EP0121916A2 - Ink jet recording sheet - Google Patents

Abstract

A recording paper for ink-jet recording processes is described which consists of a carrier with a specific degree of sizing and a coating arranged thereon, which contains a fine, special silicon dioxide and a water-soluble, polymeric binder. The paper according to the invention is better suited for fast recording.

Description

The invention relates to a coated recording paper for ink jet recorders or for the ink jet recording method, which for recording is suitable at high speed. The ink spray recording method has the advantage that it is quiet and multi-color records can be easily made. It is used in facsimile machines and for various printers.

In general, the recording papers for ink-jet recording processes are divided into conventional and coated recording papers. The conventional recording papers with a low degree of sizing have good ink absorbency; however, the clarity of the recording suffers from the diffusion of the ink in the sheet layer, in particular the image resolution and color density are unsatisfactory in the case of multicolor recordings. Therefore, investigations were carried out with coated recording papers with superior image resolution. The coated recording papers provide superior image density and clarity because the dye of the ink in the coating is locally absorbed and does not bleed. However, such recording papers have the disadvantage that they are not so suitable for rapid recording because of their insufficient ink absorption capacity.

As the rapid processing of information evolves, the rapid recording by the ink jet recording method has to be improved, as in other recording methods such as screen dot recording, electrostatic recording, heat sensitive recording, etc. As a recording device, there is a faster one Multi-nozzle type printer using a foam jet system has already been developed. From the record The coated recording paper, which has a superior image resolution, has the disadvantage that the ink papers for ink-jet recording processes have the disadvantage that the dry state of the ink is unstable because the ink drops ejected from the nozzles after being adhered to the surface of the recording paper are absorbed inside and only seemingly are available in a dry state. There are therefore various problems in fast recording, such as the contact of papers with each other after recording, the transfer and scratching of the ink during transportation by the roller of the recording apparatus, etc., which are not found in other recording methods.

The invention is based on the object of providing a coated recording paper for ink jet recorders or for ink spray recording processes which is better suited for rapid recording.

This object is achieved in that a support with a degree of sizing according to Stöckigt of less than 4 seconds (based on a weight per unit area of 60 g / m ² ) is used and this is provided with a coating which has fine silicon dioxide with a specific surface area of at least 200 m ² / g, determined by the BET method, and with a uniformity n of the Rosin-Rammler distribution of at least 1.10 and contains a water-soluble, polymeric binder.

Fine pigment with a specific surface area of at least 200 m ² / g, determined by the BET method, and with a uniformity number n of the Rosin-Rammler distribution of at least 1.10 is used as the pigment according to the invention in the coating composition. The use of a pigment based on silicon dioxide as a coating material for the surface of the ink spray paper is described in JA-OS 51583/1980. However, the silicon dioxide described there has different properties and is of a different nature. The fine silica selected in accordance with the invention results in a recording paper which is superior in color density, hue, clarity and suitability for rapid recording.

The first requirement of the silicon dioxide according to the invention is that it has a specific surface area of at least 200 m ² / g. A coating that contains silicon dioxide with a large specific surface area as the main component results in superior color density and clarity.

The silicon dioxide according to the invention must meet the second condition that it has a uniformity n of the Rosin-Rammler distribution of at least 1.10. Such a large uniformity number n means a narrow particle distribution. A silica with a large specific surface area and a narrow particle distribution results in a particularly superior ink absorption capacity. Surprisingly, the right choice of silicon dioxide gives a coating that is particularly suitable for rapid recording. Generally the coating has the structure of a dense layer of pigment and binder. It was not believed, therefore, that the superior absorbency that conventional ink jet recording papers have can be achieved with a coated paper.

The mechanism of the coating's improved ink absorbency through the choice of silica is unclear. However, it is believed that the larger number of uniform gaps of a certain size suitable for superior ink absorbency produce the beneficial effect, which is particularly pronounced with a silica having a large specific surface area.

In connection with the ink absorption capacity of the coating indicated above, a paper with a Stöckigt glue strength of less than 4 seconds (based on a basis weight of 60 g / m ² ) is used according to the invention. A Stöckigt sizing degree of less than 4 seconds (based on a basis weight of 60 gfm ² ) means that the ratio of Stöckigt sizing degree / basis weight [(second) / (g / m ² )] is less than 0.07. That is, the ink component that flows through the coating easily penetrates into the carrier and is absorbed by it because the carrier has no or only a small degree of sizing. In addition, rapid impregnation with the water-soluble binder in the coating process increases the gaps in the coating itself, causing an increase in the ink absorbency of the coating. Therefore, the commercially available premium paper cannot be used according to the invention because it has a high degree of sizing.

The uniformity number n of the Rosin-Rammler distribution is determined as follows: silicon dioxide pigment is dispersed in water; an integrated measure R (Dp) of particles with a particle size Dp is determined with the aid of a conventional device (for example a device which measures the turbidity or light scattering) in order to determine the particle size distribution in a particle size range from 0.4 to 10 _/ μm. If the values obtained in the Rosin-Rammler diagram (hereinafter referred to as RR diagram) are based on the Rosin-Rammler equation R (Dp) = 100 x exp. (-bDp ⁿ ) (where b and n are each a constant and n is called a uniformity number or a distribution constant), a straight line can be obtained. Then you draw a line parallel to this line through a point P in the RR diagram and read the exponent n on the exposed line. This way you can easily get n. The effect according to the invention can also be achieved if the measured value of the particle size distribution, which is determined by the above method, is approximately regarded as a straight line.

The commercially available silica pigments that meet the above two conditions are, for example, SILCRON G100, SILCRON 600 (manufactured by Nissan Chemical Industries, Ltd.), SYLOID 404, SYLOID 79, SYLOID 74 (manufactured by Fuji-Davison Chemical Ltd. ), GASIL HP-34 (manufactured by Joseph Crossfield & Sons, Ltd.), Finesil X27, Finesil X37, Finesil 79 (manufactured by Tokuyama Soda Co., Ltd.), CARPLEX No.80 (manufactured by Shionogi & Co., Ltd.) etc.

A water-soluble polymeric binder is suitable as the binder which is used in combination with the above-mentioned silicon dioxide pigments. Polyvinyl alcohol and its derivatives are particularly desirable in terms of color density, but one can also use oxidized starch, modified starch, rubber compounds, e.g. Guar gum and the like, sodium alginate, water-soluble cellulose derivatives, e.g. Hydroxyethyl cellulose, methyl cellulose, carboxymethyl cellulose etc., water soluble proteins e.g. Soybean protein, casein and the like, water soluble polymeric compounds e.g. Polyvinyl pyrrolidone and the like.

A fairly large amount of pigment according to the invention is preferably used in the preparation of the coating composition, i.e. a weight ratio (expressed as a solid weight) of silicon dioxide according to the invention to water-soluble polymeric binder of about 60-95: 40-5. The silicon dioxide according to the invention can optionally be used together with other pigments, e.g. Kaolin, talc, calcium carbonate, magnesium carbonate, barium sulfate, titanium white, organic fillers and the like can be used.

The coating can be carried out using customary application devices, for example doctor blade spreaders, air brush spreaders, bar spreaders, roller spreaders and the like, or size presses. The coating amount is preferably 3 to 15 g / m ² on one surface of the support; too much coating leads to poor ink absorbency.

The invention is explained in more detail using the following examples. As an abbreviation for "part by weight" "Gewt" is used here.

To test the quality of the recording papers of the present invention, the ink spray recording was made with a Panafax 6000 (manufactured by Matsushita Graphic Communication Systems, Inc.). A two-nozzle ink jet recording device was used to produce two-color printing with black and red inks. The red ink was ejected for 10 seconds, then both red and black ink were ejected for 5 seconds, and finally a black ink was ejected for 10 seconds. The respective recording width of the red and black ink was 24 mm and the overlapping recording width of red and black ink in the central area was 8 mm. The reflection density of the recording surface was measured with a Macbeth density meter, the reflection density of the red recording surface using green filter for the magenta color and of blue filter for the yellow color and the reflection density of the black recording surface using visual filter for the black color (all filters are SPI filters). The reflection density (the sum) in the table was expressed as the sum of the individual reflection densities. The ink absorption time of a recording paper was determined by dropping 0.0018 cm ^{3 of} cyan ink (manufactured by Matsushita-Giken) at 20 ° C and 65% RH using 1 micron micro-injectors onto the surface of a paper and determining the absorption time of the ink .

example 1

• 85 Gewt (als Feststoffgehalt) jeweils des Siliciumdioxids I (Silcron G100, hergestellt von Nissan Chemical Industries, Ltd.), des Siliciumdioxids II (Finesil X27, hergestellt von Tokuyama Soda Co., Ltd.) und des Siliciumdioxids III (Syloid Nr.74, hergestellt von Fuji-Davison Chemical Ltd.) als erfindungsgemäße Beispiele und des Siliciumdioxids IV (Carplex FPS-1, hergestellt von Shionogi & Co., Ltd.), des Siliciumdioxids V (Carplex FPS-3, hergestellt von Shionogi & Co., Ltd.), des Siliciumdioxids VI (Carplex Nr.1120, hergestellt von Shionogi & Co., Ltd.), des Siliciumdioxids VII (Nipsil E 200 A, hergestellt von Nippon Silica Industrial Corporation), des Siliciumdioxids VIII (Nipsil E 220 A, hergestellt von Nippon Silica Industrial Corp.) und des Siliciumdioxids IX (Mizukasil P526, hergestellt von Mizusawa Industrial Chemicals, Ltd.) als Vergleichsversuche,wurden zu 15 Gewt. (Feststoffgehalt) einer 15%igen wäßrigen Lösung von Polyvinylalkohol (Verseifungsgrad: 100%, PVA 117, hergestellt von Kuraray Co., Ltd.) gegeben. Die erhaltenen Beschichtungsmassen wurden in einer Beschichtungsmenge von 9 bis 12 g/m² auf ein höherwertiges Papier mit einem Stöckigt-Leimungsgrad von 3,6 Sekunden und einem Flächengewicht von 63 g/m² aufgetragen, wodurch die Aufzeichnungspapiere Nr. 1 bis 9 erhalten wurden. Die Tintenabsorptionsfähigkeit und die Prüfungsergebnisse dieser Aufzeichnungspapiere sind in Tabelle 1 zusammengefaßt.
  

The following nine coating compositions were produced:

• 85% by weight (as a solid content) of each of the silica I (Silcron G100, manufactured by Nissan Chemical Industries, Ltd.), the silica II (Finesil X27, manufactured by Tokuyama Soda Co., Ltd.) and the silica III (Syloid No. 74 , manufactured by Fuji-Davison Chemical Ltd.) as examples of the present invention, and the silica IV (Carplex FPS-1 manufactured by Shionogi & Co., Ltd.), the silica V (Carplex FPS-3 manufactured by Shionogi & Co., Ltd.), the silica VI (Carplex No. 1120, manufactured by Shionogi & Co., Ltd.), the silica VII (Nipsil E 200 A, manufactured by Nippon Silica Industrial Corporation), the silica VIII (Nipsil E 220 A, manufactured by Nippon Silica Industrial Corp.) and silica IX (Mizukasil P526, manufactured by Mizusawa Industrial Chemicals, Ltd.) as comparative experiments, were made up to 15 wt. (Solids content) of a 15% aqueous solution of polyvinyl alcohol (degree of saponification: 100%, PVA 117, manufactured by Kuraray Co., Ltd.). The coating compositions obtained were applied in a coating amount of 9 to 12 g / m ² onto a higher-quality paper with a Stöckigt sizing degree of 3.6 seconds and a basis weight of 63 g / m ² , whereby the recording papers Nos. 1 to 9 were obtained . The ink absorbency and test results of these recording papers are summarized in Table 1.
  

As can be seen from Table 1, the ink absorption speeds of the recording papers Nos. 1 to 3 are less than 30 seconds; so they are very fast, and their reflection densities are superior. On the other hand, the comparative tests (recording papers Nos. 4, 5 and 8), which have a uniformity number of less than 1.10, have a much lower ink absorption rate, and the other comparative tests (recording papers Nos. 6, 7 and 9), which have a BET specific surface area of less than 200 m ² / g, have inferior reflection densities.

Example 2

80 wt. (as a solid content) of a silica slurry (Gasil HP-34, manufactured by Joseph Crossfield & Sons, Ltd.) was added to 20 wt. (as a solid content) of a 15% aqueous solution of polyvinyl alcohol (degree of saponification: 100%, PVA 117, manufactured by Kuraray Co., Ltd.) to prepare a coating composition. The coating composition obtained was applied to three higher-quality papers with different degrees of sizing in an amount of 6 to 8 g / m ² to produce three recording papers.

Wie aus Tabelle 2 ersichtlich ist, weisen die mit dem erfindungsgemäßen Siliciumdioxid beschichteten Aufzeichnungspapiere (Nr. 11, 12 und 13), unabhängig von der Art der Rohpapiertypen, eine überlegene Reflexionsdichte auf. Aber die Tintenabsorptionsgeschwindigkeit ist von dem Leimungsgrad des Rohpapiers abhängig, und bei einem Leimungsgrad von mehr als 4 Sekunden (bezogen auf ein Flächengewicht von 60 g/m²) funktioniert die Beschichtung aus Siliciumdioxid ungenügend.The test results of the recording papers and the base paper obtained are summarized in Table 2.

As can be seen from Table 2, the recording papers coated with the silicon dioxide according to the invention (No. 11, 12 and 13), regardless of the type of base paper types, have a superior reflection density. But the ink absorption rate depends on the degree of sizing of the base paper, and with a degree of sizing of more than 4 seconds (based on a basis weight of 60 g / m ² ) the coating of silicon dioxide works insufficiently.

Claims (5)

1. Recording paper for ink-jet recording processes, consisting of a support and at least one coating arranged thereon, characterized in that the support has a Stöckigt sizing degree of less than 4 seconds (based on a basis weight of 60 g / m ² ) and the coating is fine silicon dioxide with a specific surface area of at least 200 m ² / g, determined by the BET method, and with a uniformity number n of the Rosin-Rammler distribution of at least 1.10 and containing a water-soluble, polymeric binder. 2. Recording paper according to claim 1, characterized in that the water-soluble, polymeric binder is at least polyvinyl alcohol and / or a polyvinyl alcohol derivative. 3. Recording paper according to claim 1 or 2, characterized in that the weight ratio of silicon dioxide to water-soluble, polymeric binder is 60-95: 40-5. 4. Recording paper according to one of claims 1 to 3, characterized in that the coating amount is in the range of 3 to 15 g / m ² on a surface of the support. 5. Use of fine silicon dioxide with a specific surface area of at least 200 m ² / g, be voted according to the BET method, and with a uniformity n of the Rosin-Rammler distribution of at least 1.10 and a water-soluble, polymeric binder in the coating on the support, which has a Stöckigt sizing degree of less than 4 seconds (based on a Basis weight of 60 g / m ² ), for the improvement of recording paper for ink-jet recording processes.