Exemplary embodiments of the present disclosure relate to a drying device and an inkjet printer system including the drying device.
In a printer employing a liquid droplet discharge method such as an inkjet printer, an image is fixed onto a recording medium with ink due to evaporation of a solvent component of the ink that permeates the recording medium. In particular, as the permeation of the ink increases, the image is more securely fixed. In recent years, demands for printing on recording media such as coated paper have been increased due to a request for finer image formation.
Permeation of ink into the coated paper with a coated surface is slower than the permeation of ink into a normal sheet, so that the degree of fixation of the image onto the coated paper tends to decrease. Thus, coated paper having better permeability has been developed, but which in turn narrows options for the type of sheets usable, and therefore is not accepted by users.
Further, oily ink and ultra-violet curing ink with lower permeation but higher fixing property are known. Both inks may contain substrates harmful to humans. As a result, special environmental and health precautions are required.
When the image is fixed on the regular and not-luxurious coated paper with aqueous ink, heat to eliminate solvent medium included in the aqueous ink needs to be applied. On the other hand, when using normal paper other than the coated paper, so much heat is not necessary because the aqueous ink effectively permeates the normal paper. When a heater to generate/supply the heat necessarily to be applied to the coated paper is provided, the heat becomes excessive for normal paper. In addition, an extra appliance is needed to supply power to the heater.
As a result, a system in which a drying device to apply heat to the recording medium is disposed downstream of the image forming section of the inkjet printer has been invented. In this system, the inkjet printer retains the capability to heat the coated paper during conveyance to such a degree that the image is not taken by a roller that contacts the image surface on both sides, and the drying device retains capability to heat the image even on other types of sheets for output commercially available in the future.
In one embodiment of the disclosure, there is provided a drying device including a drying section to dry a recording medium; a cooling section to cool the recording medium conveyed from the drying section: and a duct to expel air inside the drying section to outside the drying device. The duct including a joint section where the air from the drying section meets air from the cooling section meet, and the air from the drying section containing moisture and solvent medium is cooled in the duct.
These and other features and advantages of the present disclosure will become apparent upon consideration of the following description of embodiments of the present disclosure when taken in conjunction with the accompanying drawings.
The aforementioned and other aspects, features, and advantages of the present disclosure would be better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
Hereinafter, embodiments of the present disclosure will be described with reference to accompanying drawings.
In the first embodiment, the temperature of moist air having a relatively higher temperature is decreased to 45° C. or less, and generation of condensation is prevented. For this purpose, a path of a duct is bent to lengthen the path, so that the air including a great deal of moisture is gradually cooled when passing though the duct. Further, to increase the cooling efficiency, a contact area between the saturated air and the duct is increased and the duct is formed with materials with a higher heat conductivity. The air containing a solvent medium needs to be handled, and therefore materials for the duct are preferably solvent-resistant materials. In the present disclosure, stainless steel (such as SUS304) is used due to its higher solvent-resistant property. However, stainless steel has a lower heat conductivity than other steels, and has a low radiation performance. Thus, the air sucked in from the drying section and the low-temperature air from the cooling section that cools the recording medium are made to collide, to thereby accelerate reduction of the temperature.
The drying device according to the first embodiment will be described in more detail referring to the drawings, in particular
A continuous recording medium W rolled into the shape of a roller is sent from an unwinder UW and a coating device C pre-treats the recording medium W with a solvent coating. Then, the inkjet printer P prints letters or images on the recording medium W, and the recording medium W is sent to a drying device D. In the drying device D, the recording medium W after having been subjected to heating and cooling processes is rolled up by a re-winder RW to complete a single printing process.
The drying device D includes a dancer roller unit 1 including two driven rollers movable in the vertical direction. The dancer roller unit 1 applies its own weight to the recording medium W conveyed to the drying device D, so that the recording medium W is pulled with tension by the dancer roller unit 1 downward.
Next, the recording medium W passes through a sensor 2 that senses the recording medium W and the drying device D whether or not the recording medium W is at an input part. Then, another sensor detects the temperature of the recording medium W. The recording medium W is heated while passing through a drying section 3 to accelerate fixing of the image onto the recording medium W. The drying section 3 includes a built-in heater and includes 6 heat rollers each having a surface controlled at a predetermined temperature. The heat roller is disposed to rotate following the move of the recording medium W.
A cutter unit 4 including a cutter is disposed to prevent the internal structure inside the drying device from being damaged due to an excess tension applied to the recording medium W caused by malfunction and runaway of the drying device. The cutter unit 4 cuts the recording medium W depending on the tension of the recording medium W and an increasing speed of the tension.
The recording medium W is conveyed to a cooling section 5 that cools the recording medium W after having passed the above sections. The cooling section 5 includes a plurality of driven rollers and defines a path in which the recording medium W is moved in the vertical direction. The cooling section 5 includes a plurality of cooling fans 6 each to cool the recording medium W by blowing air from the bottom upward. In addition, air is taken in from an intake port 7. The air sent by the cooling fans 6 hits and flows along the recording medium W and is sucked out or expelled via the intake port 7. When the recording medium W passes through the cooling section 5, cooling of the recording medium W is complete. Length of the cooling path, and amount and temperature of the cooling air, are determined based on the heat applied in the drying section 3 and the thermal capacity of the recording medium W, and are determined in the design of the device.
After the cooling section 5, provided are an outfield roller 8 and a pressure roller 9 that pinches the recording medium W together with the outfield roller 8. The outfield roller 8 is connected to a drive source such as a motor, and minutely adjusts a speed of the recording medium W depending on the state of the dancer roller unit 1 or a position in the vertical direction. The outfield roller 8 and the pressure roller 9 can convey the recording medium W following rotation of the drive source.
With the present structure, the condensed liquid inside the duct 10 is concentrated and collected in a collection section 16 due to the weight and is collected therein, because the collection section 16 disposed in the bottom of the duct 10 has a narrowed shape. The cooling section 5 and the duct 10 are connected via an opening 14. The air from the drying section 3 joins in the vicinity of the opening 14 (at a joint section 18) inside the duct 10, and is cooled. The air joined in the vicinity of the opening 14 is sucked and exhausted in the direction of the arrow as illustrated in
As described above, according to the embodiments of the present disclosure, provided is a drying device that can absorb heat in the air such that the moisture and the air containing the solvent medium in ink do not cause dew formation even discharged outside the device, and after the moisture in the air and the solvent medium is concentrated in a liquid shape, is collected in the form of the liquid, and the air is discharged outside. Also, an inkjet printer system including the drying device is provided.
According to the drying device and the inkjet printer system including the drying device according to at least one embodiment of the present disclosure, water and solvent are collected from the air containing a great deal of moisture generated in the drying section, and condensation generation due to the concentration outside the drying device can be prevented.
Additional modifications and variations of the present disclosure are possible in light of the above teachings. It is therefore to be understood that, within the scope of the appended claims, the disclosure may be practiced other than as specifically described herein.
Number | Date | Country | Kind |
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2015-243720 | Dec 2015 | JP | national |
2016-208201 | Oct 2016 | JP | national |
The present application is a Rule 1.53(b) continuation of application Ser. No. 15/364,643 filed on Nov. 30, 2016, which claims priority pursuant to 35 U.S.C. § 119(a) from Japanese patent application numbers 2015-243720 and 2016-208201, filed on Dec. 15, 2015 and Oct. 24, 2016, respectively, with the Japanese Patent office, the entire disclosure of each of which is incorporated by reference herein.
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Number | Date | Country | |
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Parent | 15364643 | Nov 2016 | US |
Child | 15864067 | US |