The present invention relates to a printing press including inkjet heads for spraying ink on a sheet.
For example, Japanese Patent Laid-Open No. 2013-240989 (literature 1) discloses an example of a digital printing apparatus including inkjet heads. The digital printing apparatus disclosed in literature 1 includes an ink drying device for drying ink applied, by the inkjet heads, to a sheet to be printed. This ink drying device is controlled based on the convey state of the sheet. The ink drying device irradiates the sheet with light such as infrared or ultraviolet rays to dry ink by thermal energy. This digital printing apparatus executes printing by raising the surface temperature of the sheet to a predetermined temperature.
The digital printing apparatus disclosed in literature 1, however, poses a problem that infrared or ultraviolet rays for drying ink heat the surface of a printing cylinder for conveying the sheet, which excessively raise the surface temperature of the sheet. If the surface temperature of a sheet becomes too high, the viscosity of ink changes, thereby degrading the image quality of a printing product.
This problem can be solved to some extent by cooling the printing cylinder by a water or oil cooling device. However, this type of cooling device is difficult to control since the output is very large, and the device is large in size. Furthermore, since the rise time is long and a coolant may leak, the apparatus is difficult to deal with. Therefore, it is required to readily cool the printing cylinder without using such type of cooling device.
It is an object of the present invention to efficiently dissipate the heat of a printing cylinder while preventing the printing cylinder from being overheated when an amount of heat generated at the time of printing is transferred to the surface of the printing cylinder.
In order to achieve the above object of the present invention, there is provided a printing press including a printing cylinder configured to convey a sheet, an inkjet head configured to execute printing by discharging ink droplets to the sheet conveyed by the printing cylinder, a drying device opposing the printing cylinder and configured to dry printed ink, and a heat dissipation member overlaid and attached on an outer surface of the printing cylinder, the heat dissipation member including a main body made of a non-metal material in a sheet-like shape, and a plurality of ventilation portions through which air passes in a thickness direction of the main body.
An embodiment of a printing press according to the present invention will be described in detail below with reference to
The feeder unit 2 has a structure of transferring the sheet 4 from a feeder pile 11 to a feeder board 13 by a sucker 12. The sucker 12 is connected to an intermittent sheet feed valve 14, and operates in one of a mode in which the sheets 4 are successively fed and a mode in which the sheets 4 are intermittently fed. If only the obverse surface of each sheet 4 is printed, the sucker 12 successively feeds the sheets 4 to the feeder board 13. On the other hand, if the obverse and reverse surfaces of each sheet 4 are printed, the sucker 12 intermittently feeds the sheets 4 to the feeder board 13.
The printing unit 3 includes a feed-side transfer cylinder 16 to which the sheet 4 fed from the feeder unit 2 is conveyed by a sheet feed-side swing device 15, a printing cylinder 17 to which the sheet 4 is fed from the feed-side transfer cylinder 16, and a plurality of transport cylinders 18 to 21 for feeding the printed sheet 4. The feed-side transfer cylinder 16 includes a heater (not shown) for heating the sheet 4 to a predetermined temperature. The printing cylinder 17 sucks and conveys the sheet 4, and includes a sucking device 22 (see
The printing unit 3 further includes first to fourth inkjet heads 23 to 26 and an ink drying lamp 27, all of which oppose the printing cylinder 17. The first to fourth inkjet heads 23 to 26 are arranged on the downstream side of the feed-side transfer cylinder 16 in the sheet convey direction, and execute printing by discharging ink droplets to the sheet 4 conveyed by the printing cylinder 17. Note that the number of inkjet heads is not limited to four. The ink drying lamp 27 is arranged on the downstream side of the fourth inkjet head 26 in the convey direction, and dries (cures) printed ink which has been applied to the sheet 4 by the first to fourth inkjet heads 23 to 26. In this embodiment, the ink drying lamp 27 forms a “drying device” according to the present invention.
The above-described plurality of transport cylinders include the first delivery-side transfer cylinder 18 for receiving the sheet 4 from the printing cylinder 17, the second delivery-side transfer cylinder 19 for receiving the sheet 4 from the first delivery-side transfer cylinder 18, and the third delivery-side transfer cylinder 20 and pre-converting double-size cylinder 21 for receiving the sheet 4 from the second delivery-side transfer cylinder 19. The sheet 4 whose reverse surface is printed is conveyed from the second delivery-side transfer cylinder 19 to the pre-converting double-size cylinder 21. The sheet 4 whose obverse surface is printed or the sheet 4 whose obverse and reverse surfaces are printed is fed from the second delivery-side transfer cylinder 19 to the third delivery-side transfer cylinder 20, and then fed to the delivery pile 6 via a delivery belt 28.
The feed-side transfer cylinder 16, printing cylinder 17, first delivery-side transfer cylinder 18, second delivery-side transfer cylinder 19, third delivery-side transfer cylinder 20, and pre-converting double-size cylinder 21 include gripper devices 31 to 36 for transferring the sheet 4, respectively. These gripper devices 31 to 36 have a conventionally known structure of gripping and holding the downstream end portion of the sheet 4 in the convey direction.
A convertible swing device 37 for feeding the sheet 4 from the pre-converting double-size cylinder 21 to the printing cylinder 17 is arranged between the pre-converting double-size cylinder 21 and the feed-side transfer cylinder 16. The convertible swing device 37 grips the upstream end portion of the sheet 4 in the convey direction, which has been fed by the pre-converting double-size cylinder 21, and feeds the sheet 4 to the printing cylinder 17 while the obverse surface of the sheet 4 opposes the printing cylinder 17.
The outer portion of the printing cylinder 17 is formed by three gaps 41 (41a to 41c) each accommodating the gripper device 32, and three sheet support portions 42 each for sucking and holding the sheet 4. The three gaps 41 are formed at positions spaced apart from each other in the circumferential direction in the outer surface of the printing cylinder 17. More precisely, the three gaps 41 are formed at positions which divide the outer surface into three parts in the circumferential direction. Although details will be described later, the three sheet support portions 42 are formed between the gaps 41. That is, the printing cylinder 17 is a triple-size cylinder including three pairs of gaps 41 and sheet support portions 42.
As shown in
The gripper shaft 43 extends from one end portion of the printing cylinder 17 to the other end portion in the axial direction in parallel to the axis (rotation axis) of the printing cylinder 17, and is rotatably supported by support plate members 46a of support plates 46 (see
The gripper member 44 is disposed at each of a plurality of positions in the axial direction of the corresponding gripper shaft 43. The gripper member 44 moves between a gripping position indicated by solid lines in
The gripper receiving portion 49 includes a gripper pad 45 for sandwiching the sheet 4 in cooperation with the gripper member 44, and a gripper pad shaft 47 for detachably holding the gripper pad 45. The gripper pad 45 is fixed by a fixing bolt 48 while it is placed on the distal end portion of the gripper pad shaft 47 attached to the gap 41. In this embodiment, the gripper pad shaft 47 is formed by a support member 51 which protrudes outward in the radial direction of the printing cylinder 17 from the bottom of the gap 41, and a holding member 53 which is fixed by a fixing bolt 52 while it is overlaid on a protruded end portion 51a of the support member 51. The support member 51 and the holding member 53 extend from one end portion of the printing cylinder 17 to the other end portion in the axial direction in parallel to the axis of the printing cylinder 17. The support member 51 is fixed to the bottom of the gap 41 by a fixing bolt 54. An abutting surface 55 between the holding member 53 and the protruded end portion 51a of the support member 51 extends in the radial and axial directions of the printing cylinder 17.
As shown in
The metal sheet 61 is obtained by forming a number (a plurality) of ventilation holes 63 in a sheet made of stainless steel or the like. The metal sheet 61 is formed in a shape to cover the entire region of each sheet support portion 42, and the two end portions of the metal sheet 61 are fixed to the printing cylinder 17. The two end portions indicate the upstream and downstream end portions in the sheet convey direction. The downstream end portion of the metal sheet 61 in the sheet convey direction is folded inside in the radial direction of the printing cylinder 17 along an end portion 59a of the box-shaped member 59 in the gap 41 (41a) shown in
The non-metal sheet 62 forms a “heat dissipation member” according to the present invention. This non-metal sheet 62 includes a main body 65 formed in a sheet-like shape using a non-metal material, and a number (a plurality) of ventilation portions 66 through which air passes in the thickness direction of the main body 65, as shown in
Bases 67 and 68 are disposed in the two end portions of the main body 65. The two end portions indicate those in the right-and-left direction in
Each ventilation portion 66 is formed by a through hole which extends through the main body 65 in the thickness direction. The opening shape of each ventilation portion 66 is a circle, as shown in
The thus formed non-metal sheet 62 is attached to the printing cylinder 17 using the first base 67 and the second base 68 while it is overlaid on the above-described metal sheet 61 (the outer surface of the printing cylinder 17). As shown in
As shown in
As shown in
The second base 68 disposed in the other end portion of the non-metal sheet 62 is held by a second holding unit 81. The second holding unit 81 is disposed in the gap 41 (41b) separated, on the upstream side in the sheet convey direction, from the gap 41 (41a) where the first holding unit 71 for holding the first base 67 is disposed. The second holding unit 81 in the gap 41 (41b) has the same structure as that of the second holding unit 81 in the gap 41 (41a) shown in
The guide member 82 extends from one end portion of the printing cylinder 17 to the other end portion in the axial direction, and is formed to have a groove-shaped cross-section with a pair of ribs 82a and 82b. The rib 82a is provided in the downstream end portion of the guide member 82 in the sheet convey direction, and the rib 82b is provided in the upstream end portion of the guide member 82 in the sheet convey direction. The guide member 82 is fixed, by a support bracket 85 and fixing bolts 86 (see
The slider 83 is formed in a plate shape extending in the axial direction of the printing cylinder 17 along the guide member 82. The slider 83 is attached to the guide member 82 by two kinds of bolts. The two kinds of bolts are an adjusting bolt 87 extending in the sheet convey direction and a fixing bolt 88 extending in the radial direction of the printing cylinder 17.
The adjusting bolt 87 rotatably extends through the rib 82a of the guide member 82, and is threadably engaged with the slider 83. The adjusting bolt 87 positions the slider 83 in the sheet convey direction with reference to the guide member 82. In this embodiment, a stopper 89 (see
As shown in
As shown in
Each cover plate 84 is fixed to the slider 83 by fixing bolts 93 in the two end portions in the longitudinal direction while it is overlaid on the slider 83. As shown in
A procedure of attaching the non-metal sheet 62 to the printing cylinder 17 will now be described. To attach the non-metal sheet 62 to the printing cylinder 17, one end portion of the first base 67 in the longitudinal direction is inserted from the outside of the printing cylinder 17 in the axial direction to the release portion 73 formed in one end portion of the printing cylinder 17 in the axial direction. This attachment operation and an operation of detaching the non-metal sheet 62 from the printing cylinder 17 can be readily performed by gripping the handle 69. The first base 67 is further moved in the axial direction, and is inserted to the space S1 of the first holding unit 71.
If the non-metal sheet 62 is pulled to the other end portion side while one end portion of the non-metal sheet 62 is inserted to the space S1, the first base 67 abuts against the abutment wall 72, and cannot move any more. Thus, when one end portion of the non-metal sheet 62 is inserted to the above-described space S1, the non-metal sheet 62 is held by the first holding unit 71 (printing cylinder 17) while one end portion of the non-metal sheet 62 is prevented from being removed.
After that, the main body 65 of the non-metal sheet 62 is overlaid on the sheet support portion 42 of the printing cylinder 17. The second base 68 is sandwiched by the cover plate 84 and the slider 83 of the second holding unit 81, thereby fixing the cover plate 84 to the slider 83 by the fixing bolts 93.
The adjusting bolt 87 is tightened to pull the non-metal sheet 62 together with the slider 83. When the non-metal sheet 62 is pulled, it is brought into tight contact with the metal sheet 61 (the outer surface of the printing cylinder 17). After that, while a predetermined tension acts on the non-metal sheet 62, the slider 83 is fixed to the guide member 82 using the fixing bolts 88. By fixing the slider 83 to the guide member 82, the operation of attaching the non-metal sheet 62 to the printing cylinder 17 is completed.
If the sucking device 22 operates while the non-metal sheet 62 is attached to the printing cylinder 17, the air passes through the ventilation portions 66 of the non-metal sheet 62 and the ventilation holes 63 of the metal sheet 61, and is sucked by the suction chamber 56, and thus the sheet 4 can be sucked to the non-metal sheet 62.
The printing press 1 performs a print operation while the sucking device 22 thus operates. Therefore, the sheet 4 is conveyed while it is sucked to the printing cylinder 17, and the first to fourth inkjet heads 23 to 26 spray ink on the sheet 4, thereby executing printing.
When the sheet 4 is fed to a position opposing the ink drying lamp 27, and irradiated with ultraviolet or infrared rays by the ink drying lamp 27, thereby drying (hardening) ink attached to the sheet 4. At this time, the surface of the sheet 4 is heated, and the heat is transferred from the sheet 4 to the non-metal sheet 62.
Since the non-metal sheet 62 is formed in a sheet-like shape having a number of ventilation portions 66, it has a small heat capacity and has a small contact area with the sheet 4. The non-metal sheet 62 absorbs the heat of the sheet 4 when opposing the ink drying lamp 27, and dissipates the heat when moving away from the ink drying lamp 27 by the rotation of the printing cylinder 17. Thus, the heat generated by the ink drying lamp 27 is temporarily absorbed by the non-metal sheet 62, and then dissipated. This means that the non-metal sheet 62 substantially functions as an adiabatic material, and makes it difficult to transfer, to the printing cylinder 17, heat generated at the time of printing or ink hardening. The ventilation portions 66 of the non-metal sheet 62 facilitate, during the rotation of the printing cylinder 17, dissipation of the heat of the non-metal sheet 62 transferred from the sheet 4 at the time of ink hardening.
Therefore, according to this embodiment, it is possible to provide a printing press which can, by a simple method, efficiently dissipate the heat of the printing cylinder 17 while preventing the printing cylinder 17 from being overheated when an amount of heat generated at the time of printing is transferred to the surface of the printing cylinder 17.
By adhering the non-metal sheet 62 to the printing cylinder 17, and executing printing, as described above, overheating of the printing cylinder 17 is suppressed and heat dissipation of the printing cylinder 17 is improved, thereby increasing the number of continuous printable sheets until the temperature of the printing cylinder 17 reaches the use limit. The cooling structure formed using the non-metal sheet 62 is simple and can be implemented at low cost, as compared with a water or oil cooling device (not shown).
In this embodiment, the printing cylinder 17 includes the sucking device 22 for sucking and conveying the sheet 4. The main body 65 of the non-metal sheet 62 is formed by a sheet made of a non-metal material. The ventilation portions 66 of the non-metal sheet 62 are formed by a number of through holes extending through the main body 65 in the thickness direction. Therefore, according to this embodiment, the sheet 4 is sucked to the non-metal sheet 62 by the sucking device 22. Since the diameter of each ventilation portion 66 falls within the range of 0.2 mm (inclusive) to 1 mm (inclusive), pressing against the opening edges of the ventilation portions 66 forms no marks on the sheet 4 sucked to the non-metal sheet 62. Therefore, according to this embodiment, it is possible to provide a printing press which provides high-quality printing products.
In this embodiment, the thickness of the main body 65 of the non-metal sheet 62 falls within the range of 0.7 mm (inclusive) to 0.5 mm (inclusive). Thus, since it is possible to suppress the heat capacity of the non-metal sheet 62 to a small capacity, the non-metal sheet 62 which readily absorbs and dissipates heat is obtained. Therefore, it is possible to provide a printing press in which the temperature of the printing cylinder 17 is further difficult to rise.
The above-described embodiment has explained an example in which the non-metal sheet 62 is made of PFA. However, the material used to form the non-metal sheet 62 is not limited to PFA, and may be another fluororesin, a synthetic resin material such as polyimide, carbon, or the like. As a method of forming the ventilation portions 66 in the non-metal sheet 62, punching, etching, a laser drilling method, or the like can be adopted.
The material used to form the non-metal sheet 62 may be obtained by braiding a wire such as a mesh or net material, instead of the synthetic resin material formed in a sheet-like shape. In this case, the ventilation portions 66 are formed by gaps formed in the material. As the mesh or net material for the main body 65, PFA, another fluororesin, polyimide, glass fiber, or the like can be used. The diameter of the material in this case desirably falls within the range of about 0.03 mm to about 0.5 mm, and the formation pitch desirably falls within the range of about 0.1 mm to about 1.5 mm. The material used to form the non-metal sheet 62 may be a resin foam.
Number | Date | Country | Kind |
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2015-114514 | Jun 2015 | JP | national |