CA1305321C - Chromogenic copy systems and methods - Google Patents
Chromogenic copy systems and methodsInfo
- Publication number
- CA1305321C CA1305321C CA000572860A CA572860A CA1305321C CA 1305321 C CA1305321 C CA 1305321C CA 000572860 A CA000572860 A CA 000572860A CA 572860 A CA572860 A CA 572860A CA 1305321 C CA1305321 C CA 1305321C
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- CA
- Canada
- Prior art keywords
- color developer
- compound
- salicylic acid
- salicylate
- coating
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
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Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41M—PRINTING, DUPLICATING, MARKING, OR COPYING PROCESSES; COLOUR PRINTING
- B41M5/00—Duplicating or marking methods; Sheet materials for use therein
- B41M5/124—Duplicating or marking methods; Sheet materials for use therein using pressure to make a masked colour visible, e.g. to make a coloured support visible, to create an opaque or transparent pattern, or to form colour by uniting colour-forming components
- B41M5/132—Chemical colour-forming components; Additives or binders therefor
- B41M5/155—Colour-developing components, e.g. acidic compounds; Additives or binders therefor; Layers containing such colour-developing components, additives or binders
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- Chemical & Material Sciences (AREA)
- Chemical Kinetics & Catalysis (AREA)
- General Chemical & Material Sciences (AREA)
- Color Printing (AREA)
- Non-Silver Salt Photosensitive Materials And Non-Silver Salt Photography (AREA)
- Lubrication Of Internal Combustion Engines (AREA)
- Photoreceptors In Electrophotography (AREA)
- Medicines Containing Material From Animals Or Micro-Organisms (AREA)
- Heat Sensitive Colour Forming Recording (AREA)
Abstract
ABSTRACT OF THE DISCLOSURE
A pressure-sensitive chromogenic copy system comprising a transfer sheet having on at least a por-tion of at least one surface thereof a color developer capable of reacting with a chromogen to form a color image, said color developer comprising a crude reaction medium resulting from reactants used to prepare a salicylate and also containing therein at least one metal compound of such salicylate, the resultant transfer sheet, color developer and process for making such color developer.
A pressure-sensitive chromogenic copy system comprising a transfer sheet having on at least a por-tion of at least one surface thereof a color developer capable of reacting with a chromogen to form a color image, said color developer comprising a crude reaction medium resulting from reactants used to prepare a salicylate and also containing therein at least one metal compound of such salicylate, the resultant transfer sheet, color developer and process for making such color developer.
Description
CHROMOGENIC COPY SYSTEM AND METHODS
BACKGROUND OF THE I~VENTION
The present invention relates to novel pressure-sensitive chromogenic copy systems and receptor sheets and transfer sheets therefor, as well as novel com-positions for use as color developerc-.
The use of aromatic carboxylic acids in carbonless copying systems has been known in the art for a long time, and is described, among others, in U.S. Patents Nos. 3,488,207, 3,682,680, 3,772,052, 3,871,900, 3,896,255, 3,900,215, 3,934,070, 3,983,292, 4,303,719, 4,374,671, 4,372,583, 4,559,242, and 4,631,204. The salicylates, their metallic compounds and other salicylate derivatives including oligomers of salicylates and their metal compounds, appear to offer the best overall properties as image developers in carbonless systems. The rather complex manufacturing methods known to date for producing salicylates and the associated relatively high cost, howevex, has prevented 13~ ,?. ~1 any significant use of such materials in carbonless copy systems on a commercial basis.
It has now been discovered that a number of changes in the conventional production methods of salicylates 5 can be made which changes result in a significant reduction of the manufacturing costs of these salicyla-tes without diminishing their desired properties as color-developing materials in carbonless papers. These new processing methods are applicable to all the known 10 synthesis reactions for manufacture of salicylates and salicylate derivatives, and can yield materials with attractive and competitive cost structure which can result in a widespread use of these compounds in the carbonless paper industry. Additionally, the new 15 processing methods afford color developing materials which possess significantly improved properties (image intensity, speed of image formation, and image stability) over materials known in the prior art.
One of the commonly-used methods for producing 20 salicylates is the well-known Kolbe-Schmitt reaction (Schmitt, J. Pract. Chem., [ii], 31,397 (1885)), whereby the sodium salt of a phenol is heated with car-bon dioxide under pressure at a temperature of between 130-140C. Another method for manufacturing salicyla-25 tes is described by W. Meek and C. ~uschman in the .~
~3(J~
Journal of Chemical and Engineering Data, (Vol. 14, No.3, July 1969, p. 388) whereby carboxylation of substi-tuted phenols is performed under atmospheric conditions and with the use of N,N'-dimethylamide solvents to pro-5 duce substituted salicylates in superior yields.
Still another method for manufacturing salicylates of the present invention is the combination of the two aforementioned manufacturing methods, i.e., the use of solvents in combination with the use of pressurized lO environments of varying temperatures.
Irrespective of the manufacturing method used, the salicylates must be processed extensively; i.e., they must go through steps such as layer separation (if a solvent is used), purification (often repeated purifi-15 cation steps involving counter-current extractions), precipitation of the alkali salt of the salicylate to obtain the free acid by acidifying the aqueous layer containing the salicylate salt, filtration, and drying.
If the salicylate or salicylate derivative is to be used as a color developer, the carbonless system manu-facturer must process the material further to incor-porate it into a coating and apply it to the color-developing substrate. Such further processing by the 25 carbonless manufacturer may involve steps such as ~3~. S;~
grinding, dissolution, mixing with pigments and bin-ders, and, optionally, the formation of a polyvalent metal salt of the salicylate.
All the aforementioned processing steps by the 5 manufacturer of the salicylate and the manufacturer of the final carbonless product render the use of salicy-late and salicylate derivatives economically unattrac-tive.
SUMMARY OF THE INVENTION
It has now been surprisingly found that impure (crude) salicylic-containing compositions can be uti-lized without any purification as color-developing com-ponents in carbonless copy papers.
Briefly, the present invention comprises forming a 15 salicylic derivative capable of reacting with a chromo-gen used in carbonless copy papers and, after formation of the crude reaction medium containing such salicylic component, reac~ing or otherwise combining the crude suspension with a hydrogen-donating compound or a 20 metallic compound, preferably a lithium or a multivalent metallic compound of a metal selected from Groups IIIA through Ivs of the Periodic Table, or mixtures thereof to form a metal compound of the salicylate.
The invention also comprises carbonless copy ~3~S~
systems utilizing such products produced in accordance with the teachings of this invention; e.g., the products produced from the salicylic components, as well as transfer sheets and receptor sheets useful in carbonless papers, as well as the resultant color-developer compositions.
In a preferred embodiment there is provided A preSsure-sensitive chromogenic copy system comprising a transfer sheet having on at least a por-tion of at least one surface thereof a coating of a color developer capable of reacting with a chromogen to form a color image, said color developer comprising a crude reaction medium resulting from reactants used to prepare a salicylate and also containing therein at least one metal compound of such salicylate.
DETAILED DESCRIPTION
As used herein, the phrase "metal compound of the salicylate" means salts, complexes, adducts, esters, mixtures, and all other products resulting from combining the salicylates with the noted metal 20 compounds.
Also the term "crude" means that the reaction mixture resulting from the carboxylation step is not treated to the extent necessary to obtain a salicylic component in completely pure form. Partial 25 purification such as washing and/or distillation and/or extraction may be employed to reduce some of the impurities present. For instance, the content of 13(~
- 5a -unreacted phenol may be lowered to no less than about 10~, more usually no less than lS to 20% by weight of the reaction mixture. However, it has also been found that the reaction mixture from the carboxylation reaction containing 30~ or more unreacted phenol can be used without any purification.
,1 ' ~3(~5~1 The particular salicylate used is of little rele-vance. It can, ~or example, either be a salicylic acid, or oligomeric or polymeric salicylate or thio~
salicylate, or any other salicylate which has been or 5 can be used as a color developer in carbonless copy systems. Examples have been noted above with reference to certain patents. Preferably, salicylic acid and alkylated, cycloalkylated, or arylated salicylates are used. Salicylates with Cl to C20 alkyl groups are 10 used; C2 to C12 alkylated salicylates being especially preferred with octyl and nonyl salicylates being exemplary. As to the arylated salicylates, any phenyl or cyclohexyl salicylic acid can be used.
Of significance and importance is the proper pro-15 cessing of the material during its manufacture.
In one aspect of this invention relating to themanufacture of salicylates by the well-known reaction between substituted or unsubstituted phenols with car-bon dioxide in water under pressure, the entire reac-20 tion mixture after the reaction is completed is treatedin accordance with the present invention to produce the desired salicylate moiety. The thus treated crude mixture contains the desired salicylate moiety as well as up to about 80% by weight of unreacted phenol, carbonates (primarily bicarbonates) and other ~3(~
impurities. A~ter the reaction between the phenol and carbon dioxide has been completed, the pH of the crude aqueous medium is raised to between about pH 7.5 to 12.5 with an alkali such as aqueous ammonia, LiOH, 5 NaOH, K~H, or combinations of aqueous amonia with LiOH
or with other water soluble hydroxides; aqueous ammonia or combinations of aqueous ammonia with other alkalis has been found to be the preferred ~ay of adjusting the pH of the coating dispersions containing the crude 10 salicylates of this invention.
Following the adjustment of the pH of the crude aqueous medium, a polyvalent metallic compound selected from Groups IIIA through IVB of the Periodic Table may be added to form the desired metal compound of the 15 salicylate. The use of lithium alone in an amount stoichiometric to the particular salicylic acid in the crude mixture or in an amount less than stoichiometric and using aqueous ammonia to reach stoichiometry or beyond can obviate the use of polyvalent metallic com-20 pounds.
Further, it has been unexpectedly found that thecareful adjustment of the pH of the final coating dispersion with a hydrogen-donating compound such as an organic or inorganic acid; e.g., hydrochloric, acetic, 25 sulfuric, citric, maleic, glyoxylic, glycolic, and the 13(~S;~l like and mixtures thereof can also obviate the use of polyvalent metal compounds.
Another unexpected finding of this invention is that controlling the pH of the coating dispersions 5 containing salicylates or salicylate derivatives, made in accordance with the processes of this invention, by the use of aqueous ammonia and permanent alkalis, along with the use of mineral inorganic acids to effect a pH
of the dried CF coated surface of between 5.0 and 8.0, 10 and preferably between 5.5 and 7.5, can offer the best image properties of the salicylates as color develo-pers. The preferred mode of this invention, however, is the use of polyvalent metal compounds along with the careful pH adjustments of the coating dispersions and 15 coated surfaces. Preferred polyvalent metals added are zinc, nickel, cadmium, titanium, aluminum, tin, magne-sium, and manganese and the like, and mixtures thereof with zinc being especially preferred. It is possible to use a mixture of polyvalent metals and the monova-20 lent lithium and/or hydrogen compounds. Dependent uponthe particular salicylate, the metal compound used, and the quantity thereof which is added, a precipitate may form, but such precipitate as well as the remaining portions of the aqueous solution containing the other 25 materials such as noted unreacted phenol, bicarbonates, 13C~S;:~2~
and the like or the entire solution, if no precipitate is formed, can be easily and directly formulated as hereinafter set forth into a color-developing coating.
The mechanism by which the presence of metallic 5 compounds potentiate the image-forming and image-stabilizing properties of the salicylate compounds is not well understood to date. It has been found, ho~ever, during the course of this invention that the nature, i.e., ionizable (salt), or nonionizable (pigments, etc.), of the metallic compound used to form the final salicylate color developer does not appear critical; this point is easily exemplified in Table I, where various salicylates, combined with different metallic compounds of varying nature such as salts, 15 pigments, and esters, exhibit essentially no difference in their ability to affect the intensity, or the light stability of the final image formed.
The color-developing coating is prepared by admixing the impure salicylate mixture with 20 conventional pigments such as clays, carbonates and the like and/or conventional adhesives or binders such as natural or modified starches, latexes, partially or fully hydrolyzed polyvinyl alcohols, proteins, gums, and the like conventionally used in forming carbonless copy paper; all being added in their usual amounts for their usual effect. Other conventional additives such as pigment dispersants and coating lubricants can also 5 be used.
The main function of the conven~ionally used pigments in preparing coated front (CF) formulations, is to "extend" or "spread out" the principal color-developing material for a more efficient use. In this 10 invention, the nature of the extending pigment is inconsequential; calcium carbonate, various types of clays, or combinations of calcium carbonate and clays have been used as extending pigments in formulating the impure salicylates of this invention, without any 15 apparent influence in the functional properties of the CFs containing the salicylates noted herein as color developers. This is demonstrated in Table II, where the same salicylate moiety is formulated with different extending pigments without any evident loss in func-20 tional properties.
A generally accepted indicator of the efficiency of a color developing material in carbonless CF papers is the amoun~ of the color developer used relative to the amount of the extending pigment, usually expressed as a 25 percent by weight of the color developer on the weight of the pigment. It has been surprisingly found during the development of this invention that only relatively small amoun-ts of the salicylates are required to give superior results, i.e., speed of image formation and 5 image intensity and stability, when the salicylates are manufactured and processed in accordance with ~he modes described herein. For example, 4~ to 10% by weight of the salicylates of the present invention on the weight of the pigment is sufficient to produce superior image 10 intensities and stabilities compared to color-developing materials heretofore described in the prior art [U.S. Patent Nos. 3,934,070, 4,051,303, 4,147,830, 4,159,208 and othersl and reported to be used at between 30% and 1000~ of the weight of the color 15 developer on the weight of the pigment.
The final mixture is applied in the conventional manner as by conventional paper coaters, such as an air knife, gate roll, blade, reverse roll, and the like in the usual thickness to substrates conventionally used 20 for forming carbonless copy paper (usually paper) to form the color-developing part (receptor or transfer sheet) of a carbonless pressure-sensitive chromogenic copy system~ Alternatively, the coating noted can be mixed with a solution of leuco dyes containing 25 microcapsules and applied to a single surface to form a 13~S;32~
"self-contained" type of carbonless system.
If the manufacturing method used to produce the salicylate involves the use of a solvent, the salicylate formed is usually extracted from the 5 solvent by the addition of sufficient amounts of water and unreacted or uncarboxylated phenols usually stay mainly in the solvent layer and do not interfere with the processing of the water layer. The water layer in addition to the desired salicylate usually contains up 10 to about 5~ to 6% by weight of solvent, up to 50~ by weight or more of unreacted phenol, up to about 10% by weight of catalyst, and up to about 15% by weight of carbonates (primarily bicarbonates). Following the separation the water layer is treated in the manner 15 described above to form the metal compound of a salicy-late and color developer.
If an oligomeric or polymeric condensation product of the salicylate is the final desired color developer subsequent to the carboxylation reaction and layer 20 separation, if one is required, as is conventional, the pH of the water layer is again adjusted to the alkaline side for the formation of oligomers or pH on the acid side for the formation of higher molecular weight poly-mers and the condensation agent, such as an aldehyde or 25 the like, is added and the condensation reaction is ~3t~S~"~
allowed to proceed under time and temperature con-ditions suitable for the formation of the desired pro-duct. Such reaction conditions are conventional and described in the literature. At the completion of the 5 condensation reaction the total solution is treated in the same manner as described above with respect to treating the reaction product resulting from reacting phenols with carbon dioxide. In the event that the layer separation is not totally complete any residual 10 solvent that may be carried through to the water layer does not have any detrimental effect on either the reactive processes of the salicylate as color developers, nor on the behavior or properties of the final coating.
For eEfective color-developer use, the crude sali- r cylate solution should contain at least about 5% to 25 by weight of the particular salicylate. This permits preparation of the color developer which preferably should contain at least about i% by weight of salicy-late, dependent upon the particular salicylate used.
Ordinarily larger amounts are utilized to ensure color development, such as at least about 4% by weight.
The presence of varying amounts of impurities have no detrimental effect on, and in some cases even improve, the overall performance o~ the salicylates of 13~1S~
this invention as color developers, as can be demonstrated by the results presented in Table II. To have a proper comparison, the ratios of all the components such as salicylate to pigment, pigment to 5 binder, etc., were kept constant; only the amount of the impurities was varied. All intensity measurements were made using the same, commercially available capsule-coated CB (Coated Back) paper. Strips of CB
paper were mated with CF paper, a constant pressure was 10 applied to crush the microcapsules of the CB paper and produce the colored images on the CF surface. The instrument used to make the intensity measurements was a Brightimeter Micro S4-M Brightness, Opacity, and Color Tester. The L value on the ~unter L,a,b scale 15 which the Brightimeter calculates was taken as a measure of the color intensity of the images. Since lower L values on the 0-100 scale mean higher image intensities, the Intensity values ~I) presented in Tables I and II were calculated as 100-L.
To measure light resistance, the colored images were exposed for twenty hours to a General ~lectric cool white fluorescent bulb at a distance of six inches and the intensity of the image was compared before and after exposure. The % light resistance was calculated from the following formula:
13~;tS;~
Light Resistance = (I ~efore ~ ter) x 100 I Before The invention will be further described in connec-tion with the following examples and tables which are set forth for purposes of illustration only.
Thirty-five grams of xylener 20.6 grams (0.1 mole) of p-octyl phenol, and 12.5 grams of a 45% aqueous solution of potassium hydroxide are charged into a suitable reactor equipped with a turbine-type agita-tor. The reaction mixture is heated to reflux, separating the water into a Dean-Starke trap; heating is continued until the mixture is dehydrated and the theoretical amount of water (8.7 g) has been collected.
The reaction mixture is cooled to 120C under a nitro-gen atmosphere, and 7.3 grams (0.1 mole) of dimethyl formamide are added; while maintaining the agitation and the temperature to between 125-130C, 4.5 grams of carbon dioxide are added to the mixture through a sub-surface gas inlet tube for approximately 30 to 60 minu-tes. The solution temperature of 125-130C is maintained for about one additional hour after the addition of the carbon dioxide has been completed. The reaction mixture is then cooled to about 90C, 68-70 grams of water are added with thorough mixing for about ~3U5~
15 to 20 minutes, the mixing is stopped and the phase separation is allowed to occur. The lower layer ~water phase) containing the potassium salt octyl salicylic acid product (about 20~ by weight) as well as the 5 impurities; primarily octyl phenol, xylene, dimethyl formamide, and potassium bicarbonate, is drained off into a suitable vessel equipped with an agitator, and the pH is raised to between 12 and 13 with an aqueous solution of concentrated ammonia. Fourteen grams of a 10 50% by weight aqueous solution of zinc chloride are added slowly and with agitation forming a precipitate;
this precipitate remains stable over an indefinite period of time and over a wide range of temperatures.
The coating can be prepared by applying the crude 15 solution containing the flocculant precipitate directly to a paper substrate at very low coating weights of about 1.5 to 2.2 g/m2, after mixing with small amounts (10% to 15~ by weight on a dry basis) of one or more binders such ethylated or oxidized starches, and/or 20 small amounts (10% to 15% by weight) of a styrene-butadiene latex (Dow's latex-638), producing a receptor or color developer coated front (CF) part of a car-bonless paper product. When the CF surface is mated with a coated back (CB) part of a carbonless form con-25 taining leuco dyes (usually in an encapsulated form) 13~
and localized pressure is applied, bright and intenseimages are formed instantaneously on the CF surface.
Alternatively, the solution containing the floc-culant precipitate is formulated into a coating by the 5 addition of 200 grams of calcium carbonate, 130 grams of a 20~ aqueous solution of ethylated starch, and 30 grams of Dow's latex-~38 ~48% by weight aqueous solu-tion) and applied to a paper substrate at low coating weights (2 to 3 g/m2). Images of the same high inten-10 sity, speed and brightness as those obtained from thenonpigmented formulation are obtained.
COMPARATIVE EXAMPLE la Twenty-five grams of pure, conventionally produced octyl salicylic acid are dissolved in 100 grams of 15 water with the aid of 12.5 grams of a 45~ aqueous solu-tion of potassium hydroxide. The pH of the solution is raised to between 12 and 13 using a concentrated solu-tion of aqueous ammonia, mixed with 14 grams of a 50~
aqueous solution of zinc chloride and formulated into 20 coatings (with and without pigments) as described in Example 1 above. The properties of the images formed on the CF paper of this example are identical to the properties of the images produced on the CF of Example 1.
13~5~i _XAMPLE 2 Example 1 is repeated, but the aqueous layer con-taining the octyl salicylic acid is drained off into a suitable vessel equipped with an agitator, 4 grams of 5 an aqueous (37% by weight) formaldehyde solution are added and the reaction mixture is heated to between 85 and 90C and maintained at this temperature for 2 to 4 hours while maintaining the pH at between 8.5 and 9.
At the end of this reaction, almost all of the for-10 maldehyde has been consumed, and oligomers of the octylsalicylate have been formed. The crude oligomeric octyl salicylate reaction mass is treated in a similar manner to that described in Example l; i.e., the pH is raised to between 12 and 13 with concentrated aqueous 15 ammonia, and the zinc chloride solution is added to form the flocculant precipitate. 5ubsequently, the solution containing the flocculant precipitate is for-mulated into the coatings described in Example 1 and applied to a paper substrate in equivalent coating 20 weights. The images produced on such CF surfaces possess properties similar to the images produced in Example 1, but in addition they exhibit improved sta-bility to severe light exposures.
Example 1 is repeated, but the p-octyl phenol is 13~:i;3~
replaced with equimolar quantities of p-tert.butyl phenol. Equivalent results are obtained.
Example 2 is repeated, but the water layer contains 5 the p-tert.butyl salicylate produced in Example 3. The CF papers produced using the methods described in Example 1 exhibit equivalent properties.
Example 1 is repeated, but the p-octyl phenol is 10 replaced with equimolar quantities of 2,4, ditertiary butyl phenol. The resultant material, 3,5, ditertiary butyl salicylate, and/or its metal salts, when used as the color developer in a CF coating exhibit properties equivalent to those obtained with the octyl salicylate-15 containing CF.
Example 1 is repeated up to the point of drainingoff the lower layer (water phase) containing the potassium salt of the salicylic acid product, except 20 that the p-octyl phenol is replaced with equimolar quantities of phenol. The resultant salicylic acid salt contained in the water layer is reacted with 16 grams of aqueous formaldehyde solution ~37% by weight) in the presence of 25 grams of 12N sulfuric acid solution at a temperature of 95 to 97C for one hour to 13(~5~1 produce d high molecular weight polymer of salicylic acid. The alkaline salt of this material was treated in a manner si~lilar to that described in Example 1 to form the flocculant precipitate, and formulated into 5 coatin~s according to the methods described in Example 1. The CF papers produced containing the material of this example exhibited properties similar to those of the CF produced in Example 1, but the images required substantially higher amount of time to develop full 10 intensities.
Example 1 i5 repeated throughout, but the p-octyl phenol is replaced with equimolar quantities of 2-methyl, 3-isobutylthiophenol. The resultant product, 15 2-hydroxy-4-methyl-5-isobutylthiobenzoic acid and/or its metal salts, when used as the color developer in a CF coating exhibit properties equivalent to those obtained with the CF containing the octyl salicylate product.
Example 1 is repeated in its entirety, but the p-octyl phenol is replaced with equimolar quantities of p-t-butylthiophenol. The resultant product, 2-hy-droxy-5-t-butylthiobenzoic acid and/or its metal 25 salts, when used as the color developer in a CF
~31~S~
coating, exhibit properties equivalent to those obtained with the CF containing the octyl salicylate product.
EXAMPL~ 9 Twenty grams of an impure mixture of m-nonyl sali-cylic acid and nonyl phenol containing about 11 grams (55% o~ total mixture weight) of nonyl phenol and about 1-1.5 grams of potassium carbonate and xylene, are dissolved in 100 grams of water containing 1.5 dry 10 grams of sodium hydroxide. While maintaining the solution under agitation, 5.8 grams of 50% by weight of an aqueous solution of zinc chloride are added and allowed to react, forming the zinc salt of the nonyl salicylic acid. Subsequently, 100 grams of a 72~
15 by weight dispersion of calcium carbonate in water are added along with 17 grams of Dow's latex-620 (50~ by weight) and 42 grams of a 20% by weight aqueous solution of ethylated starch, the pH of the dispersion is adjusted to about 9.5 with concentrated aqueous 20 ammonium hydroxide solution (28% by weight), and the final coating is applied to a paper substrate at coating weights of between 3 and 5 g/m2, producing a receptor or color developer coated front (CF) part of a carbonless product. When the CF surface is mated with 25 a coated back (CB) of a carbonless form containing ~3(~
leuco dyes (usually in an encapsulated form) and localized pressure is applied, bright and intense images are formed instantaneously on the CF surface.
The process of Example 9 is repeated except that 1 gram of lithium hydroxide is substituted for the 1.5 grams of sodium hydroxide used therein and no zinc chloride is added. Equivalent results are obtained.
Twenty grams of an impure mixture of m-nonyl salicylic acid and nonyl phenol containing about 50% by weight nonyl salicylic acid, about 43-45% by weight nonyl phenol, and about 5-7% by weight of potassium carbonate and xylene, are dissolved in 90 grams of water 15 containing 0.5 dry gram of sodium hydroxide, and 10 grams of concentrated aqueous ammonium hydroxide.
While maintaining the solution under agitation, 15 grams of zinc oxide are thoroughly dispersed therein.
Subsequently, 213 grams of a 72% by weight dispersion 20 of calcium carbonate and kaolin clays in water are added along with 36 grams of Dow's latex-620 (50%
solids by weight) and 92 grams of a 20~ by weight aqueous solution of ethylated starch. The pH of the dispersion is adjusted to about 11 with a concentrated 25 aqueous ammonium hydroxide solution ~28% by weight), 13(~5~
and applled onto a paper substrate at a coating weight of between 5 and 7 g/m2 producing a receptor or color developer coated front (CF) part of a carbonless product. When the CF surface is mated with a coated S back (CB) of a carbonless form containing encapsulated leuco dye and localized pressure is applied, bright and intense images are formed instantaneously on the CF
surface.
The process of Example 9 is repeated except that the amount of zinc chloride solution is reduced to 4 grams. Equivalent results are obtained.
~he process of Example 11 is repeated except that 15 the amount of zinc oxide is reduced to 4 grams.
Equivalent results are obtained.
The process of Example 9 is repeated except that the zinc chloride is replaced with 15 grams of an 18%
20 by weight solution of zinc octoate in mineral spirits.
Equivalent results are obtained.
The process of Example 11 is repeated except that the 213 grams of the calcium carbonate and kaolin clays 25 dispersion are replaced with 213 grams of a 72~ by 13(~S3~i weight dispersion of kaolin clays in water. Equivalent results are obtained.
The process of Example 11 is repeated except that 5 the 213 grams of the calcium carbonate and kaolin clays dispersion are replaced with 213 grams of a 72% by weight dispersion of a 50-50 mixture of calcium carbonate and kaolin clays. Equivalent results are obtained.
The process of Example 9 is repeated except that the zinc chloride is replaced with 8 grams of a 12~ by weight hydrochloric acid solution. Equivalent results are obtained.
Examples 9 through 1~ are repeated except that the 20 grams of the impure mixture of nonyl salicylic acid are replaced with 13.5 grams of an impure mixture containing about 75% by weight nonyl salicylic acid, 20 about 20 to 22% by weight of nonyl phenol, and about 3 to 5% by weight potassium carbonate and xylene.
Equivalent results are obtained in all cases.
The processes of Examples 9 and 11 are repeated 25 except that the 20 grams of impure nonyl salicylic acid 13(~5~1 mixture are replaced with 10 grams of pure nonyl salicylic acid. Comparable results are obtained.
A self-contained carbonless system is prepared by 5 the following procedure:
Microcapsules containing leuco color formers are manufactured according to the specifications of U.S.
Patent No. 4,586,060, as follows:
An oiL solution comprising 90 grams of 10 monoisopropylbiphenolr 3 grams of Hilton Davis' ~-102 black leuco dye, 1 gram of Crystal Violet Lactone, 0.5 --gram of benzoyl leuco methylene blue, 0.4 gram of Hilton Davis' Kopichem XIV leuco dye, and 5 grams of a hexamethylene di-isocyanate adduct (Mobay's Desmondur 15 L-2291A) are emulsified with 100 grams of a 13% by weight aqueous solution of gelatin (Hudson Industries G-llO). Emulsification is continued until an average particle size of between 5 and 5.5 microns are obtained and the solution is heated to 65C for about two hours.
20 Subsequently, 10 grams of a 10% by weight polyvinyl alcohol (Airco's Vinol-205), 1 gram of toluene, and 1 gram of Desmondure L-2291A are added with agitation and the heating is continued at 65C for an additional two hours. The microcapsular dispersion is cooled to room 25 temperature and mixed with 35 grams of load-bearing *Trade mark ~1''~' ~3US3~1 material such as Henkel's Keestar-328, a granular, `~
uncooked starch, and lO0 grams of a 20% by weight aqueous solution of ethylated starch. The solids of the microcapsular dispersion are adjusted with water to 5 between 35 and 40% by weight.
Two hundred grams of a color developer CF coating prepared according to the procedure of Example ll are thoroughly mixed with 75 grams of the microcapsular dispersion of this Example, coated onto a paper lO substrate at a coating weight of about 6.5 gms/m2, and dried. When pressure is applied to the coated surface, the microcapsules are ruptured, releasing the oily material containing the leuco color developers and forming an in-situ black image of high intensity and 15 excellent light stability.
Examples l and 2 are repeated except that the pH is raised to only about ll to 12. Comparable results are obtained.
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BACKGROUND OF THE I~VENTION
The present invention relates to novel pressure-sensitive chromogenic copy systems and receptor sheets and transfer sheets therefor, as well as novel com-positions for use as color developerc-.
The use of aromatic carboxylic acids in carbonless copying systems has been known in the art for a long time, and is described, among others, in U.S. Patents Nos. 3,488,207, 3,682,680, 3,772,052, 3,871,900, 3,896,255, 3,900,215, 3,934,070, 3,983,292, 4,303,719, 4,374,671, 4,372,583, 4,559,242, and 4,631,204. The salicylates, their metallic compounds and other salicylate derivatives including oligomers of salicylates and their metal compounds, appear to offer the best overall properties as image developers in carbonless systems. The rather complex manufacturing methods known to date for producing salicylates and the associated relatively high cost, howevex, has prevented 13~ ,?. ~1 any significant use of such materials in carbonless copy systems on a commercial basis.
It has now been discovered that a number of changes in the conventional production methods of salicylates 5 can be made which changes result in a significant reduction of the manufacturing costs of these salicyla-tes without diminishing their desired properties as color-developing materials in carbonless papers. These new processing methods are applicable to all the known 10 synthesis reactions for manufacture of salicylates and salicylate derivatives, and can yield materials with attractive and competitive cost structure which can result in a widespread use of these compounds in the carbonless paper industry. Additionally, the new 15 processing methods afford color developing materials which possess significantly improved properties (image intensity, speed of image formation, and image stability) over materials known in the prior art.
One of the commonly-used methods for producing 20 salicylates is the well-known Kolbe-Schmitt reaction (Schmitt, J. Pract. Chem., [ii], 31,397 (1885)), whereby the sodium salt of a phenol is heated with car-bon dioxide under pressure at a temperature of between 130-140C. Another method for manufacturing salicyla-25 tes is described by W. Meek and C. ~uschman in the .~
~3(J~
Journal of Chemical and Engineering Data, (Vol. 14, No.3, July 1969, p. 388) whereby carboxylation of substi-tuted phenols is performed under atmospheric conditions and with the use of N,N'-dimethylamide solvents to pro-5 duce substituted salicylates in superior yields.
Still another method for manufacturing salicylates of the present invention is the combination of the two aforementioned manufacturing methods, i.e., the use of solvents in combination with the use of pressurized lO environments of varying temperatures.
Irrespective of the manufacturing method used, the salicylates must be processed extensively; i.e., they must go through steps such as layer separation (if a solvent is used), purification (often repeated purifi-15 cation steps involving counter-current extractions), precipitation of the alkali salt of the salicylate to obtain the free acid by acidifying the aqueous layer containing the salicylate salt, filtration, and drying.
If the salicylate or salicylate derivative is to be used as a color developer, the carbonless system manu-facturer must process the material further to incor-porate it into a coating and apply it to the color-developing substrate. Such further processing by the 25 carbonless manufacturer may involve steps such as ~3~. S;~
grinding, dissolution, mixing with pigments and bin-ders, and, optionally, the formation of a polyvalent metal salt of the salicylate.
All the aforementioned processing steps by the 5 manufacturer of the salicylate and the manufacturer of the final carbonless product render the use of salicy-late and salicylate derivatives economically unattrac-tive.
SUMMARY OF THE INVENTION
It has now been surprisingly found that impure (crude) salicylic-containing compositions can be uti-lized without any purification as color-developing com-ponents in carbonless copy papers.
Briefly, the present invention comprises forming a 15 salicylic derivative capable of reacting with a chromo-gen used in carbonless copy papers and, after formation of the crude reaction medium containing such salicylic component, reac~ing or otherwise combining the crude suspension with a hydrogen-donating compound or a 20 metallic compound, preferably a lithium or a multivalent metallic compound of a metal selected from Groups IIIA through Ivs of the Periodic Table, or mixtures thereof to form a metal compound of the salicylate.
The invention also comprises carbonless copy ~3~S~
systems utilizing such products produced in accordance with the teachings of this invention; e.g., the products produced from the salicylic components, as well as transfer sheets and receptor sheets useful in carbonless papers, as well as the resultant color-developer compositions.
In a preferred embodiment there is provided A preSsure-sensitive chromogenic copy system comprising a transfer sheet having on at least a por-tion of at least one surface thereof a coating of a color developer capable of reacting with a chromogen to form a color image, said color developer comprising a crude reaction medium resulting from reactants used to prepare a salicylate and also containing therein at least one metal compound of such salicylate.
DETAILED DESCRIPTION
As used herein, the phrase "metal compound of the salicylate" means salts, complexes, adducts, esters, mixtures, and all other products resulting from combining the salicylates with the noted metal 20 compounds.
Also the term "crude" means that the reaction mixture resulting from the carboxylation step is not treated to the extent necessary to obtain a salicylic component in completely pure form. Partial 25 purification such as washing and/or distillation and/or extraction may be employed to reduce some of the impurities present. For instance, the content of 13(~
- 5a -unreacted phenol may be lowered to no less than about 10~, more usually no less than lS to 20% by weight of the reaction mixture. However, it has also been found that the reaction mixture from the carboxylation reaction containing 30~ or more unreacted phenol can be used without any purification.
,1 ' ~3(~5~1 The particular salicylate used is of little rele-vance. It can, ~or example, either be a salicylic acid, or oligomeric or polymeric salicylate or thio~
salicylate, or any other salicylate which has been or 5 can be used as a color developer in carbonless copy systems. Examples have been noted above with reference to certain patents. Preferably, salicylic acid and alkylated, cycloalkylated, or arylated salicylates are used. Salicylates with Cl to C20 alkyl groups are 10 used; C2 to C12 alkylated salicylates being especially preferred with octyl and nonyl salicylates being exemplary. As to the arylated salicylates, any phenyl or cyclohexyl salicylic acid can be used.
Of significance and importance is the proper pro-15 cessing of the material during its manufacture.
In one aspect of this invention relating to themanufacture of salicylates by the well-known reaction between substituted or unsubstituted phenols with car-bon dioxide in water under pressure, the entire reac-20 tion mixture after the reaction is completed is treatedin accordance with the present invention to produce the desired salicylate moiety. The thus treated crude mixture contains the desired salicylate moiety as well as up to about 80% by weight of unreacted phenol, carbonates (primarily bicarbonates) and other ~3(~
impurities. A~ter the reaction between the phenol and carbon dioxide has been completed, the pH of the crude aqueous medium is raised to between about pH 7.5 to 12.5 with an alkali such as aqueous ammonia, LiOH, 5 NaOH, K~H, or combinations of aqueous amonia with LiOH
or with other water soluble hydroxides; aqueous ammonia or combinations of aqueous ammonia with other alkalis has been found to be the preferred ~ay of adjusting the pH of the coating dispersions containing the crude 10 salicylates of this invention.
Following the adjustment of the pH of the crude aqueous medium, a polyvalent metallic compound selected from Groups IIIA through IVB of the Periodic Table may be added to form the desired metal compound of the 15 salicylate. The use of lithium alone in an amount stoichiometric to the particular salicylic acid in the crude mixture or in an amount less than stoichiometric and using aqueous ammonia to reach stoichiometry or beyond can obviate the use of polyvalent metallic com-20 pounds.
Further, it has been unexpectedly found that thecareful adjustment of the pH of the final coating dispersion with a hydrogen-donating compound such as an organic or inorganic acid; e.g., hydrochloric, acetic, 25 sulfuric, citric, maleic, glyoxylic, glycolic, and the 13(~S;~l like and mixtures thereof can also obviate the use of polyvalent metal compounds.
Another unexpected finding of this invention is that controlling the pH of the coating dispersions 5 containing salicylates or salicylate derivatives, made in accordance with the processes of this invention, by the use of aqueous ammonia and permanent alkalis, along with the use of mineral inorganic acids to effect a pH
of the dried CF coated surface of between 5.0 and 8.0, 10 and preferably between 5.5 and 7.5, can offer the best image properties of the salicylates as color develo-pers. The preferred mode of this invention, however, is the use of polyvalent metal compounds along with the careful pH adjustments of the coating dispersions and 15 coated surfaces. Preferred polyvalent metals added are zinc, nickel, cadmium, titanium, aluminum, tin, magne-sium, and manganese and the like, and mixtures thereof with zinc being especially preferred. It is possible to use a mixture of polyvalent metals and the monova-20 lent lithium and/or hydrogen compounds. Dependent uponthe particular salicylate, the metal compound used, and the quantity thereof which is added, a precipitate may form, but such precipitate as well as the remaining portions of the aqueous solution containing the other 25 materials such as noted unreacted phenol, bicarbonates, 13C~S;:~2~
and the like or the entire solution, if no precipitate is formed, can be easily and directly formulated as hereinafter set forth into a color-developing coating.
The mechanism by which the presence of metallic 5 compounds potentiate the image-forming and image-stabilizing properties of the salicylate compounds is not well understood to date. It has been found, ho~ever, during the course of this invention that the nature, i.e., ionizable (salt), or nonionizable (pigments, etc.), of the metallic compound used to form the final salicylate color developer does not appear critical; this point is easily exemplified in Table I, where various salicylates, combined with different metallic compounds of varying nature such as salts, 15 pigments, and esters, exhibit essentially no difference in their ability to affect the intensity, or the light stability of the final image formed.
The color-developing coating is prepared by admixing the impure salicylate mixture with 20 conventional pigments such as clays, carbonates and the like and/or conventional adhesives or binders such as natural or modified starches, latexes, partially or fully hydrolyzed polyvinyl alcohols, proteins, gums, and the like conventionally used in forming carbonless copy paper; all being added in their usual amounts for their usual effect. Other conventional additives such as pigment dispersants and coating lubricants can also 5 be used.
The main function of the conven~ionally used pigments in preparing coated front (CF) formulations, is to "extend" or "spread out" the principal color-developing material for a more efficient use. In this 10 invention, the nature of the extending pigment is inconsequential; calcium carbonate, various types of clays, or combinations of calcium carbonate and clays have been used as extending pigments in formulating the impure salicylates of this invention, without any 15 apparent influence in the functional properties of the CFs containing the salicylates noted herein as color developers. This is demonstrated in Table II, where the same salicylate moiety is formulated with different extending pigments without any evident loss in func-20 tional properties.
A generally accepted indicator of the efficiency of a color developing material in carbonless CF papers is the amoun~ of the color developer used relative to the amount of the extending pigment, usually expressed as a 25 percent by weight of the color developer on the weight of the pigment. It has been surprisingly found during the development of this invention that only relatively small amoun-ts of the salicylates are required to give superior results, i.e., speed of image formation and 5 image intensity and stability, when the salicylates are manufactured and processed in accordance with ~he modes described herein. For example, 4~ to 10% by weight of the salicylates of the present invention on the weight of the pigment is sufficient to produce superior image 10 intensities and stabilities compared to color-developing materials heretofore described in the prior art [U.S. Patent Nos. 3,934,070, 4,051,303, 4,147,830, 4,159,208 and othersl and reported to be used at between 30% and 1000~ of the weight of the color 15 developer on the weight of the pigment.
The final mixture is applied in the conventional manner as by conventional paper coaters, such as an air knife, gate roll, blade, reverse roll, and the like in the usual thickness to substrates conventionally used 20 for forming carbonless copy paper (usually paper) to form the color-developing part (receptor or transfer sheet) of a carbonless pressure-sensitive chromogenic copy system~ Alternatively, the coating noted can be mixed with a solution of leuco dyes containing 25 microcapsules and applied to a single surface to form a 13~S;32~
"self-contained" type of carbonless system.
If the manufacturing method used to produce the salicylate involves the use of a solvent, the salicylate formed is usually extracted from the 5 solvent by the addition of sufficient amounts of water and unreacted or uncarboxylated phenols usually stay mainly in the solvent layer and do not interfere with the processing of the water layer. The water layer in addition to the desired salicylate usually contains up 10 to about 5~ to 6% by weight of solvent, up to 50~ by weight or more of unreacted phenol, up to about 10% by weight of catalyst, and up to about 15% by weight of carbonates (primarily bicarbonates). Following the separation the water layer is treated in the manner 15 described above to form the metal compound of a salicy-late and color developer.
If an oligomeric or polymeric condensation product of the salicylate is the final desired color developer subsequent to the carboxylation reaction and layer 20 separation, if one is required, as is conventional, the pH of the water layer is again adjusted to the alkaline side for the formation of oligomers or pH on the acid side for the formation of higher molecular weight poly-mers and the condensation agent, such as an aldehyde or 25 the like, is added and the condensation reaction is ~3t~S~"~
allowed to proceed under time and temperature con-ditions suitable for the formation of the desired pro-duct. Such reaction conditions are conventional and described in the literature. At the completion of the 5 condensation reaction the total solution is treated in the same manner as described above with respect to treating the reaction product resulting from reacting phenols with carbon dioxide. In the event that the layer separation is not totally complete any residual 10 solvent that may be carried through to the water layer does not have any detrimental effect on either the reactive processes of the salicylate as color developers, nor on the behavior or properties of the final coating.
For eEfective color-developer use, the crude sali- r cylate solution should contain at least about 5% to 25 by weight of the particular salicylate. This permits preparation of the color developer which preferably should contain at least about i% by weight of salicy-late, dependent upon the particular salicylate used.
Ordinarily larger amounts are utilized to ensure color development, such as at least about 4% by weight.
The presence of varying amounts of impurities have no detrimental effect on, and in some cases even improve, the overall performance o~ the salicylates of 13~1S~
this invention as color developers, as can be demonstrated by the results presented in Table II. To have a proper comparison, the ratios of all the components such as salicylate to pigment, pigment to 5 binder, etc., were kept constant; only the amount of the impurities was varied. All intensity measurements were made using the same, commercially available capsule-coated CB (Coated Back) paper. Strips of CB
paper were mated with CF paper, a constant pressure was 10 applied to crush the microcapsules of the CB paper and produce the colored images on the CF surface. The instrument used to make the intensity measurements was a Brightimeter Micro S4-M Brightness, Opacity, and Color Tester. The L value on the ~unter L,a,b scale 15 which the Brightimeter calculates was taken as a measure of the color intensity of the images. Since lower L values on the 0-100 scale mean higher image intensities, the Intensity values ~I) presented in Tables I and II were calculated as 100-L.
To measure light resistance, the colored images were exposed for twenty hours to a General ~lectric cool white fluorescent bulb at a distance of six inches and the intensity of the image was compared before and after exposure. The % light resistance was calculated from the following formula:
13~;tS;~
Light Resistance = (I ~efore ~ ter) x 100 I Before The invention will be further described in connec-tion with the following examples and tables which are set forth for purposes of illustration only.
Thirty-five grams of xylener 20.6 grams (0.1 mole) of p-octyl phenol, and 12.5 grams of a 45% aqueous solution of potassium hydroxide are charged into a suitable reactor equipped with a turbine-type agita-tor. The reaction mixture is heated to reflux, separating the water into a Dean-Starke trap; heating is continued until the mixture is dehydrated and the theoretical amount of water (8.7 g) has been collected.
The reaction mixture is cooled to 120C under a nitro-gen atmosphere, and 7.3 grams (0.1 mole) of dimethyl formamide are added; while maintaining the agitation and the temperature to between 125-130C, 4.5 grams of carbon dioxide are added to the mixture through a sub-surface gas inlet tube for approximately 30 to 60 minu-tes. The solution temperature of 125-130C is maintained for about one additional hour after the addition of the carbon dioxide has been completed. The reaction mixture is then cooled to about 90C, 68-70 grams of water are added with thorough mixing for about ~3U5~
15 to 20 minutes, the mixing is stopped and the phase separation is allowed to occur. The lower layer ~water phase) containing the potassium salt octyl salicylic acid product (about 20~ by weight) as well as the 5 impurities; primarily octyl phenol, xylene, dimethyl formamide, and potassium bicarbonate, is drained off into a suitable vessel equipped with an agitator, and the pH is raised to between 12 and 13 with an aqueous solution of concentrated ammonia. Fourteen grams of a 10 50% by weight aqueous solution of zinc chloride are added slowly and with agitation forming a precipitate;
this precipitate remains stable over an indefinite period of time and over a wide range of temperatures.
The coating can be prepared by applying the crude 15 solution containing the flocculant precipitate directly to a paper substrate at very low coating weights of about 1.5 to 2.2 g/m2, after mixing with small amounts (10% to 15~ by weight on a dry basis) of one or more binders such ethylated or oxidized starches, and/or 20 small amounts (10% to 15% by weight) of a styrene-butadiene latex (Dow's latex-638), producing a receptor or color developer coated front (CF) part of a car-bonless paper product. When the CF surface is mated with a coated back (CB) part of a carbonless form con-25 taining leuco dyes (usually in an encapsulated form) 13~
and localized pressure is applied, bright and intenseimages are formed instantaneously on the CF surface.
Alternatively, the solution containing the floc-culant precipitate is formulated into a coating by the 5 addition of 200 grams of calcium carbonate, 130 grams of a 20~ aqueous solution of ethylated starch, and 30 grams of Dow's latex-~38 ~48% by weight aqueous solu-tion) and applied to a paper substrate at low coating weights (2 to 3 g/m2). Images of the same high inten-10 sity, speed and brightness as those obtained from thenonpigmented formulation are obtained.
COMPARATIVE EXAMPLE la Twenty-five grams of pure, conventionally produced octyl salicylic acid are dissolved in 100 grams of 15 water with the aid of 12.5 grams of a 45~ aqueous solu-tion of potassium hydroxide. The pH of the solution is raised to between 12 and 13 using a concentrated solu-tion of aqueous ammonia, mixed with 14 grams of a 50~
aqueous solution of zinc chloride and formulated into 20 coatings (with and without pigments) as described in Example 1 above. The properties of the images formed on the CF paper of this example are identical to the properties of the images produced on the CF of Example 1.
13~5~i _XAMPLE 2 Example 1 is repeated, but the aqueous layer con-taining the octyl salicylic acid is drained off into a suitable vessel equipped with an agitator, 4 grams of 5 an aqueous (37% by weight) formaldehyde solution are added and the reaction mixture is heated to between 85 and 90C and maintained at this temperature for 2 to 4 hours while maintaining the pH at between 8.5 and 9.
At the end of this reaction, almost all of the for-10 maldehyde has been consumed, and oligomers of the octylsalicylate have been formed. The crude oligomeric octyl salicylate reaction mass is treated in a similar manner to that described in Example l; i.e., the pH is raised to between 12 and 13 with concentrated aqueous 15 ammonia, and the zinc chloride solution is added to form the flocculant precipitate. 5ubsequently, the solution containing the flocculant precipitate is for-mulated into the coatings described in Example 1 and applied to a paper substrate in equivalent coating 20 weights. The images produced on such CF surfaces possess properties similar to the images produced in Example 1, but in addition they exhibit improved sta-bility to severe light exposures.
Example 1 is repeated, but the p-octyl phenol is 13~:i;3~
replaced with equimolar quantities of p-tert.butyl phenol. Equivalent results are obtained.
Example 2 is repeated, but the water layer contains 5 the p-tert.butyl salicylate produced in Example 3. The CF papers produced using the methods described in Example 1 exhibit equivalent properties.
Example 1 is repeated, but the p-octyl phenol is 10 replaced with equimolar quantities of 2,4, ditertiary butyl phenol. The resultant material, 3,5, ditertiary butyl salicylate, and/or its metal salts, when used as the color developer in a CF coating exhibit properties equivalent to those obtained with the octyl salicylate-15 containing CF.
Example 1 is repeated up to the point of drainingoff the lower layer (water phase) containing the potassium salt of the salicylic acid product, except 20 that the p-octyl phenol is replaced with equimolar quantities of phenol. The resultant salicylic acid salt contained in the water layer is reacted with 16 grams of aqueous formaldehyde solution ~37% by weight) in the presence of 25 grams of 12N sulfuric acid solution at a temperature of 95 to 97C for one hour to 13(~5~1 produce d high molecular weight polymer of salicylic acid. The alkaline salt of this material was treated in a manner si~lilar to that described in Example 1 to form the flocculant precipitate, and formulated into 5 coatin~s according to the methods described in Example 1. The CF papers produced containing the material of this example exhibited properties similar to those of the CF produced in Example 1, but the images required substantially higher amount of time to develop full 10 intensities.
Example 1 i5 repeated throughout, but the p-octyl phenol is replaced with equimolar quantities of 2-methyl, 3-isobutylthiophenol. The resultant product, 15 2-hydroxy-4-methyl-5-isobutylthiobenzoic acid and/or its metal salts, when used as the color developer in a CF coating exhibit properties equivalent to those obtained with the CF containing the octyl salicylate product.
Example 1 is repeated in its entirety, but the p-octyl phenol is replaced with equimolar quantities of p-t-butylthiophenol. The resultant product, 2-hy-droxy-5-t-butylthiobenzoic acid and/or its metal 25 salts, when used as the color developer in a CF
~31~S~
coating, exhibit properties equivalent to those obtained with the CF containing the octyl salicylate product.
EXAMPL~ 9 Twenty grams of an impure mixture of m-nonyl sali-cylic acid and nonyl phenol containing about 11 grams (55% o~ total mixture weight) of nonyl phenol and about 1-1.5 grams of potassium carbonate and xylene, are dissolved in 100 grams of water containing 1.5 dry 10 grams of sodium hydroxide. While maintaining the solution under agitation, 5.8 grams of 50% by weight of an aqueous solution of zinc chloride are added and allowed to react, forming the zinc salt of the nonyl salicylic acid. Subsequently, 100 grams of a 72~
15 by weight dispersion of calcium carbonate in water are added along with 17 grams of Dow's latex-620 (50~ by weight) and 42 grams of a 20% by weight aqueous solution of ethylated starch, the pH of the dispersion is adjusted to about 9.5 with concentrated aqueous 20 ammonium hydroxide solution (28% by weight), and the final coating is applied to a paper substrate at coating weights of between 3 and 5 g/m2, producing a receptor or color developer coated front (CF) part of a carbonless product. When the CF surface is mated with 25 a coated back (CB) of a carbonless form containing ~3(~
leuco dyes (usually in an encapsulated form) and localized pressure is applied, bright and intense images are formed instantaneously on the CF surface.
The process of Example 9 is repeated except that 1 gram of lithium hydroxide is substituted for the 1.5 grams of sodium hydroxide used therein and no zinc chloride is added. Equivalent results are obtained.
Twenty grams of an impure mixture of m-nonyl salicylic acid and nonyl phenol containing about 50% by weight nonyl salicylic acid, about 43-45% by weight nonyl phenol, and about 5-7% by weight of potassium carbonate and xylene, are dissolved in 90 grams of water 15 containing 0.5 dry gram of sodium hydroxide, and 10 grams of concentrated aqueous ammonium hydroxide.
While maintaining the solution under agitation, 15 grams of zinc oxide are thoroughly dispersed therein.
Subsequently, 213 grams of a 72% by weight dispersion 20 of calcium carbonate and kaolin clays in water are added along with 36 grams of Dow's latex-620 (50%
solids by weight) and 92 grams of a 20~ by weight aqueous solution of ethylated starch. The pH of the dispersion is adjusted to about 11 with a concentrated 25 aqueous ammonium hydroxide solution ~28% by weight), 13(~5~
and applled onto a paper substrate at a coating weight of between 5 and 7 g/m2 producing a receptor or color developer coated front (CF) part of a carbonless product. When the CF surface is mated with a coated S back (CB) of a carbonless form containing encapsulated leuco dye and localized pressure is applied, bright and intense images are formed instantaneously on the CF
surface.
The process of Example 9 is repeated except that the amount of zinc chloride solution is reduced to 4 grams. Equivalent results are obtained.
~he process of Example 11 is repeated except that 15 the amount of zinc oxide is reduced to 4 grams.
Equivalent results are obtained.
The process of Example 9 is repeated except that the zinc chloride is replaced with 15 grams of an 18%
20 by weight solution of zinc octoate in mineral spirits.
Equivalent results are obtained.
The process of Example 11 is repeated except that the 213 grams of the calcium carbonate and kaolin clays 25 dispersion are replaced with 213 grams of a 72~ by 13(~S3~i weight dispersion of kaolin clays in water. Equivalent results are obtained.
The process of Example 11 is repeated except that 5 the 213 grams of the calcium carbonate and kaolin clays dispersion are replaced with 213 grams of a 72% by weight dispersion of a 50-50 mixture of calcium carbonate and kaolin clays. Equivalent results are obtained.
The process of Example 9 is repeated except that the zinc chloride is replaced with 8 grams of a 12~ by weight hydrochloric acid solution. Equivalent results are obtained.
Examples 9 through 1~ are repeated except that the 20 grams of the impure mixture of nonyl salicylic acid are replaced with 13.5 grams of an impure mixture containing about 75% by weight nonyl salicylic acid, 20 about 20 to 22% by weight of nonyl phenol, and about 3 to 5% by weight potassium carbonate and xylene.
Equivalent results are obtained in all cases.
The processes of Examples 9 and 11 are repeated 25 except that the 20 grams of impure nonyl salicylic acid 13(~5~1 mixture are replaced with 10 grams of pure nonyl salicylic acid. Comparable results are obtained.
A self-contained carbonless system is prepared by 5 the following procedure:
Microcapsules containing leuco color formers are manufactured according to the specifications of U.S.
Patent No. 4,586,060, as follows:
An oiL solution comprising 90 grams of 10 monoisopropylbiphenolr 3 grams of Hilton Davis' ~-102 black leuco dye, 1 gram of Crystal Violet Lactone, 0.5 --gram of benzoyl leuco methylene blue, 0.4 gram of Hilton Davis' Kopichem XIV leuco dye, and 5 grams of a hexamethylene di-isocyanate adduct (Mobay's Desmondur 15 L-2291A) are emulsified with 100 grams of a 13% by weight aqueous solution of gelatin (Hudson Industries G-llO). Emulsification is continued until an average particle size of between 5 and 5.5 microns are obtained and the solution is heated to 65C for about two hours.
20 Subsequently, 10 grams of a 10% by weight polyvinyl alcohol (Airco's Vinol-205), 1 gram of toluene, and 1 gram of Desmondure L-2291A are added with agitation and the heating is continued at 65C for an additional two hours. The microcapsular dispersion is cooled to room 25 temperature and mixed with 35 grams of load-bearing *Trade mark ~1''~' ~3US3~1 material such as Henkel's Keestar-328, a granular, `~
uncooked starch, and lO0 grams of a 20% by weight aqueous solution of ethylated starch. The solids of the microcapsular dispersion are adjusted with water to 5 between 35 and 40% by weight.
Two hundred grams of a color developer CF coating prepared according to the procedure of Example ll are thoroughly mixed with 75 grams of the microcapsular dispersion of this Example, coated onto a paper lO substrate at a coating weight of about 6.5 gms/m2, and dried. When pressure is applied to the coated surface, the microcapsules are ruptured, releasing the oily material containing the leuco color developers and forming an in-situ black image of high intensity and 15 excellent light stability.
Examples l and 2 are repeated except that the pH is raised to only about ll to 12. Comparable results are obtained.
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Claims (25)
1. A pressure-sensitive chromogenic copy system comprising a transfer sheet having on at least a por-tion of at least one surface thereof a coating of a color developer capable of reacting with a chromogen to form a color image, said color developer comprising a crude reaction medium resulting from reactants used to prepare a salicylate and also containing therein at least one metal compound of such salicylate.
2. The pressure-sensitive chromogenic copy system of Claim 1 wherein the metallic compound is a hydrogen-donating compound or lithium or a Group IIIA through IVB of the Periodic Table polyvalent metal compound of salicylic acid or C1 to C20 alkyl or aryl salicylic acid.
3. The pressure-sensitive chromogenic copy system of Claim 2 wherein the metallic compound is a hydrogen-donating compound or lithium or polyvalent metal compound of octyl salicylic acid or nonyl salicylic acid.
4. The pressure-sensitive chromogenic copy system of Claims 1, 2, or 3 wherein the color developer con-tains at least about 1% by weight of salicylate.
5. The pressure-sensitive chromogenic copy system of Claim 1, 2, or 3 wherein the pH of said coating is between about 5 and 8.
6. A transfer sheet for a pressure-sensitive chromogenic copy system comprising a substrate having on at least a portion of one surface thereof a coating of a color developer capable of reacting with a chromogen to form a color image, said color developer comprising a crude reaction medium resulting from reactants used to prepare a salicylate and also containing therein at least one metal compound of such salicylate.
7. The transfer sheet of Claim 6 wherein the metallic compound is a hydrogen-donating compound or lithium or Group IIIA through IVB polyvalent metal compound of the Periodic Table of salicylic acid or C1 to C20 alkyl or aryl salicylic acid.
8. The transfer sheet of Claim 7 wherein the metallic compound is a polyvalent metal compound of octyl salicylic acid or nonyl salicylic acid.
9. The transfer sheet of Claim 6, 7, or 8 wherein the color developer contains at least about 1% by weight of salicylate.
10. The transfer sheet of Claim 6, 7, or 8 wherein the pH of said coating is between about 5 and 8.
11. A color developer for use in a pressure-sensitive chromogenic copy system comprising a crude reaction medium resulting from reactants used to prepare a salicylate and also containing therein at least one metal compound of such salicylate.
12. The color developer of Claim 11 wherein the metallic compound is a hydrogen-donating compound or lithium or Group IIIA through IVB of the Periodic Table polyvalent metal compound of salicylic acid or C1 to C20 alkyl or aryl salicylic acid.
13. The color developer of Claim 12 wherein the metallic compound is a hydrogen-donating compound or lithium or polyvalent metal compound of octyl salicylic acid or nonyl salicylic acid.
14. The color developer of Claim 13 wherein the color developer contains at least about 1% by weight of salicylate.
15. The color developer of Claim 14 wherein the color developer also contains a pigment and a binder.
16. The color developer of Claim 11, 12, 13, 14, or 15 wherein said crude reaction medium contains at least about 5% by weight of said salicylate.
17. A process for the manufacture of a color deve-loper for use in a pressure-sensitive chromogenic copy system comprising carrying out a reaction with reac-tants capable of forming a salicylic compound to form a crude reaction medium containing said salicylic com-pound, forming at least one metal compound of said salicylic compound, and then admixing said crude reac-tion medium with an effective amount of a binder to form said color developer.
18. The process of Claim 17 wherein the metallic compound is a hydrogen-donating compound or lithium or Group IIIA through IVB of the Periodic Table polyvalent metal compound of salicylic acid or C1 to C20 alkyl or aryl salicylic acid.
19. The process of Claim 18 wherein the metallic compound is a hydrogen-donating compound or lithium or polyvalent metal compound of octyl salicylic acid or nonyl salicylic acid.
20. The process of Claim 19 wherein the color developer contains at least about 1% by weight of sali-cylate.
21. The process of Claim 17, 18, 19, or 20 wherein the metallic compound added to form the metal compound of said salicylic compound is zinc oxide or zinc chloride.
22. The process of Claim 17, 18, 19, or 20 wherein a pigment is also admixed with said crude reaction medium and said binder in an amount effective to extend the coating surface of said color developer.
23. The process of Claim 17, 18, 19, or 20 wherein the pH of said color developer is adjusted such that a dried coating thereof has a pH of about 5 to 8.
24. A self-contained pressure-sensitive chromogenic copy system comprising at least one sheet having on at least a portion of at least one surface thereon a coating of a color developer of Claim 11, 12, 13, or 14 and a chromogen.
25. A self-contained pressure-sensitive chromogenic copy system comprising at least one sheet having on at least a portion of at least one surface thereon a coating of a color developer of Claim 11, 12, 13 or 14 and a chromogen wherein said color developer and said chromogen are in the same coating.
Applications Claiming Priority (6)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US7632687A | 1987-07-22 | 1987-07-22 | |
US076,326 | 1987-07-22 | ||
US10159387A | 1987-09-28 | 1987-09-28 | |
US101,593 | 1987-09-28 | ||
USPCT/US88/02366 | 1988-07-19 | ||
PCT/US1988/002366 WO1989000506A1 (en) | 1987-07-22 | 1988-07-19 | Chromogenic copy system and methods |
Publications (1)
Publication Number | Publication Date |
---|---|
CA1305321C true CA1305321C (en) | 1992-07-21 |
Family
ID=26757970
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA000572860A Expired - Lifetime CA1305321C (en) | 1987-07-22 | 1988-07-22 | Chromogenic copy systems and methods |
Country Status (10)
Country | Link |
---|---|
EP (1) | EP0330685B1 (en) |
JP (1) | JPH02500428A (en) |
AT (1) | ATE76816T1 (en) |
AU (1) | AU608651B2 (en) |
BR (1) | BR8807134A (en) |
CA (1) | CA1305321C (en) |
DE (1) | DE3871771T2 (en) |
DK (1) | DK147489D0 (en) |
FI (1) | FI884964A (en) |
WO (1) | WO1989000506A1 (en) |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP3107173B2 (en) * | 1991-12-27 | 2000-11-06 | 株式会社三光開発科学研究所 | Process for producing nuclear-substituted salicylic acid metal salt |
US5807933A (en) * | 1992-06-22 | 1998-09-15 | The Mead Corporation | Carboxyl-containing phenolic resin developer and method of preparation |
AU703239B3 (en) * | 1998-10-22 | 1999-03-18 | Ezee Whip Dispensing Systems Limited | Frozen dessert dispensing system |
Family Cites Families (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3934070A (en) * | 1970-10-23 | 1976-01-20 | Fuji Photo Film Co., Ltd. | Recording sheet and color developer therefor |
JPS54120010A (en) * | 1978-03-06 | 1979-09-18 | Fuji Photo Film Co Ltd | Developer and developing sheet for pressureesensitive recording |
JPS61149390A (en) * | 1984-12-25 | 1986-07-08 | Mitsubishi Paper Mills Ltd | Color develop sheet for pressure-sensitive recording |
JPH0623132B2 (en) * | 1985-10-07 | 1994-03-30 | 富士写真フイルム株式会社 | Method for producing alkoxysalicylic acid derivative |
-
1988
- 1988-07-19 DE DE8888906823T patent/DE3871771T2/en not_active Expired - Lifetime
- 1988-07-19 AU AU22622/88A patent/AU608651B2/en not_active Ceased
- 1988-07-19 WO PCT/US1988/002366 patent/WO1989000506A1/en not_active Application Discontinuation
- 1988-07-19 AT AT88906823T patent/ATE76816T1/en not_active IP Right Cessation
- 1988-07-19 BR BR888807134A patent/BR8807134A/en not_active Application Discontinuation
- 1988-07-19 JP JP63506830A patent/JPH02500428A/en active Pending
- 1988-07-19 EP EP88906823A patent/EP0330685B1/en not_active Expired
- 1988-07-22 CA CA000572860A patent/CA1305321C/en not_active Expired - Lifetime
- 1988-10-27 FI FI884964A patent/FI884964A/en not_active IP Right Cessation
-
1989
- 1989-03-22 DK DK147489A patent/DK147489D0/en not_active Application Discontinuation
Also Published As
Publication number | Publication date |
---|---|
DE3871771T2 (en) | 1992-12-10 |
WO1989000506A1 (en) | 1989-01-26 |
JPH02500428A (en) | 1990-02-15 |
BR8807134A (en) | 1989-10-17 |
EP0330685B1 (en) | 1992-06-03 |
ATE76816T1 (en) | 1992-06-15 |
DE3871771D1 (en) | 1992-07-09 |
EP0330685A1 (en) | 1989-09-06 |
FI884964A0 (en) | 1988-10-27 |
DK147489A (en) | 1989-03-22 |
DK147489D0 (en) | 1989-03-22 |
EP0330685A4 (en) | 1989-08-09 |
AU2262288A (en) | 1989-02-13 |
AU608651B2 (en) | 1991-04-11 |
FI884964A (en) | 1989-01-23 |
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MKLA | Lapsed |