JP7050197B2 - Printing equipment - Google Patents

Description

The present invention relates to a printing apparatus.

Patent Document 1 discloses a printing apparatus in which inkjet printing is performed at at least one inkjet printing station and a plurality of inkjet heads are arranged in the inkjet printing station.

Japanese Unexamined Patent Publication No. 2012-232771

In the printing apparatus, the moving body holding the can body may be moved, but if the weight of the moving body is large, the moving speed of the moving body is lowered, and the printing efficiency is likely to be lowered. Further, if the weight of the moving body is large, the inertial force when the moving body is stopped becomes large, and the moving body may stop at a position different from the originally planned position.
An object of the present invention is to reduce the weight of a moving body that moves while holding a can body.

The printing apparatus to which the present invention is applied is provided with a drive mechanism for rotating the can body, and is a printing unit that prints on a moving body that moves while supporting the can body and a can body supported by the moving body. A drive source that is provided at a position different from the moving body and generates a driving force used by the driving mechanism of the moving body, and a driving force generated by the driving source to the driving mechanism of the moving body. The transmission mechanism comprises a transmission mechanism for transmitting, and the transmission mechanism contacts the drive mechanism of the moving body to transmit a driving force to the drive mechanism, sandwiches the drive mechanism of the moving body, and installs the transmission mechanism. It is a printing apparatus further provided with a support member for supporting the drive mechanism from the opposite side to the above.
Further, the printing apparatus to which the present invention is applied is provided with a drive mechanism for rotating the can body, and prints on a moving body that moves while supporting the can body and a can body supported by the moving body. The printing unit is provided at a position different from the moving body, and the driving source that generates the driving force used by the driving mechanism of the moving body and the driving force generated by the driving source are used to drive the moving body. It is a printing apparatus including a transmission mechanism for transmitting to the mechanism and an advancing / retreating means for advancing / retreating the transmission mechanism with respect to the driving mechanism of the moving body.

According to the present invention, it is possible to reduce the weight of a moving body that moves while holding the can body.

It is a top view of the printing apparatus. It is sectional drawing of the moving unit, the moving mechanism and the like in line II-II of FIG. It is a figure which showed the other structural example of a printing part and a moving unit. (A), (B), and (C) are diagrams showing other configuration examples of the printing unit. It is a figure which showed the other structural example of a mandrel drive mechanism. (A) and (B) are diagrams for explaining the can body charging portion. 6 is an enlarged view of a portion indicated by reference numeral 6A in FIG. 6A. (A) and (B) are diagrams for explaining the can body discharging portion. It is a figure which showed the other structural example of a printing part. (A) and (B) are diagrams showing other arrangement examples of inkjet heads. It is a figure which showed the other configuration example of a printing apparatus. It is a figure which showed the other configuration example of a printing apparatus. It is a figure which showed the other configuration example of a printing apparatus. It is a figure which showed the other configuration example of a printing apparatus. It is sectional drawing of the XV-XV line of FIG. It is a schematic diagram when looking at two adjacent inkjet heads.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a top view of the printing apparatus 500.
The printing device 500 includes a can body charging unit 510 into which the can body 10 is loaded, a printing unit 520 that prints on the loaded can body 10, a drying unit 530 that dries the printed can body 10, and drying. A can body discharge unit 540 for discharging the finished can body 10 is provided.
Further, the printing apparatus 500 is provided with a plurality of moving units 550 that move while supporting the can body 10, and a moving mechanism 560 that functions as a part of moving means for moving the moving unit 550. The moving mechanism 560 is formed in an annular shape.

The printing unit 520 is provided with a plurality of inkjet heads arranged side by side in the left-right direction in the drawing. Each of the inkjet heads can be regarded as an image forming unit that forms an image on the can body 10, and in the present embodiment, the printing unit 520 is provided with a plurality of image forming units.

Specifically, the printing unit 520 includes a first inkjet head 11W that ejects white ink, a second inkjet head 11C that ejects cyan ink, a third inkjet head 11M that ejects magenta ink, and yellow ink. A fourth inkjet head 11Y for ejecting black ink and a fifth inkjet head 11K for ejecting black ink are provided.
In the following description, when the first inkjet head 11W to the fifth inkjet head 11K are not particularly distinguished, they are simply referred to as "inkjet head 11".

Here, the five inkjet heads 11 of the first inkjet head 11W to the fifth inkjet head 11K use ultraviolet curable ink to form an image on the can body 10.
Further, in the present embodiment, in the process of the can body 10 passing below the five inkjet heads 11, ink is ejected from above with respect to the can body 10 and an image is formed on the can body 10. In other words, in the present embodiment, the moving unit 550 goes through each of the plurality of inkjet heads 11. In the process of this movement, ink is ejected from each inkjet head 11 to the can body 10, and an image is formed on the can body 10.
In this embodiment, the case where five inkjet heads 11 are provided is illustrated, but an inkjet head 11 for ejecting a special color ink such as a corporate color may be further provided.

The moving unit 550 as an example of the moving body moves at a predetermined moving speed, and the can body 10 on the moving body 550 rotates in the circumferential direction at a predetermined rotation speed.
Although five moving units 550 are shown in FIG. 1, more than five moving units 550 are installed in the printing apparatus 500, and these moving units 550 are circularly moved by the moving mechanism 560. I do.

In the present embodiment, the timing at which the can body 10 reaches each inkjet head 11 is predetermined, and each inkjet head 11 starts ejecting ink at the timing when the can body 10 reaches the inkjet head 11.
The first inkjet head 11W is used to form a positioning mark on the surface of the can body 10, and the second and subsequent inkjet heads 11 read the positioning mark to determine the ink ejection timing. You may decide.
Further, in the determination of the discharge timing using the positioning mark, the discharge timing may be determined by reading the dedicated mark, or by reading the barcode or the recycle mark.

The drying unit 530 is arranged on the downstream side of the printing unit 520, and irradiates the can body 10 with ultraviolet rays. As a result, the image formed on the outer peripheral surface of the can body 10 is cured. In the present embodiment, as described above, an image is formed on the can body 10 using an ultraviolet curable ink. The drying portion 530 irradiates the can body 10 with ultraviolet rays to cure the image on the can body 10.
A heat-curable ink may be used to form an image on the can body 10. In this case, heat is applied to the can body 10 in the drying portion 530, and the image on the can body 10 is displayed. It cures.

FIG. 2 is a cross-sectional view of the moving unit 550, the moving mechanism 560, and the like in line II-II of FIG.
The moving mechanism 560 is provided with a guide member 561 for guiding the moving unit 550. The guide member 561 has an upper surface 561A, an outer peripheral surface 561B, and a lower surface 561C. An electromagnet 562 is provided inside the guide member 561.

In this embodiment, the moving unit 550 is moved by using a linear mechanism.
As shown in FIG. 1, the printing apparatus 500 of the present embodiment is provided with a control unit 600 that functions as a part of a moving means for controlling the energization of the electromagnet 562 to move the moving unit 550. The control unit 600 is composed of a program-controlled CPU (Central Processing Unit).
In the transfer using the linear mechanism, the moving speed of the moving unit 550 can be easily changed. Further, in the transfer using the linear mechanism, the moving unit 550 can be retracted.

In the present embodiment, the moving unit 550 is stopped below each of the plurality of inkjet heads 11 to form an image on the can body 10. In each inkjet head 11, the moving unit 550 is moved with respect to the inkjet head 11. If the positioning accuracy of the unit 550 is poor (the accuracy of the stop position is poor), the images of each color formed on the can body 10 are displaced, and the quality of the formed images is deteriorated. When a linear mechanism is used as in the present embodiment, for example, the accuracy of the stop position can be set to 100 μm or less, and the deviation of the image of each color can be reduced. When high-definition printing is required, it is possible to obtain position accuracy of 50 μm to 100 μm or 10 μm to 30 μm by taking measures such as reducing the moving speed of the moving unit 550.

As shown in FIG. 2, the moving unit 550 is provided with a guided member 551 to be guided by the guide member 561.
The guided member 551 includes an upper facing portion 551A facing the upper surface 561A of the guide member 561, a side facing portion 551B facing the outer peripheral surface 561B of the guide member 561, and a lower facing portion 551C facing the lower surface 561C of the guide member 561. Is provided.
Further, a rotatable roll-shaped member 80 is installed between the guide member 561 and each of the upper facing portion 551A, the side facing portion 551B, and the lower facing portion 551C. The roll-shaped member 80 is fixed to the guided member 551. The roll-shaped member 80 reduces the sliding resistance between the guide member 561 and the guided member 551.

Further, each of the upper facing portion 551A and the lower facing portion 551C of the guided member 551 is provided with a unit side magnet 90 composed of a permanent magnet.
In the present embodiment, the magnetic field generated by the electromagnet 562 provided in the guide member 561 and the unit-side magnet 90 generate a propulsive force in the moving unit 550, and the moving unit 550 moves along the annular guide member 561. do.

Further, as shown in FIG. 2, the moving unit 550 has a mandrel 70 that supports the can body 10 and a support portion 75 that supports the mandrel 70. The support portion 75 is supported from below by the guided member 551. Inside the support portion 75, a mandrel motor M for rotating the mandrel 70 in the circumferential direction is provided.
The mandrel 70 is formed in a cylindrical shape. Further, the mandrel 70 is arranged in a lying state (a state along the horizontal direction). As a result, in the present embodiment, the can body 10 is also arranged in a lying state.

Further, in the present embodiment, as shown in FIG. 1, a plurality of mobile units 550 are provided. Further, the moving unit 550 passes through a region located below the plurality of inkjet heads 11.
Further, the moving unit 550 is stopped every time it reaches the lower part of each inkjet head 11. Further, in the present embodiment, the mandrel motor M (see FIG. 2) is driven, and the mandrel 70 (see FIG. 2) rotates in the circumferential direction. Further, the ink is ejected from the inkjet head 11.

Then, when the mandrel 70 rotates 360 ° after the ink ejection is started, the ink ejection is stopped. As a result, an image is formed on the outer peripheral surface of the can body 10.
The rotation of the mandrel 70 may be performed each time the mandrel 70 reaches the lower part of each inkjet head 11, or the moving unit 550 departs from the can body loading section 510 and reaches the can body discharging section 540. During that time, the mandrel 70 may be continuously rotated.

Here, in the present embodiment, as shown in FIG. 1, the mandrel 70 is arranged sideways. Specifically, the mandrel 70 is arranged along a direction orthogonal to (intersecting) the moving direction of the moving unit 550. In other words, in the present embodiment, the can body 10 is transported in a state where the axial direction of the can body 10 is orthogonal (crosses) to the moving direction of the moving unit 550.
In such a case, the length L of the printing apparatus 500 can be reduced as compared with the case where the mandrel 70 is arranged along the moving direction of the moving unit 550. In other words, the total length of the movement path to which the movement unit 550 moves can be reduced.

In this case, the manufacturing cost of the printing apparatus 500 can be reduced. In the case of the printing device 500 that prints in the process of moving the can body 10, the manufacturing cost of the printing device 500 tends to increase depending on the length of the moving path of the can body 10. In particular, in the case of linear transfer, the manufacturing cost becomes high.
When the mandrel 70 is arranged sideways as in the present embodiment, the moving path of the moving unit 550 can be shortened, and the manufacturing cost of the printing apparatus 500 can be reduced.
Further, when the mandrel 70 is arranged sideways, the arrangement density of the moving units 550 in the moving direction of the moving units 550 can be increased, and the number of movable units 550 that can be installed can be increased.

Further, in the present embodiment, as shown in FIG. 1, the mandrel 70 and the inkjet head 11 are arranged sideways and are provided so as to project outward in the radial direction of the guide member 561. In addition, the mandrel 70 and the inkjet head 11 are arranged so as to be closer to the outside than the inside in the radial direction of the guide member 561.

More specifically, in the present embodiment, the moving unit 550 moves along the annular movement path indicated by reference numeral 1A in the figure, and the can body 10 is outside the inner side in the radial direction of the annular movement path. It is arranged in a state of being brought close to.
Maintenance of the mandrel 70 and the inkjet head 11 may be performed. In such a case, when the mandrel 70 and the inkjet head 11 are moved to the outside as in the present embodiment, the mandrel 70 and the inkjet head 11 are moved to the inside as compared with the case where the mandrel 70 and the inkjet head 11 are moved to the inside. This maintenance will be easier.

Further, in the present embodiment, as described above, the inkjet head 11 is arranged above the can body 10, and ink is ejected from above to the can body 10.
In this case, the influence of gravity acting on the ink droplets ejected from the inkjet head 11 can be reduced as compared with the case where the inkjet head 11 is arranged on the side of the can body 10 or below the can body 10. The accuracy of the ink adhesion position on the can body 10 can be improved.

In FIG. 2, the case where the mandrel 70 and the inkjet head 11 are provided on the right side of the support portion 75 in the figure is shown, but as shown by reference numeral 2A in FIG. 2, the support portion 75 is on the left side in the figure. , Mandrel 70 and inkjet head 11 may be provided.
Further, the mandrel 70 and the inkjet head 11 may be provided on both the right side and the left side of the support portion 75 in the drawing.

When the mandrel 70 and the inkjet head 11 are provided on the right side and the left side of the support portion 75 (on both sides of the support portion 75), the unit time is compared with the case where the mandrel 70 and the inkjet head 11 are provided only on one side of the support portion 75. The number of cans 10 that can be printed can be increased.
Further, when the mandrel 70 is provided on both sides of the support portion 75, the balance between the left and right sides (left and right in FIG. 2) of the moving unit 550 is improved, and the movement unit 550 can be suppressed from tilting due to the weight of the mandrel 70.

When mandrel 70s are provided on both sides of the support portion 75, a mandrel motor M may be provided corresponding to each mandrel 70 (a mandrel motor M may be provided for each mandrel 70). One mandrel motor M may rotate two mandrel 70s located on both sides (a plurality of mandrel 70s may be rotated).
Here, when rotating two mandrel 70s with one mandrel motor M, for example, a transmission gear is installed between the mandrel motor M and the two mandrel 70s, and the rotational driving force from the mandrel motor M is provided. Is transmitted to each mandrel 70.

When the mandrel 70 is provided on both sides of the support portion 75, the orientation of the can body 10 mounted on the mandrel 70 is different. The two mandrel 70s located on both sides of the support portion 75 have different directions in which the tip portion of the mandrel 70 faces, and in such a case, the orientation of the can body 10 to be mounted is also different.
Further, depending on the configuration of the transmission gear described above, the two can bodies 10 may rotate in the same direction or in opposite directions.

In such a case, if the ejection control of the two inkjet heads 11 provided corresponding to the two can bodies 10 is performed with the same control, the image formed for one can body 10 is originally formed. The image may be different from the planned image.
Therefore, when the mandrel 70 is provided on both sides of the support portion 75, the image data matched to the direction and rotation direction of the mandrel 70 is obtained by performing image processing such as rotation processing and inversion processing of the image data used for printing. It is generated, and an image is formed on the can body 10 using this image data.

Next, the moving mechanism 560 will be described.
As shown in FIG. 1, the guide member 561 provided in the moving mechanism 560 is formed in an annular shape. Further, the guide member 561 has a first curved portion 571 having a curvature, a first straight portion 571 formed linearly, a second curved portion 573 having a curvature, and a second straight portion 574 formed linearly. To prepare for.

The first straight line portion 572 and the second straight line portion 574 are arranged so as to be parallel to each other. Further, the first straight line portion 572 and the second straight line portion 574 are arranged so as to face each other.
Further, the first curved line portion 571 connects one end portion of the first straight line portion 572 and one end portion of the second straight line portion 574. Further, the second curved portion 573 connects the other end portion of the first straight line portion 572 and the other end portion of the second straight line portion 574.
In the present embodiment, the can body charging portion 510 is provided in the first curved portion 571. Further, the first straight line portion 572 is provided with a printing portion 520 and a drying portion 530. Further, the second curved portion 573 is provided with a can body discharging portion 540.

FIG. 3 is a diagram showing another configuration example of the printing unit 520 and the moving unit 550.
In this configuration example, one moving unit 550 is provided with three (plural) mandrel 70s, and each moving unit 550 moves while holding three cans 10.
Further, the printing unit 520 is provided with three inkjet heads 11 of the same color corresponding to the three mandrels 70. Specifically, three inkjet heads 11 are provided for each color.
In FIG. 3, the yellow fourth inkjet head 11Y and the black fifth inkjet head 11K are not shown, but the yellow fourth inkjet head 11Y and the black fifth inkjet head 11K also have three pieces. Inkjet head 11 is provided.

In this configuration example shown in FIG. 3, each moving unit 550 is stopped below the three inkjet heads 11 provided for each color.
Then, in each moving unit 550, three mandrel 70s (can bodies 10) are rotated, and ink is ejected from three inkjet heads 11 that eject ink of the same color to each can body 10. Is done. As a result, an image is formed on the outer peripheral surface of the can body 10 as described above.

In the configuration example shown in FIG. 3, the printing efficiency can be improved as compared with the configuration of FIG. 1 in which printing is performed each time the moving unit 550 reaches the adjacent inkjet head 11.
Further, in this configuration example, ink is ejected at the same timing by each of the three inkjet heads 11 that eject ink of the same color. As a result, the processing can be simplified as compared with the configuration in which the ink ejection timings of the inkjet heads 11 are different from each other.

When a plurality of mandrel 70s are installed in the mobile unit 550, the number of mandrel 70s installed is preferably 2 to 8. When the number of mandrel 70s is 9 or more, the weight of the moving unit 550 becomes large, and it may be difficult to control the position of the moving unit 550.
Specifically, when the weight of the moving unit 550 increases, the inertial force of the moving unit 550 when the moving unit 550 stops increases, and the stop position of the moving unit 550 tends to deviate from the original position.
When a plurality of mandrel 70s are installed in the mobile unit 550, the preferred number of mandrel 70s to be installed is 2 to 4.

4 (A), (B), and (C) are views showing other configuration examples of the printing unit 520.
4 (A) is a top view, FIG. 4 (B) is a view when the printing unit 520 is viewed from the arrow IVB direction of FIG. 4 (A), and FIG. 4 (C) is a view. It is a figure when the printing part 520 is seen from the arrow IVC direction of FIG. 4A.

In the configuration example shown in FIG. 4, the mandrel motor M is not provided in the moving unit 550.
In this configuration example, as shown in FIG. 4B, the mandrel 70 provided in each moving unit 550 is driven by a mandrel driving mechanism 20 provided in a place different from the moving unit 550.
The mandrel drive mechanism 20 includes a belt member 21 that is formed in an endless shape and circulates, a drive roll 22 that is contact-arranged with the belt member 21 to rotate the belt member 21, and a belt motor 23 that rotates the drive roll 22. And prepare. Further, although not shown, the mandrel drive mechanism 20 includes a tension roll for tensioning the belt member 21 from the inside.
Here, the belt motor 23 as an example of the drive source generates a driving force for rotating the can body 10 supported by the moving unit 550. This driving force is transmitted to the can body 10 via the belt member 21 and the like.

As shown in FIG. 4C, the belt member 21 is contact-arranged with the mandrel 70. More specifically, each moving unit 550 is provided with a gear coaxially arranged with the mandrel 70 (hereinafter referred to as "mandrel side gear 71"), and the belt member 21 is the mandrel side gear. It meshes with 71.
A gear (concave and convex portion) is formed on the outer peripheral surface of the belt member 21, and in the present embodiment, this gear of the belt member 21 meshes with the mandrel side gear 71, and the belt member 21 that circulates to the mandrel 70. The rotational driving force is transmitted.

In the present embodiment, when the moving unit 550 reaches the printing unit 520 (see FIG. 4B), the mandrel side gear 71 provided in the moving unit 550 comes into contact with the belt member 21, and the mandrel side gear 71 and the belt member. Engagement with 21 occurs. This allows the mandrel 70 to rotate in the circumferential direction.

In other words, in the present embodiment, the mandrel side gear 71 and the mandrel 70 function as a drive mechanism for rotating the can body 10, and the drive roll 22 and the belt member 21 have a driving force generated by the belt motor 23. Functions as a transmission mechanism that transmits the above to this drive mechanism. In the present embodiment, the mandrel side gear 71 that functions as a part of the drive mechanism comes into contact with the belt member 21 that functions as a part of the transmission mechanism, so that the mandrel 70 is rotated in the circumferential direction.

In this embodiment, as shown in FIG. 4C, the belt member 21 contacts the upper portion of the mandrel side gear 71, but the belt member 21 contacts the lower portion of the mandrel side gear 71. It may be configured to be used.
Further, in the present embodiment, as shown in FIG. 4B, the mandrel side gear 71 comes into contact with the outer peripheral surface of the belt member 21, but the mandrel side gear 71 comes into contact with the inner peripheral surface of the belt member 21. May be good. In this case, the size of the printing device 500 can be reduced as compared with the case where the mandrel side gear 71 comes into contact with the outer peripheral surface of the belt member 21.
Further, in the present embodiment, the configuration of the printing unit 520 has been described, but the mandrel drive mechanism 20 is also provided in the drying unit 530 (see FIG. 1) and the like, and even in the drying unit 530 and the like, the can body 10 is rotated. Rotate in the direction.

In the configuration example shown in FIG. 4, the accuracy of the stop position of the moving unit 550 can be improved, and the number of drive sources can be further reduced.
When the mandrel motor M is installed in each of the moving units 550, the gravity of the moving unit 550 increases, and the inertial force when the moving unit 550 stops increases. In such a case, the accuracy of the stop position of the moving unit 550 may decrease.

On the other hand, in the present embodiment, a drive source is provided separately from the mobile unit 550, and the driving force is supplied to the mobile unit 550 from the outside of the mobile unit 550.
In such a configuration, the weight of the moving unit 550 can be reduced, and the inertial force when the moving unit 550 is stopped becomes small. Then, in this case, the accuracy of the stop position of the moving unit 550 can be improved.

Further, in the configuration in which the mandrel motors M are provided in each of the mobile units 550, the mandrel motors M are provided in the number corresponding to the number of the mobile units 550, which causes an increase in the drive source and the manufacturing cost of the printing apparatus 500. Will increase.
On the other hand, in the configuration example shown in FIG. 4, the drive source is shared, and the number of drive sources can be reduced. In this case, the manufacturing cost of the printing apparatus 500 can be reduced.

In the present embodiment, the case where the belt member 21 extending along the moving direction of the moving unit 550 is installed to rotate each mandrel 70 has been described, but the rotation of each mandrel 70 uses other than the belt member 21. You may go there.
For example, a rotating gear (not shown) (hereinafter referred to as "rotating gear") is installed corresponding to each of the inkjet heads 11, and the mandrel side gear 71 is engaged with the rotating gear. , Each mandrel 70 may be rotated.
In this case, each rotary gear may be rotated by a common drive source, or may be rotated by a drive source prepared for each rotary gear.

The belt member 21 and each rotary gear may be rotated or stopped while the moving unit 550 is moving, and after the moving unit 550 is stopped below the inkjet head 11. , You may start the rotation.
When the belt member 21 is constantly rotated, a driving force is supplied from the belt member 21 to the mandrel 70 even when the moving unit 550 moves between the inkjet heads 11. In this case, the moving unit 550 moves while the mandrel 70 on the moving unit 550 rotates.

It should be noted that rotating a plurality of mandrel 70s with the belt member 21 improves the quality of the image formed on the can body 10 rather than rotating the mandrel 70 using a rotation gear individually provided for each mandrel 70. Easy to improve.
When a plurality of mandrel 70s are rotated by the belt member 21, the deviation of the position of the image of each color can be reduced, and the quality of the formed image can be improved.

When the rotary gear is provided corresponding to each mandrel 70, the mutual positions of the rotary gears may be displaced due to the dimensional tolerance of the members and the like. In such a case, the position of the mandrel 70 (the position of the mandrel 70 with respect to the inkjet head 11) when the mandrel side gear 71 meshes with the rotary gear tends to be different for each rotary gear with which the mandrel side gear 71 meshes. In such a case, the image of each color formed on the can body 10 is likely to be displaced.
On the other hand, when the continuous belt member 21 is used, since the mandrel 70 is synchronized, the position of the mandrel 70 is less likely to fluctuate, and the image of each color formed on the can body 10 is less likely to be displaced.

Other configuration examples will be further described.
In the configuration example shown in FIG. 5 (a diagram showing another configuration example of the mandrel drive mechanism 20), the belt member 21 that applies a rotational driving force to the mandrel side gear 71 both above and below the mandrel side gear 71 in the figure. Is installed.
In the case of the configuration example shown in FIG. 4C, the mandrel side gear 71 is pressed from above by the belt member 21, and the load that tilts the mandrel 70 acts on the mandrel side gear 71.

On the other hand, in the configuration example shown in FIG. 5, the mandrel side gear 71 is supported from below by the belt member 21 (lower belt member 21 in the figure) as an example of the support member, and FIG. 4C shows. Compared to the configuration shown, the mandrel 70 is less likely to be tilted.
In other words, in this configuration example shown in FIG. 5, the upper belt member 21 in the figure can be regarded as a transmission mechanism for transmitting the rotational driving force to the mandrel side gear 71. In this configuration example, the mandrel side gear 71 is sandwiched, and the mandrel side gear 71 is supported by the belt member 21 (lower belt member 21 in the drawing) from the side opposite to the installation side of the transmission mechanism. ..

Although the case where the belt member 21 is installed in both the upper part and the lower part of the mandrel side gear 71 in FIG. 5 is described, the rotary gear is installed in place of the belt member 21 (mandrel side gear). Rotating gears may be installed above and below the 71), and the rotating gear may be used to rotate the mandrel-side gear 71 and support the mandrel-side gear 71.

Further, the belt member 21 may be installed on one of the upper side and the lower side of the mandrel side gear 71 in the drawing, and the rotary gear may be installed on the other side.
Further, one of the two members (belt member 21 and rotary gear) arranged above and below the mandrel side gear 71 in the drawing does not apply a rotational driving force to the mandrel side gear 71. May be.
In this case, one of the members mainly supports the mandrel side gear 71. Further, in this case, one of the members is driven by the mandrel side gear 71 to rotate.

Further, as shown in FIG. 4B, an advancing / retreating mechanism 89 is provided as an example of advancing / retreating means for advancing / retreating the mandrel drive mechanism 20 with respect to the moving unit 550 (mandrel side gear 71). The mandrel drive mechanism 20 may be moved up and down to move the mandrel drive mechanism 20 forward and backward with respect to the moving unit 550.
Specifically, for example, while the moving unit 550 is moving (while the moving unit 550 is moving between the inkjet heads 11), the mandrel drive mechanism 20 is retracted upward. .. Then, when the moving unit 550 stops below the inkjet head 11, the mandrel drive mechanism 20 is lowered, and the belt member 21 of the mandrel drive mechanism 20 is brought into contact with the mandrel side gear 71.

In this case, the belt member 21 may be rotated after the belt member 21 comes into contact with the mandrel side gear 71, the belt member 21 may be constantly rotated, and the rotating belt member 21 may be moved to the mandrel side gear. It may be brought into contact with 71.
Further, in the configuration example shown in FIG. 4B, the configuration in which the entire mandrel drive mechanism 20 moves up and down has been described, but the portion (lower side of the belt member 21) indicated by reference numeral 4E in FIG. 4B has been described. It may be configured to move only the part located in) up and down.
Further, the same applies to the rotary gear, and the rotary gear may be moved up and down, the rotary gear may be brought into contact with the mandrel side gear 71, and the rotary gear may be retracted from the mandrel side gear 71.

When the mandrel side gear 71 of the moving unit 550 moving from the upstream side comes into contact with the circulating belt member 21 or the rotating rotating gear, the impact acting on the moving unit 550 becomes large or the mandrel side. Wear of the gear 71 and the like is likely to be promoted.
When the belt member 21 or the rotary gear comes into contact with the stopped moving unit 550 as in the present embodiment, the impact acting on the moving unit 550 can be made smaller, and the mandrel side gear 71 or the like can be made smaller. Wear can be suppressed.

In the configuration example shown in FIG. 4A, one inkjet head group is configured by three inkjet heads 11 provided for each color, and the spacing between the inkjet heads 11 is the head spacing L1. The separation distances of the inkjet head groups adjacent to each other are all the separation distance L2, and all the distances L1 between the inkjet heads 11 and the separation distances L2 of the inkjet head groups adjacent to each other are equal to each other.
In this case, each inkjet head 11 is positioned at equal intervals, and the moving distance when moving each moving unit 550 to the adjacent inkjet head group becomes equal in each moving unit 550, and the moving unit 550 is moved. The control when making it can be simplified.
Here, it is preferable that the head distance L1 and the distance distance L2 are the shortest distances within a range in which the can bodies 10 and the inkjet heads 11 do not interfere with each other, because the above-mentioned moving distance is the shortest.
Further, at this time, for example, when the can body 10 moves from the position of the inkjet head 11W to the position of the inkjet head 11C, in other words, when the can body 10 moves a distance of (2 × L1 + L2), the inkjet head 11W It is preferable that the rotation speed of the can body 10 is set so that the printing start point of the can body 10 is located at a position facing the inkjet head 11C. Then, at the position of the inkjet head 11C, there is no waiting time until the printing start point of the can body 10 comes to the position facing the inkjet head 11C due to rotation.

6 (A) and 6 (B) are views for explaining the can body charging unit 510. FIG. 7 is an enlarged view of a portion indicated by reference numeral 6A in FIG. 6 (A).
As shown in FIG. 6A, the can body charging portion 510 of the present embodiment is provided in the first curved portion 571 of the moving mechanism 560.
The can body 10 that has not yet been printed is sequentially conveyed to the can body charging unit 510 by the transport mechanism 400. Then, as shown by arrow 6B in FIG. 6A, the can body 10 is extruded toward the mandrel 70 provided in the moving unit 550 (extruded by an extrusion mechanism (not shown), and the can body 10 is extruded. The mandrel 70 is inserted inside. As a result, the mandrel 70 starts to support the can body 10.

In the can body charging portion 510, air in the mandrel 70 is sucked from the rear end side of the mandrel 70 (the end side opposite to the tip end where insertion into the can body 10 is started). When the can body 10 is attached to the mandrel 70, the can body 10 is sucked by the mandrel 70.
Specifically, as shown in FIG. 7, a suction device 410 is provided in the can body charging section 510, and in the can body loading section 510, the suction device 410 is connected to the moving unit 550. The air inside the mandrel 70 is sucked by this suction device 410. As a result, the can body 10 is sucked by the mandrel 70, and the mandrel 70 enters the inside of the can body 10.
As shown in FIG. 6B, when a plurality of mandrel 70s are provided in the mobile unit 550, the number of cans 10 corresponding to the number of installed mandrels 70 is advanced toward the mandrel 70. Let me.

8 (A) and 8 (B) are views for explaining the can body discharging unit 540.
As shown in FIG. 8A, the can body discharging portion 540 is provided in the second curved portion 573 of the moving mechanism 560.
In the can body discharge unit 540, compressed air is supplied into the mandrel 70 from the rear end side of the mandrel 70 by using an air supply device (not shown). As a result, the can body 10 is pressed by the compressed air, and the can body 10 comes off from the mandrel 70. The can body 10 detached from the mandrel 70 is transported to the next step by a transport mechanism (not shown).
As shown in FIG. 8B, when a plurality of mandrel 70s are provided in the mobile unit 550, compressed air is supplied into each mandrel 70 to remove the can body 10 from all the mandrel 70s. Remove.

Here, in the present embodiment, as shown in FIG. 1, the printing unit 520 is provided in the first straight line unit 572 of the moving mechanism 560. If the printing unit 520 is provided on the first curved section 571 or the second curved section 573, the position of the can body 10 with respect to the inkjet head 11 is likely to fluctuate, and the quality of the formed image may deteriorate.
On the other hand, when the printing unit 520 is provided in the first straight line unit 572, an image is formed on the can body 10 in the process of the moving unit 550 moving linearly. In this case, the position of the can body 10 with respect to the inkjet head 11 is less likely to fluctuate, and the deterioration of the quality of the image formed on the can body 10 can be suppressed.

FIG. 9 is a diagram showing another configuration example of the printing unit 520.
In this configuration example, a plurality of inkjet heads 11 are arranged on one mandrel 70 (can body 10). Specifically, three mandrel 70s are arranged in the moving unit 550 located on the most upstream side in the figure.
Two inkjet heads 11 of a white first inkjet head 11W and a cyan second inkjet head 11C are installed above each mandrel 70 included in the three mandrel 70s.

Further, in the moving unit 550 located second from the upstream side in the figure, two inkjet heads 11 of magenta's third inkjet head 11M and yellow's fourth inkjet head 11Y are located above each of the three mandrel 70s. is set up.
In the moving unit 550 located on the most downstream side, a black fifth inkjet head 11K is installed above each of the three mandrel 70s. At this time, when the inkjet head 11 for ejecting special color ink such as corporate color is provided, it may be installed at the position of the moving unit 550 located on the most downstream side together with the black fifth inkjet head 11K.

In this configuration example, an image is formed by using a plurality of inkjet heads 11 for one can body 10 in this way. Further, in this configuration example, an image is formed using inks of the same color for each of the plurality of can bodies 10 provided in one moving unit 550.
Specifically, for example, in the moving unit 550 located on the most upstream side in the figure, three can bodies 10 are provided, but in these three can bodies 10, any can body 10 is used. However, the image is formed using two color inks of white and cyan.

In the configuration example shown in FIG. 1, it is necessary to stop and restart the movement unit 550 each time an image for one color is formed, and it is necessary to stop and restart the movement five times in total. be. In the configuration example shown in FIG. 9, it is sufficient to stop and restart the movement three times, and the printing efficiency can be improved.

In FIG. 9, a case where two inkjet heads 11 are installed on one mandrel 70 has been described as an example, but FIG. 10 (A) of FIG. 10 (a diagram showing another arrangement example of the inkjet heads 11). , (B), three or more inkjet heads 11 may be installed on one mandrel 70 (can body 10).
Further, when a plurality of inkjet heads 11 are installed on one mandrel 70 in this way, as shown in FIGS. 10A and 10B, the plurality of inkjet heads 11 are mounted on the mandrel 70 (). An advance / retreat mechanism 800 for advancing / retreating the can body 10) may be provided.

More specifically, in the present embodiment, as shown by the arrow 10A in FIG. 10A, the can body 10 (mandrel 70) moves along the horizontal direction and linearly. In this case, the can body 10 (mandrel 70) moves in a horizontal direction and linearly. There is a possibility that the inkjet head 11 on the most upstream side (inkjet head 11 represented by reference numeral 10B) and the can body 10 interfere with each other.
In order to avoid this interference, the can body 10 may be moved so as to pass through a portion away from the inkjet head 11 as shown by the arrow 10C. In this case, the can body 10 is separated from the inkjet head 11. , Image quality may deteriorate.

On the other hand, if the advancing / retreating mechanism 800 is provided, interference between the inkjet head 11 and the can body 10 can be avoided, and the can body 10 can be arranged near the inkjet head 11.
Explaining in detail the processing by the advancing / retreating mechanism 800, when the can body 10 is conveyed, the inkjet head 11 is moved in the direction indicated by the arrow 10X in FIGS. 10A and 10B, and the can body 10 is moved. The inkjet head 11 is retracted to a side away from the moving path.

Then, when the can body 10 stops below the inkjet head 11, the inkjet head 11 is advanced to the can body 10 as shown by the arrow 10Y. After that, the ink is ejected from the inkjet head 11 to form an image on the can body 10.
When the image formation is completed, the inkjet head 11 is moved in the direction indicated by the arrow 10X, and the inkjet head 11 is retracted. Then, the transportation of the can body 10 is restarted.
As a result, interference between the inkjet head 11 and the can body 10 can be avoided, and the inkjet head 11 can be arranged near the can body 10.
The advancing / retreating mechanism 800 can be configured by a known technique, and can be configured by using, for example, a motor or a solenoid.

Although the case where the inkjet head 11 is moved (moved up and down) has been described in FIG. 10, the can body 10 may be moved up and down.
Further, as shown in FIG. 10B, when five inkjet heads 11 are installed above one can body 10, printing on the can body 10 is completed only by rotating the can body 10 once. be able to.

FIG. 11 is a diagram showing another configuration example of the printing apparatus 500.
In this configuration example, the moving mechanism 560 is formed in a substantially rectangular shape.
Further, in this configuration example, an abnormality detection unit 511 and an abnormality product discharge unit 512 are provided between the can body charging unit 510 and the printing unit 520. Further, an outer surface coating portion 535 is provided between the drying portion 530 and the can body discharging portion 540.

The abnormality detection unit 511 detects an abnormality in the can body 10. More specifically, an abnormality such as a shape, a scratch or a dent of the can body 10 or an abnormality in mounting of the can body 10 is detected. For example, when a part of the can body 10 protrudes outward from the outer peripheral surface of the can body 10, this protrusion is detected, and it is detected that there is an abnormality in the can body 10.
For example, a so-called transmissive sensor is installed in the abnormality detection unit 511, and a light emitting unit and a light receiving unit are provided. When the can body 10 has a protruding portion as described above, the protruding portion blocks the light from the light emitting portion to the light receiving portion. As a result, an abnormality in the can body 10 is detected. Similarly, scratches and dents on the can body 10 or abnormal mounting of the can body 10 may be detected by using various sensors.

The abnormal product discharge unit 512 is configured in the same manner as the can body discharge unit 540, and when an abnormal can body 10 is transported, compressed air is supplied to the inside of the mandrel 70 holding the can body 10. do. As a result, the can body 10 is removed from the mandrel 70. The can body 10 (the can body 10 having an abnormality) that is detached from the mandrel 70 is transported to a predetermined location by a transport mechanism (not shown).
The outer surface coating portion 535 applies paint to the outer peripheral surface of the can body 10 to form a protective layer on the outer peripheral surface of the can body 10. The outer surface coating portion 535 is provided with a roller (not shown) that contacts the outer peripheral surface of the can body 10, and the roller is used to apply paint to the outer peripheral surface of the can body 10 to form a protective layer. ..

FIG. 12 is a diagram showing another configuration example of the printing apparatus 500.
In this configuration example, two sets of basic configurations including a can body charging unit 510, a printing unit 520, a drying unit 530, and a can body discharging unit 540 are provided. Thereby, in this configuration example, the number of cans 10 that can be printed per unit time can be increased.
Specifically, the basic configuration of the first set (can body loading section 510, printing section 520, drying section 530, can body discharging section 540) is located above the straight line 12A extending in the left-right direction in the figure. ing.
Here, as in the above, in the basic configuration of the first set, the can body charging section 510 is located in the first curved section 571, and the printing section 520 and the drying section 530 are located in the first straight line section 572. The can body discharging portion 540 is located at the second curved portion 573.

Further, the second set of basic configurations (can body loading section 510, printing section 520, drying section 530, can body discharging section 540) is located below the straight line 12A in the figure.
Here, in this second set of basic configurations, the can body charging section 510 is located in the second curved section 573, the printing section 520 and the drying section 530 are located in the second straight line section 574, and the can body discharging section. 540 is located at the first curved portion 571.

In this configuration example shown in FIG. 12, as a result of providing two sets of basic configurations, the number of cans 10 that can be printed per unit time is also doubled.
In this configuration example, the case where two sets of basic configurations are provided has been described, but this is an example, and three or more sets of basic configurations may be provided. Further, the abnormality detection unit 511, the abnormality product discharge unit 512, and the outer surface coating unit 535 shown in FIG. 11 may be installed in each of the basic configurations.

FIG. 13 is a diagram showing another configuration example of the printing apparatus 500.
In the configuration example described above, the guide member 561 is installed over the entire circumference of the circuit path in which the moving unit 550 moves, and the moving unit 550 is moved over the entire circumference by using a linear mechanism.
By the way, the installation range of the moving mechanism 560 (guide member 561) is not limited to the entire circumference, and may be a part of the circumferential route as shown in FIG. In this configuration example shown in FIG. 13, a part of the moving mechanism 560 is replaced with a belt transport device 750. In other words, in this configuration example, the printing unit 520 and the like use a linear mechanism to move the moving unit 550, but the second straight line unit 574 moves the moving unit 550 without using the linear mechanism.

The belt transport device 750 is provided with a circulation belt 751 that circulates and moves, a tension roll (not shown) for tensioning the circulation belt 751, and a drive motor (not shown) for rotating the tension roll.
Further, a moving rail 750C is provided between the upstream portion 750A of the belt transport device 750 and the moving mechanism 560, and between the downstream portion 750B of the belt transport device 750 and the moving mechanism 560.

In this configuration example, when the moving unit 550 moves to the upstream side of the belt transport device 750, the moving rail is inside the U-shaped guided member 551 (see FIG. 2) provided in the moving unit 550. 750C enters. Then, the moving unit 550 is guided by the moving rail 750C, and the moving unit 550 moves to the belt transport device 750. Then, the moving unit 550 is placed on the circulation belt 751.

Then, the moving unit 550 is moved to the right in the drawing by the circulation belt 751, and then supported again by the guide member 561 of the moving mechanism 560.
Specifically, the moving unit 550 is first supported by the moving rail 750C after moving to the right in the figure while being mounted on the circulation belt 751. Next, the moving unit 550 is guided by the moving rail 750C, and the moving unit 550 reaches the moving mechanism 560. Then, the moving unit 550 is supported again by the guide member 561 provided in the moving mechanism 560.

In the printing unit 520 and the like, it is necessary to control the position of the moving unit 550, but in a place where the functional unit is not particularly installed such as the second straight line unit 574, it is not necessary to control the position of the moving unit 550. .. Further, since the moving mechanism 560 moves the moving unit 550 using a linear mechanism, if the moving mechanism 560 is provided on the entire circumference, the manufacturing cost of the printing apparatus 500 increases.
Therefore, in this configuration example, the moving mechanism is located at a location opposite to the location where the printing unit 520 is provided (at a location where the functional unit for processing the can body 10 is not provided). A part of 560 is replaced with a cheaper belt transfer device 750.

Although the case where the belt transfer device 750 is installed only in the second straight line portion 574 is described in FIG. 13, the belt transfer device 750 may be provided in the first curved section 571 and the second curved section 573. Further, for example, in the first straight line portion 572 and the second straight line portion 574, the moving unit 550 is moved by using the linear mechanism, and in the first curved line portion 571 and the second curved line portion 573, the belt transport device 750 is used. The moving unit 550 may be moved.

FIG. 14 is a diagram showing another configuration example of the printing apparatus 500. FIG. 15 is a cross-sectional view taken along the line XV-XV of FIG. Note that FIG. 14 shows a state when the printing device 500 is viewed from the side of the printing device 500. Further, in FIG. 14, the illustration of the mandrel drive mechanism 20 shown in FIG. 4 is omitted.

As shown in FIG. 14, in this configuration example, the printing apparatus 500 is arranged vertically. Specifically, in the printing apparatus 500, the first straight line portion 572 is located above and the second straight line portion 574 is located below the first straight line portion 572.
Although the printing device 500 placed horizontally is shown in FIG. 1 and the like, the printing device 500 is not limited to the horizontal placement and may be installed vertically as shown in FIG.

When the printing device 500 is installed vertically, as shown in FIG. 15, the moving unit 550 is placed on the outer peripheral surface 561B of the guide member 561 provided in the moving mechanism 560 when the moving unit 550 is located in the first straight line portion 572. Become.
Further, the mandrel 70 on the moving unit 550 is arranged sideways as in FIG. 1 and as shown in FIG. Specifically, the mandrel 70 is arranged along a direction orthogonal to (intersecting) the moving direction of the moving unit 550.

When the printing apparatus 500 is arranged vertically as in this configuration example, the occupied area of the printing apparatus 500 is smaller than that when the printing apparatus 500 is arranged horizontally.
On the other hand, in the case of vertical installation, it becomes difficult to utilize the second straight line portion 574 (see FIG. 14). In the case of horizontal installation, as shown in FIG. 12, the printing unit 520 or the like can be installed in the second straight line portion 574, but in the case of vertical installation, the printing unit 520 or the like is installed in the second straight section 574. It becomes difficult.

Even in the vertical printing device 500, the various configurations described above can be applied to the vertical printing device 500.
For example, a configuration in which a plurality of mandrel 70s are installed in the mobile unit 550 (see FIG. 3A), a configuration in which the mandrel 70 is driven by an external drive source (see FIG. 4B), an abnormality detection unit 511, and the like. The configuration in which the abnormal product discharging unit 512 and the outer surface coating unit 535 are provided (see FIG. 11) can also be applied to the vertically installed printing apparatus 500.
Further, a configuration in which a plurality of sets of printing units 520 and the like are provided (see FIG. 12), a configuration in which a plurality of inkjet heads 11 are installed above one mandrel 70 (see FIG. 9), and a configuration in which the inkjet heads 11 advance and retreat (see FIG. 9). 10) and the like can also be applied to the vertical printing apparatus 500.

In addition, although the rotation speed of the can body 10 is not particularly mentioned in the above, the rotation speed of the can body 10 may be controlled.
Specifically, for example, after the movement of the can body 10 from one inkjet head 11 of the two inkjet heads 11 adjacent to each other in the moving direction of the can body 10 to the other inkjet head 11 is started, the other The rotation of the can body 10 may be controlled so that the number of rotations of the can body 10 until the can body 10 reaches the inkjet head 11 is an integer.

A specific description will be given with reference to FIG. 16 (schematic diagram when two adjacent inkjet heads 11 are viewed).
In the process shown in FIG. 16, the can body 10 is constantly rotating, and the inkjet head 11 located on the upstream side (the inkjet head on the right side in the figure, hereinafter referred to as “upstream inkjet head 11A”) When the can body 10 moves to the other inkjet head 11 located on the downstream side (the inkjet head 11 on the left side in the figure, hereinafter referred to as "downstream side inkjet head 11B"), the can body 10 moves while rotating.

In this process, the number of rotations of the can body 10 from the start of the movement of the can body 10 from the upstream inkjet head 11A to the arrival of the can body 10 at the downstream inkjet head 11B is an integer. It has become.
As a result, in the present embodiment, when the can body 10 reaches the downstream inkjet head 11B, the adhesion start position P1 to which the ink ejected from the upstream inkjet head 11A first adheres faces the downstream inkjet head 11B. Located in position.

Here, in the upstream inkjet head 11A, a strip extending from the adhesion start position P1 (position indicated by reference numeral 3A) to which the ink first adheres to the adhesion end position P2 (position also indicated by reference numeral 3A) to which the ink adheres last. The image of is formed on the outer peripheral surface of the can body 10.
Then, in the present embodiment, when the can body 10 moves while rotating and the can body 10 reaches below the downstream inkjet head 11B, the adhesion start position is located at the position facing the lower surface 241 of the downstream inkjet head 11B. P1 is located.

Then, in the present embodiment, the ink is ejected at the same time when the can body 10 reaches below the downstream inkjet head 11B to form an image.
More specifically, in the present embodiment, at the same time as the image formation is completed at the upstream inkjet head 11A (the can body 10 makes one rotation and the adhesion start position P1 faces the upstream inkjet head 11A again. At the same time), the movement of the can body 10 is started.
Then, at the same time that the can body 10 reaches below the downstream inkjet head 11B (at the same time that the adhesion start position P1 faces the downstream inkjet head 11B), ink ejection from the downstream inkjet head 11B is started. , Start image formation.

Here, in this process, when image formation is started by the downstream inkjet head 11B, the adhesion start position P1 is located directly below the downstream inkjet head 11B.
As a result, in the present embodiment, the image formation start position when the upstream inkjet head 11A starts image formation and the image formation start position when the downstream inkjet head 11B starts image formation coincide with each other. ..

Here, when the can body 10 reaches the downstream inkjet head 11B, if the adhesion start position P1 does not face the downstream inkjet head 11B, the adhesion start position P1 is directed toward the downstream inkjet head 11B. Control is required.
Specifically, for example, it is necessary to detect the state of the can body 10 with a rotary encoder or the like and rotate the can body 10 based on the detection result. On the other hand, in the present embodiment, such processing becomes unnecessary, and the image formation start position can be more easily aligned.
The number of rotations of the can body 10 from the start of the movement of the can body 10 from the upstream inkjet head 11A to the arrival of the can body 10 at the downstream inkjet head 11B is any integer. It may be a value of 1, it may be 1, or it may be 2 or more.

Further, as another process, when the can body 10 moves from one inkjet head 11 of two adjacent inkjet heads 11 to the other inkjet head 11, a predetermined rotation speed (rotation during image formation) is performed. The can body 10 may be rotated at a rotation speed larger than the number).
More specifically, when each of the inkjet heads 11 forms an image on the can body 10, the can body 10 is rotated at a predetermined rotation speed, and when the can body 10 is moved, the can body 10 is moved. (While moving the can body 10), the can body 10 may be rotated at a rotation speed higher than this predetermined rotation speed.

Here, when the rotation speed is increased in this way, the ink on the outer peripheral surface of the can body 10 is easily cured. More specifically, when, for example, a thermosetting ink is used instead of the ultraviolet curable ink as in the present embodiment, if the rotation speed increases, the ink becomes easier to dry and the rotation speed does not increase. Ink cures more quickly than in.
In addition, although the case where the ultraviolet curable ink is used has been described above, the thermosetting ink can also be used. In this case, if the rotation speed of the can body 10 is increased, the rotation speed is increased. The ink cures more quickly than when it is not allowed.

Further, as another process, when the can body 10 moves from one of the two inkjet heads 11 adjacent to each other to the other inkjet head 11, the rotation speed is smaller than the predetermined rotation speed. The can body 10 may be rotated.
More specifically, when the image is formed on the can body 10 by each of the inkjet heads 11, when the can body 10 is rotated at a predetermined rotation speed and the can body 10 is moved (). While the can body 10 is being moved), the can body 10 may be rotated at a rotation speed smaller than this predetermined rotation speed.
In this way, when the rotation speed of the can body 10 is lowered, the total rotation speed of each mechanism portion for rotating the can body 10 is reduced, and the rotation speed of each mechanism portion is constant or as described above. Compared to the case where it becomes large, the wear of each mechanical part is suppressed.

Further, in each inkjet head 11, the image formation is not started at the same time when the can body 10 reaches the inkjet head 11, but after the can body 10 is rotated a predetermined number of times below the inkjet head 11. , Image formation on the can body 10 may be started.

Immediately after the can body 10 is moved below each inkjet head 11, the can body 10 may vibrate without completely stopping. In particular, when the moving speed of the can body 10 is high, the vibration of the can body 10 tends to be large. When the can body 10 vibrates, the quality of the image formed on the can body 10 tends to deteriorate.
On the other hand, when the can body 10 is rotated below the inkjet head 11 and then the image formation by the inkjet head 11 is started (when the image formation by the inkjet head 11 is started after a certain period of time has elapsed), the can body is started. The vibration of the 10 is reduced or eliminated, and the deterioration of the quality of the image formed on the can body 10 is suppressed.

In addition, while the can body 10 reaches below the inkjet head 11 and rotates the can body 10 for a certain period of time, the rotation of the can body 10 is stopped or the rotation speed of the can body 10 is decelerated. May be good. However, in this case, when the image formation by the inkjet head 11 is started, it is necessary to accelerate the can body 10 which has been stopped or decelerated to the rotation speed required for the image formation, and at this time, the can body 10 vibrates. May occur.

Further, as another control, the image formation start position (position in the circumferential direction of the can body 10) when the inkjet head 11 starts image formation is made different for each inkjet head 11, and the image formation start position of each color is set. It may be shifted in the circumferential direction of the can body 10.
When the image formation start positions are aligned, the parts where the image quality tends to deteriorate are concentrated in one place, which may cause the image quality to deteriorate. More specifically, at the image formation start position, the start point and the end point of the formed image may overlap each other, or a gap may be formed between the start point and the end point, so that the image quality tends to deteriorate. In such a case, if the image formation start positions are aligned, the image quality is more likely to deteriorate as compared with the case where the image formation start positions are not aligned.

By making the image formation start position different for each inkjet head 11 and shifting the image formation start position of each color in the circumferential direction of the can body 10, deterioration of image quality can be suppressed.
The method of shifting the image formation start position by the inkjet head 11 is not particularly limited, but for example, the image formation start position is shifted by shifting the ink ejection timing of each inkjet head 11.

10 ... Can body, 11 ... Inkjet head, 21 ... Belt member, 22 ... Drive roll, 23 ... Belt motor, 70 ... Mandrel, 71 ... Mandrel side gear, 89 ... Advance / retreat mechanism, 90 ... Unit side magnet, 500 ... Printing Equipment, 520 ... printing unit, 550 ... moving unit, 560 ... moving mechanism, 562 ... electromagnet, 600 ... control unit

Claims (1)

A moving body that has a drive mechanism to rotate the can body and moves while supporting the can body,
A printing unit that prints on a can body supported by the moving body, and a printing unit.
A drive source that is provided at a location different from the moving body and generates a driving force used by the driving mechanism of the moving body.
A transmission mechanism that transmits the driving force generated by the driving source to the driving mechanism of the moving body, and
Equipped with
The transmission mechanism contacts the drive mechanism of the moving body and transmits a driving force to the drive mechanism.
A support member that sandwiches the drive mechanism of the moving body and supports the drive mechanism from a side opposite to the installation side of the transmission mechanism is further provided.
Printing equipment.

Images