The present invention relates generally to ink-jet recording methods according to which ink is ejected to perform recording on a recording medium and recording media used in the ink-jet recording methods, and more particularly to an ink-jet recording method and an ink-jet recording medium suitable therefor, according to which method a bias is applied to an endless conveyor belt to convey a recording medium to a predetermined position by an electrostatic attraction force, and ink (recording liquid) is ejected from a recording part (recording head) to the recording medium so that recording is performed thereon.
Ink-jet recording, according to which ink is ejected from a recording head to a recording medium (a material on which recording is performed) so as to perform recording thereon, can achieve high-speed recording of a high-definition image. Accordingly, ink-jet recording is employed in facsimile machines, copiers, and printers.
In ink-jet recording, the pursuit of higher image quality requires ink droplets to be ejected onto a recording medium with higher positional accuracy, which also requires accuracy of conveyance of the recording medium. According to an ink-jet recording serial printer, a recording medium is stopped during scanning by a head. The feeding of the recording medium is by repetition of movement and stoppage of the recording medium. The feeding accuracy of the recording medium conveyance is the accuracy of a position at which the recording medium is stopped after being fed by a predetermined amount.
In the case of forming an image on a recording medium by ink-jet recording, if the recording medium is paper such as coated paper having an ink absorbing layer formed on plain paper or a paper base, the paper is caused to stretch by moisture included in ink. This phenomenon is called cockling. This cockling causes the paper to undulate, so that the distance between the nozzles of a recording head and the surface of the paper differs by positions on the paper. If cockling worsens, in the worst case, the paper may come into contact with the nozzle face of the recording head so that not only the nozzle face but also the paper itself is contaminated. Further, cockling may cause ink droplets to be ejected onto wrong (offset) positions.
Therefore, according to the conventional ink-jet recording, printing is performed on a platen provided with a recess absorbing the cockling of paper, and a spur is provided to hold the paper. Here, the spur is a gear-like part, having projections formed circumferentially on its outer surface. The spur helps to convey the paper with the small area of one or more of the projections. However, scratches made on an image by the spur cause a problem in some cases.
Further, according to the conventional ink-jet recording, paper is fed by rollers. Two pairs of rollers, one of the above-described spur and a roller and the other of a conveying roller and a driven roller, are provided to sandwich a printing region. According to this configuration, paper feeding accuracy can be guaranteed only when the two pairs of rollers are biting (engaging) the paper.
In these days, there is a demand for enlarging an image printing region. In order to ensure this printing region, some printers perform printing even in a state where paper feeding accuracy cannot be guaranteed under ordinary circumstances, that is, in a state where only one of the two pairs of rollers is biting the paper. With only one of the two roller pairs biting the paper, it is impossible to cope with paper floating or ensure a paper conveying force. Accordingly, it is impossible to ensure paper feeding accuracy, thus resulting in reduced image quality.
At present, an electrostatic attraction force is employed in many cases to convey a recording medium in order to increase the accuracy of recording medium conveyance.
For instance, Japanese Patent No. 2873879 discloses an ink-jet recording apparatus having an electrostatic attraction conveyance member conveying a material on which recording is performed and a cleaning member cleaning the electrostatic attraction conveyance member using liquid higher in electric resistance than ink. The cleaning member is provided in order to clean conductive ink having adhered to the electrostatic attraction conveyance member (such as a belt or a drum), thereby preventing the surface resistance of the electrostatic attraction conveyance member from decreasing as much as possible.
This ink-jet recording apparatus includes a cleaning member that is complicated in structure. Accordingly, the ink-jet recording apparatus is inevitably large in size and costly.
Japanese Patent No. 2915450 discloses a conveyor belt having a specific high resistance layer of 50 μm in thickness on its outer surface and having its inner surface grounded through an idle roller. The outer surface of the conveyor belt is charged to approximately 1500 V. However, when this conveyor belt is used, a negative charge is injected into a recording medium from another power supply. Accordingly, there is the disadvantage that two different power supplies should be prepared. According to Japanese Patent No. 3014815, different charges are injected separately into a conveyor belt and a recording medium.
Further, Japanese Patent No. 3124668 discloses an electrostatic attraction unit for providing electrostatic attraction to a conveyor belt. The electrostatic attraction unit includes a pair of spaced electrodes, a circuit for applying voltage between the electrodes, and a circuit for supplying current for causing at least one of the paired electrodes to generate heat. According to this electrostatic attraction unit, a voltage is applied between the paired electrodes to generate an electrostatic force between the electrodes so that a material on which recording is performed is attracted and adhered to the conveyor belt. This electrostatic attraction unit is different from those providing an electric charge directly to the conveyor belt.
On the other hand, in the case where a recording medium having an ink absorbing layer provided on a base body of high surface resistivity, such as a plastic film, is conveyed, being electrostatically attracted and adhering to an electrostatic attraction conveyor belt, the surface charge of the recording medium has difficulty in moving when the recording medium is separated from the conveyor belt. As a result, separating discharge occurs with an electric charge on the conveyor belt. Once the separating discharge occurs, the surface of the recording medium which surface has been in contact with the conveyor belt is charged. As a consequence, the recording medium that is being conveyed electrostatically adheres to recording media that have been ejected and stacked in a paper ejection tray. This may cause the recording media on which recording has already been performed to be pushed out, or may generate resistance against the conveyance of the recording medium that is being conveyed, thus adversely affecting the conveyability of the recording medium.
This problem of the adverse effect on conveyability remains unsolved in the above-described electrostatic attraction devices.
Accordingly, it is a general object of the present invention to provide an ink-jet recording method in which the above-described disadvantages are eliminated.
A more specific object of the present invention is to provide an ink-jet recording method by which a recording medium is conveyed satisfactorily using an electrostatic attraction force and in which an improvement is made in recording medium stackability in a paper ejection tray part after recording in the case of performing recording on recording media having an ink absorbing layer provided on a base body such as a plastic film.
Another more specific object of the present invention is to provide a recording medium suitable for such an ink-jet recording method.
One or more of the above objects of the present invention are achieved by an ink-jet recording method for performing recording on a recording medium by attaching ink thereto, the recording medium adhering to a conveyor belt because of electrostatic attraction thereto, wherein: the electrostatic attraction is caused by a charging unit, the charging unit applying AC bias to the conveyor belt so that positive and negative charges are provided on the conveyor belt so as to alternate with each other in a direction in which the conveyor belt moves; and a surface of the recording medium which surface comes into contact with the conveyor belt has surface resistivity that falls within a range of 1×109 to 9×1012Ω.
According to the above-described ink-jet recording method, image quality can be improved without providing a spur on the side of the printing surface of the recording medium. Further, cockling, which may occur when the recording medium is plain paper or coated paper having an ink absorbing layer formed on a paper base, can be controlled. Furthermore, the stackability of the recording medium after recording can be improved.
One or more of the above objects of the present invention are also achieved by a recording medium to be employed in an ink-jet recording method for performing recording on the recording medium by attaching ink thereto, the recording medium adhering to a conveyor belt because of electrostatic attraction thereto, wherein: a surface of the recording medium which surface comes into contact with the conveyor belt has surface resistivity that falls within a range of 1×109 to 9×1012Ω.
According to the above-described recording medium, paper transportation can be performed smoothly. As a result, good image quality can be obtained.
Other objects, features and advantages of the present invention will become more apparent from the following detailed description when read in conjunction with the accompanying drawings, in which:
FIG, 6 is a schematic diagram for illustrating an ink-jet recording method using a serial printer according to the embodiment of the present invention;
A description is given below, with reference to the accompanying drawings, of an embodiment of the present invention.
When positive and negative AC voltages are applied to the conveyor belt 21 having the above-described structure, positive (+) belts and negative (−) belts are alternately formed in the insulating layer 21a of the conveyor belt 21 to create alternating fields passing through the paper sheet 11 as shown in
Referring to
It is well known, however, that an electrostatic attraction force is extremely reduced when the distance to an object of attraction becomes great.
The paper sheet 11 is pressed against the conveyor belt 21 by the edge rollers 23 to receive an efficient electrostatic attraction force. As a result, the paper sheet 11 is conveyed to a printing part, being superimposed on the conveyor belt 21 with no space therebetween.
Referring to
In this paper conveyance path, a rotary encoder 61a is provided to the shaft of the conveyor roller 24 as shown in
As the encoder reading sensor 61b, a common encoder reading sensor that outputs pulses four times those actually output from an encoder is known. For instance, in the case of an encoder with 2400 lines per rotation, 9600 pulses may be obtained when a sensor that can output four times as much as the encoder is employed. A motor that drives the conveyor roller 24 is subjected to pulse-managed control based on the output of the encoder 61a so as to perform paper feeding of a desired amount (distance). The minimum unit of the conveyance of the paper sheet 11 is the highest image density (resolution) outputtable by the printer including this device. For instance, in the case of a 600 dpi printer, the minimum unit of feeding is 25.4 mm/600=42.3 μm. In practice, feeding of an integral multiple of 42.3 μm is performed. In the printer of
An example of this is shown below.
It is assumed that control is performed based on a signal four times the output of the encoder 61a of 2400 pulses per rotation. In this case, the number of output pulses obtained from a rotation of the encoder 61a is 2400×4=9600. Provided that the highest image density of the printer is 1200 dpi, then the minimum unit of feeding is 25.4 mm/1200=21.2 μm. Since the encoder 61a rotates once when the conveyor roller 24 rotates once, a roller diameter φ of 64.5 mm is obtained from the following equation:
(φ×π)/9600=21.2 μm. (1)
That is, by providing the encoder 61a of 2400 pulses per rotation to the shaft of the conveyor roller 24 of 64.5 mm in diameter, a paper feed unit that performs feeding of 21.2 μm per pulse for control can be realized.
Alternatively, the diameter of the conveyor roller 24 may be set so that feeding per single pulse of the encoder 61a is a quotient obtained by dividing the highest image density of the printer by n (n=an integer≧2). An example of this is shown below.
It is assumed that control is performed based on a signal four times the output of the encoder 61a of 2400 pulses per rotation. In this case, the number of output pulses obtained from a rotation of the encoder 61a is 2400×4=9600. Provided that the highest image density of the printer is 1200 dpi, then the minimum unit of feeding is 25.4 mm/1200=21.2 μm. In this case, a unit of control is a value obtained by dividing 21.2 μm by n (for instance, 2), that is, 21.2/2=10.6 μm. Since the encoder 61a rotates once when the conveyor roller 24 rotates once, a roller diameter φ of 32.4 mm is obtained from the following equation:
(φ×π)/9600=10.6 μm. (2)
That is, by providing the encoder 61a of 2400 pulses per rotation to the shaft of the conveyor roller 24 of 32.4 mm in diameter, a paper feed unit that performs feeding of 10.6 μm per pulse for control can be realized. As a result, even if there is a single pulse error in control, it is possible to prevent an image from being affected by the error.
Thus, feeding control can be performed with higher accuracy (resolution).
Next,
On the other hand,
It may be determined freely whether to select a reflection sensor or a transmission sensor to read an encoder.
According to the embodiment of the present invention, the surface resistivity of the surface of a recording medium which surface comes into contact with a conveyor belt falls within the range of 1×109 to 9×1012Ω, preferably, 1×109 to 9×1011Ω, under 23° C./50% RH condition.
In general, in the case of performing recording on a recording medium having an ink absorbing layer formed on a base body of high surface resistivity, the surface (base body surface) of the recording medium which surface has been in contact with a conveyor belt is charged. As a result, the recording medium that is being conveyed electrostatically adheres to recording media already ejected and stacked in a paper ejection tray part with images formed thereon after recording. This may cause the recording media after recording to be pushed out, or may generate resistance against the conveyance of the recording medium that is being conveyed, thus adversely affecting the conveyability of the recording medium.
On the other hand, according to the embodiment of the present invention, the surface resistivity of the surface of a recording medium which surface comes into contact with a conveyor belt is set to 9×1012Ω or lower. As a result, the surface potential of the above-mentioned contact surface of the recording medium attenuates immediately, thus causing no adverse effect on the conveyability and stackability of the recording medium. Further, according to the embodiment of the present invention, the surface resistivity of the contact surface of the recording medium is set to 1×109Ω or higher. As a result, sufficient electrostatic attraction to the conveyor belt is secured, thus preventing the occurrence of skewed feeding due to insufficient electrostatic attraction or a decrease in conveyance accuracy.
Referring to
That is, by applying electric charges to the conveyor belt 21 with alternating current, it is possible to charge the conveyor belt 21 while erasing the history of electric charges that have already been thereon. Further, in actual charging, discharge occurs in a minute gap atmosphere between a conveyor belt and a charged object (recording medium), and at the same time, a region to which an electric charge is applied has a certain width. That is, in the case of attempting accurate control of a charging width, if application of electric charges continues even after the conveyor belt is stopped, the past history may be erased for an uncertain width, or the electric charges may be applied in an undesired direction. Further, a current flowing at the time of charging, although extremely small in amount, may generate heat on the conveyor belt to induce the generation of pin holes, which may lead to leakage.
According to the embodiment of the present invention, it is possible to control a charging width accurately with respect to a conveyor belt so as to eliminate the risk of damaging the conveyor belt.
On the other hand, in the case of employing a single-layer conveyor belt 121 formed only of an insulating layer as shown in
According to the embodiment of the present invention, when the ink-jet recording printer (for instance, of
Thus, an image is formed on the paper sheet 11, and the paper sheet 11 is conveyed further downstream. The direction in which the conveyor belt 21 moves is changed by the tension roller (driven roller) 26. The paper sheet 11 is separated from the conveyor belt 21 because of the curvature of the tension roller 26 and the stiffness of the paper sheet 11 so as to be guided to a paper ejection tray 51 (a part to which output paper is ejected). At this point, power for conveying the paper sheet 11 is obtained basically from the electrostatic attraction force generated between the paper sheet 11 and the conveyor belt 21 and the rotation of the conveyor belt 21. At the time of image formation, the paper sheet 11 is conveyed without necessity for a pressing force from the side of its surface on which an image is formed.
Next,
In step S11, the continuous rotation of the conveyor belt 21 is started to move the conveyor belt 21 in the sub scanning direction, when, in step S12, the application of AC bias to the charging roller 25 (the conveyor belt 21) is started. In step S13, the rotation of the conveyor belt 21 and the application of AC bias are stopped, when, in step S14, the feeding of the paper sheet 11 is started. In step S15, printing is started, and when the printing of step S15 is completed, in step S16, the conveyor belt 21 is rotated to move in the sub scanning direction for line feeding. Steps S15 and S16 are repeated until printing is completed for the paper sheet 11 in step S17. Then, in step S18, the paper sheet is ejected, and the application of AC bias to the charging roller 25 is started. The charging performed between steps S11 and S13 and in step S18 is referred to as prefeed charging.
According to the embodiment of the present invention, while the conveyor belt 21 is in continuous operation, the application of AC bias is performed so as to store electric charges on the conveyor belt 21. As a result, desired positively and negatively charged regions can be formed on the conveyor belt 21 with accuracy, and AC bias application can be controlled easily.
According to the embodiment of the present invention, multiple projections may be provided on the surface of the conveyor roller 24 and/or the tension roller 26.
The grip roller 24a has multiple projections S provided on its surface. In the case of employing the grip roller 24a, the projections S of the grip roller 24a bite the conveyor belt 21 or the paper sheet 11 so as to prevent the occurrence of slippage between the grip roller 24a and the conveyor belt 21 or the paper sheet 11.
Next,
According to the embodiment of the present invention, the surface resistivity of the surface (contact surface) of a recording medium which surface comes into contact with a conveyor belt falls within the range of 1×109 to 9×1012Ω. The recording medium having a contact surface whose surface resistivity falls within such a range may be formed by including an antistatic agent in the base body of the recording medium by internal addition. Alternatively, the recording medium may also be formed by having coating liquid containing an antistatic agent included in or applied on the base body of the recording medium by coating such as roll coating, blade coating, or air knife coating.
Preferred antistatic agents employed in the embodiment of the present invention include: alkali metal salts such as sodium chloride, potassium chloride, lithium chloride, and sodium sulfate, alkaline earth metal salts such as calcium chloride and barium chloride, colloidal metal oxides such as colloidal silica and colloidal alumina, and conductive fine particle metal oxides such as tin oxide, titanium oxide, and zinc oxide as inorganic antistatic agents; and organic salts such as poly(sodium ethylenesulfonate), sodium styrene maleic anhydride, poly(2-acrylamide-sodium 2-methylsulfonate), poly(vinylbenzyltrimethylammonium chloride), and sodium sulfamate, organic electrolytes, and antistatic agents using a siloxane bond as organic antistatic agents. As the antistatic agents using a siloxane bond, chemical complexes of a vinyl polymer including a silyl group and polysiloxane are preferred because variations due to environmental conditions are small in those chemical complexes and their adhesiveness to plastic films is excellent.
The amount of the antistatic agent included in or applied to the base body is suitably controlled based on the material and thickness of the base body, the types of other additives and their amount of inclusion, and the properties of the base body, and is not limited to a specific value. In general, the amount of conductive material included falls within the range of 0.01 to 10 g/m2, preferably, 0.1 to 5 g/m2.
There is no specific limitation on the base body of a recording medium according to the embodiment of the present invention. A sheet-like base body used in the conventional recording medium may be employed as it is. For instance, polyolefin or polystyrene synthetic paper, woodfree paper, art paper, coated paper, cast-coated paper, wall paper, backing paper, synthetic resin impregnated paper, emulsion impregnated paper, synthetic rubber impregnated paper, synthetic resin containing paper, paperboard, cellulose fiber paper, and various transparent plastic films or sheets of polyolefin, polyvinyl chloride, polyethylene terephthalate, polystyrene, polymethacrylate, and polycarbonate may be employed. Further, white opaque films formed by adding white pigment and filler to the above-described synthetic resins and foamed sheets formed by foaming the above-described synthetic resins may also be employed. A layered body of any combination of the above-described base material films, such as a layered body of cellulose fiber paper and synthetic paper or a layered body of cellulose fiber paper and a plastic film, may also be employed. If such base bodies have poor adhesiveness to an ink absorbing layer or an antistatic agent layer formed thereon, it is preferable to perform primer processing or corona discharge processing on the surfaces of the base bodies.
There is no particular restriction on the thickness of the base body employed in the embodiment of the present invention. However, considering a feeling to the touch and elasticity, the base body is preferably 20 to 300 μm in thickness. More preferably, the base body is 40 to 250 μm in thickness so as to produce remarkable effects according to the present invention.
The recording medium according to the embodiment of the present invention may be composed of only a base body if the base body has ink absorbability. However, it is preferable that at least one ink absorbing layer be formed on the base body to obtain a high quality image. There are two common types of ink absorbing layers. One type has an air gap layer, being formed mainly of solid particles. The other type is formed mainly of a polymer that swells or dissolves in water or a solvent included in ink. Either type of ink absorbing layer is employable in the recording medium according to the embodiment of the present invention.
Next, a description is given below of specific examples of the recording medium and ink according to the present invention and their comparative examples. However, the present invention is not limited to the below-described specific examples.
[Production of Recording Medium]
(Recording Medium 1)
First, 100 g of alumina sol of a solid content of 18 wt % synthesized by hydrolysis and peptization of aluminum alkoxide and 32 g of an aqueous solution of 6.2 wt % polyvinyl alcohol were mixed to form a coating liquid. The coating liquid was applied on a polyethylene terephthalate film (100 μm in thickness, transparent) using a bar coater so that the amount of coating would become 26 g/m2 after drying, and was dried. As a result, a pseudoboehmite layer (ink absorbing layer) was formed.
Next, silica sol coating liquid of a solid content of 5 wt % composed of silica sol of 10 to 20 nm in primary particle size and a polyvinyl alcohol copolymer including a silanol group (R-polymer R-1130 [product name]; manufactured by Kuraray Co., Ltd.) (the copolymer/SiO2=0.3) was applied on the surface (bottom surface) of the base material (polyethylene terephthalate film) on the side opposite to the side of the surface on which the ink absorbing layer was formed so that the amount of coating of a silica gel layer formed after drying would become 1 g/m2. Thereafter, the silica sol coating liquid was subjected to drying and heat treatment at 140° C.
The surface resistivity of the ink absorbing layer (pseudoboehmite layer) surface was 9×1011Ω, and the surface resistivity of the bottom surface was 3×1012Ω.
The measurement of surface resistivity was performed based on JIS K 6911. Specifically, the measurement was performed using 4329A HIGH RESISTANCE METER and 16008A RESISTIVITY CELL manufactured by Yokogawa Hewlett-Packard, Ltd. after charging of one minute with an applied voltage of 100 V. The environment at the time of humidification of a recording medium and measurement of surface resistivity was 23±1° C. and 50±2% RH. This was the same in the following.
(Recording Medium for Comparison 1)
First, 100 g of alumina sol of a solid content of 18 wt % synthesized by hydrolysis and peptization of aluminum alkoxide and 32 g of an aqueous solution of 6.2 wt % polyvinyl alcohol were mixed to form a coating liquid. The coating liquid was applied on a polyethylene terephthalate film (100 μm in thickness, transparent) using a bar coater so that the amount of coating would become 26 g/m2 after drying, and was dried. As a result, a pseudoboehmite layer (ink absorbing layer) was formed. Then; the pseudoboehmite layer was subjected to heat treatment at 140° C.
The surface resistivity of the bottom surface of the base material was 2×1015Ω.
(Recording Medium 2)
[Manufacturing of Antistatic Agent Using Siloxane Bond]
A solution in which 100 parts of butyl methacrylate (hereinafter, BMA), 3 parts of azobis(isobutylonitrile) (hereinafter, AIBN), and 2 parts of n-dodecyl mercaptan were dissolved was added dropwise to 90 parts of toluene heated to 100° C. in 6 hours, and was subjected to reaction for 2 hours. As a result, a BMA polymer of a molecular weight of 5000 was obtained. Next, liquid formed by dissolving 2.5 parts of methyldimethoxysilane and 0.0005 parts of chloroplatinic acid in isopropanol was added to 30 parts of the obtained BMA polymer, which was hermetically sealed at a temperature of 90° C. and subjected to reaction for 8 hours. As a result, a BMA polymer including a silyl group was obtained. Further, 25 parts of water, 35 parts of ortho-ethyl silicate, and 0.5 parts of a concentrated hydrochloric acid were mixed and subjected to reaction at 60° C. for 5 hours. As a result, a polysiloxane solution was obtained. Then, 100 parts of the polysiloxane solution was added to 20 parts of the BMA polymer including a silyl group, and the mixture was stirred at room temperature for 30 minutes for reaction. After adding 40 parts of ethyl acetate, 20 parts of n-butanol, and 20 parts of cyclohexanone to the mixture, the mixture was allowed to stand for 24 hours. As a result, an antistatic agent was obtained.
Then, 100 g of alumina sol of a solid content of 18 wt % synthesized by hydrolysis and peptization of aluminum alkoxide and 32 g of an aqueous solution of 6.2 wt % polyvinyl alcohol were mixed to form a coating liquid. The coating liquid was applied on a polyethylene terephthalate film (100 μm in thickness, transparent) using a bar coater so that the amount of coating would become 26 g/m2 after drying, and was dried. As a result, a pseudoboehmite layer (ink absorbing layer) was formed.
Next, the above-described antistatic agent liquid using the siloxane bond was applied on the bottom side of the base material (polyethylene terephthalate film) so that the amount of coating would become 1 g/m2 after drying, and was dried.
The surface resistivity of the bottom surface of the base material was 3×1010Ω.
(Recording Medium 3)
First, 100 g of alumina sol of a solid content of 18 wt % synthesized by hydrolysis and peptization of aluminum alkoxide and 32 g of an aqueous solution of 6.2 wt % polyvinyl alcohol were mixed to form a coating liquid. The coating liquid was applied on a polyethylene terephthalate film (100 μm in thickness, transparent) using a bar coater so that the amount of coating would become 26 g/m2 after drying, and was dried. As a result, a pseudoboehmite layer (ink absorbing layer) was formed.
Next, a coating liquid having the below-described composition was applied on the bottom side of the base material (polyethylene terephthalate film) so that the amount of coating would become 5 g/m2 after drying, and was dried.
Composition:
The surface resistivity of the bottom surface of the base material was 2×109Ω.
(Recording Medium for Comparison 2)
Coating liquid having the below-described composition was applied on the bottom side of Recording Medium for Comparison 1 so that the amount of coating would become 5 g/m2 after drying, and was dried.
Composition:
The surface resistivity of the bottom surface of the obtained recording medium was 4×108Ω.
[Preparation of Ink]
(Ink 1)
An ink composition of the following formula was prepared, and was adjusted with a 10% lithium hydroxide aqueous solution so as to have a pH of 9. Thereafter, the ink composition was filtered with a membrane filter of 0.8 μm in average pore size so that an ink composition (Ink 1) was obtained.
Formula:
(Ink 2)
The preparation of Ink 2 was equal to that of Ink 1 except that an ink composition of the following formula was employed. The ink composition was adjusted with sodium hydroxide so as to have a pH of 9, so that an ink composition (Ink 2) was obtained.
Formula:
(Ink 3)
The preparation of Ink 3 was equal to that of Ink 1 except that an ink composition of the following formula was employed. The ink composition was adjusted with lithium hydroxide so as to have a pH of 9, so that an ink composition (Ink 3) was obtained.
Formula:
Next, using the above-described recording media and Inks 1 through 3, recording was performed with an ink-jet recording apparatus having the configuration of
As a result, Recording Medium for Comparison 1, while being conveyed, electrostatically adhered to a recording medium that had already been ejected onto the paper ejection part, and pushed out the recording medium after recording. On the other hand, Recording Media 1, 2, and 3 according to the present invention did not adhere to a recording medium that had already been ejected on the paper ejection part, and showed good stackability in the paper ejection part.
In the case of Recording Medium for Comparison 2, its adhesiveness to the conveyor belt was insufficient so that skewed feeding occurred. The antistatic agent layer of Recording Medium 2 according to the present invention in particular showed good adhesiveness to the base body.
Thus, according to the ink-jet recording method of the present invention, image quality can be improved without providing a spur on the side of the printing surface of a recording medium. Further, cockling, which may occur when the recording medium is plain paper or coated paper having an ink absorbing layer formed on a paper base, can be controlled. Furthermore, the stackability of the recording medium after recording can be improved. Further, the application of AC bias to a charging roller may be stopped when a conveyor belt remains stationary. Accordingly, electrostatic attraction can be performed stably without removing charges on the conveyor belt. Further, the possibility of damaging the conveyor belt is reduced. In addition, the application of AC bias to the charging roller may be performed at the time of paper feeding. Therefore, electrostatic attraction can be performed stably without affecting printing throughput.
According to the recording medium of the present invention, paper transportation can be performed smoothly. As a result, good image quality can be obtained.
The present invention is not limited to the specifically disclosed embodiment, and variations and modifications may be made without departing from the scope of the present invention.
The present application is based on Japanese priority patent applications No. 2003-158507, filed on Jun. 3, 2003, and No. 2004-162241, filed on May 31, 2004, the entire contents of which are hereby incorporated by reference.
Number | Date | Country | Kind |
---|---|---|---|
2003-158507 | Jun 2003 | JP | national |
2004-162241 | May 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP04/07995 | 6/2/2004 | WO | 11/21/2005 |