Electrocoagulation printing and apparatus

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US6420A (en) * 1849-05-01 Improvement in electric telegraphs
GB189825292A (en) * 1898-11-30 1899-07-29 Thomas Archibald Goodchild Improvements in the Production of Watermarks and other Designs and Impressions in or on Paper, Textiles, and other Materials.
DE435092C (en) * 1925-02-10 1926-10-07 I G Farbenindustrie Akt Ges Stuff printing process
GB251970A (en) * 1925-05-08 1927-05-19 Joseph Lahousse Improved insulating material for electric condensers and the like
US1865708A (en) * 1927-11-01 1932-07-05 Sherman Duplicating material
US1910568A (en) * 1932-04-30 1933-05-23 Theodore J Snyder Document paper
US2035474A (en) * 1933-02-21 1936-03-31 Donaid L Hay Spark recording system
US2229091A (en) * 1935-07-09 1941-01-21 Western Union Telegraph Co Telegraphic transmission of intelligence
US2290945A (en) * 1940-06-29 1942-07-28 Du Pont Printing of textile fabrics
US2294146A (en) * 1939-01-27 1942-08-25 Western Union Telegraph Co Electrosensitive recording blank
US2306471A (en) * 1937-12-08 1942-12-29 Rca Corp Electrolytic facsimile recording
US2358839A (en) * 1940-10-25 1944-09-26 Faximile Inc Electrolytic recording
US2423556A (en) * 1943-04-17 1947-07-08 Heyden Chemical Corp Hygroscopic liquid composition and the process of softening paper with said composition

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6420A (en) * 1849-05-01 Improvement in electric telegraphs
GB189825292A (en) * 1898-11-30 1899-07-29 Thomas Archibald Goodchild Improvements in the Production of Watermarks and other Designs and Impressions in or on Paper, Textiles, and other Materials.
DE435092C (en) * 1925-02-10 1926-10-07 I G Farbenindustrie Akt Ges Stuff printing process
GB251970A (en) * 1925-05-08 1927-05-19 Joseph Lahousse Improved insulating material for electric condensers and the like
US1865708A (en) * 1927-11-01 1932-07-05 Sherman Duplicating material
NL28923C (en) * 1928-06-14
US1910568A (en) * 1932-04-30 1933-05-23 Theodore J Snyder Document paper
US2035474A (en) * 1933-02-21 1936-03-31 Donaid L Hay Spark recording system
US2229091A (en) * 1935-07-09 1941-01-21 Western Union Telegraph Co Telegraphic transmission of intelligence
US2306471A (en) * 1937-12-08 1942-12-29 Rca Corp Electrolytic facsimile recording
US2294146A (en) * 1939-01-27 1942-08-25 Western Union Telegraph Co Electrosensitive recording blank
US2290945A (en) * 1940-06-29 1942-07-28 Du Pont Printing of textile fabrics
US2358839A (en) * 1940-10-25 1944-09-26 Faximile Inc Electrolytic recording
US2423556A (en) * 1943-04-17 1947-07-08 Heyden Chemical Corp Hygroscopic liquid composition and the process of softening paper with said composition

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2662803A (en) * 1949-06-29 1953-12-15 Faximile Inc Recording method and apparatus
US2776252A (en) * 1953-04-23 1957-01-01 Faximile Inc Dry electrical recording medium
US2776251A (en) * 1953-04-23 1957-01-01 Faximile Inc Electrical recording medium
US2786807A (en) * 1953-04-23 1957-03-26 Faximile Inc Dry electrical recording medium
US2863033A (en) * 1954-11-29 1958-12-02 Gen Electric Temperature detector and method of making
US5538601A (en) * 1995-09-14 1996-07-23 Elcorsy Inc. Electrocoagulation printing and apparatus

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