JP7156198B2 - Gravure printing device and manufacturing method of multilayer ceramic capacitor - Google Patents

Description

The present invention relates to a gravure printing apparatus and a method of manufacturing a multilayer ceramic capacitor using the gravure printing apparatus.

2. Description of the Related Art A gravure printing apparatus is known in which a printing object is sandwiched between a plate roll and a drum roll to transfer ink filled in cells of the plate roll to the printing object for printing.

As one of such gravure printing apparatuses, Patent Document 1 discloses that each of a plurality of plate rolls is rotated and one drum roll is rotated in a state in which inks of different colors are stored in the cells of the plurality of plate rolls. A gravure printing apparatus is described that rotates to perform multicolor gravure printing on a print substrate. In this gravure printing apparatus, the rotation of the plate roll and the rotation of the drum roll are controlled so that the peripheral speeds of the plate roll and the drum roll are the same.

JP 2009-96189 A

Here, the drum roll preferably has a perfect circular cross-sectional shape when cut along a plane perpendicular to the rotation axis, but there are cases where the perfect circular shape is not obtained depending on the processing accuracy. In that case, since the peripheral speed varies depending on the position of the outer peripheral surface of the drum roll, the peripheral speed of the plate roll and the peripheral speed of the drum roll do not match at the position where the plate roll and the drum roll contact each other, and the printing accuracy decreases. A problem arises.

The present invention is intended to solve the above problems, and a gravure printing apparatus that can improve printing accuracy even when the cross-sectional shape of the drum roll is not a perfect circle, and a lamination using such a gravure printing apparatus. It is an object of the present invention to provide a method of manufacturing a ceramic capacitor.

The gravure printing apparatus of the present invention is
A gravure printing apparatus that performs printing by sandwiching a print target between a plate roll and a drum roll and transferring ink filled in cells formed on the outer peripheral surface of the plate roll to the print target. There is
a first printing plate roll formed with the cells having a shape corresponding to a figure to be printed on the outer peripheral surface;
the drum roll;
a first peripheral speed detection unit that detects the peripheral speed of the drum roll at a position where it contacts the first plate roll through the printing object;
A first method for adjusting the angular velocity of the first plate roll so that the peripheral speed of the drum roll detected by the first peripheral speed detection unit and the peripheral speed of the first plate roll match. an angular velocity adjustment unit;
with
The object to be printed is a ceramic green sheet formed on a carrier film,
the ink is at least one of a conductive paste and a ceramic paste;
An elastic member is disposed on at least a portion of the outer peripheral surface of the drum roll that comes into contact with the first plate roll through the print target .

The gravure printing device is
a second plate roll having, on its outer peripheral surface, the cells having a shape corresponding to a figure to be printed;
a second peripheral speed detection unit that detects the peripheral speed of the drum roll at a position where it contacts the second plate roll through the printing object;
A second method for adjusting the angular velocity of the second plate roll so that the peripheral speed of the drum roll detected by the second peripheral speed detection unit and the peripheral speed of the second plate roll match. an angular velocity adjustment unit;
may further include

The gravure printing device is
further comprising a third peripheral speed detection unit that detects a peripheral speed of the first plate roll at a position where the printing target is in contact with the drum roll,
The first angular velocity adjuster adjusts the peripheral velocity of the first plate roll detected by the third peripheral velocity detector and the peripheral velocity of the drum roll detected by the first peripheral velocity detector. may be configured to adjust the angular velocity of the first plate roll so that the difference between is zero.

The gravure printing device is
a third peripheral speed detection unit that detects a peripheral speed of the first plate roll at a position where the drum roll contacts the printing target;
a fourth peripheral speed detector that detects a peripheral speed of the second plate roll at a position where the drum roll contacts the printing target;
further comprising
The first angular velocity adjuster adjusts the peripheral velocity of the first plate roll detected by the third peripheral velocity detector and the peripheral velocity of the drum roll detected by the first peripheral velocity detector. Adjust the angular velocity of the first plate roll so that the difference between
The second angular velocity adjustment section adjusts the peripheral velocity of the second plate roll detected by the fourth peripheral velocity detection section and the peripheral velocity of the drum roll detected by the second peripheral velocity detection section. may be configured to adjust the angular velocity of the second plate roll so that the difference between is zero.

The gravure printing apparatus of the present invention is
A gravure printing apparatus that performs printing by sandwiching a print target between a plate roll and a drum roll and transferring ink filled in cells formed on the outer peripheral surface of the plate roll to the print target. There is
a first printing plate roll formed with the cells having a shape corresponding to a figure to be printed on the outer peripheral surface;
the drum roll;
a storage unit that stores peripheral speed data indicating the relationship between the rotational position of the drum roll and the peripheral speed of the drum roll;
a rotational position detection unit that detects the rotational position of the drum roll;
Based on the rotational position of the drum roll detected by the rotational position detection section and the peripheral speed data stored in the storage section, contact is made with the first plate roll via the print target. A first method for obtaining the peripheral speed of the drum roll at the position and adjusting the angular speed of the first plate roll so that the obtained peripheral speed of the drum roll and the peripheral speed of the first plate roll match. and an angular velocity adjustment unit of
with
The object to be printed is a ceramic green sheet formed on a carrier film,
the ink is at least one of a conductive paste and a ceramic paste;
An elastic member is disposed on at least a portion of the outer peripheral surface of the drum roll that comes into contact with the first plate roll through the print target .

The gravure printing device is
a second plate roll having, on its outer peripheral surface, the cells having a shape corresponding to a figure to be printed;
Based on the rotational position of the drum roll detected by the rotational position detection unit and the peripheral speed data stored in the storage unit, contact is made with the second plate roll via the print target. A second method for obtaining the peripheral speed of the drum roll at the position and adjusting the angular speed of the second plate roll so that the obtained peripheral speed of the drum roll matches the peripheral speed of the second plate roll. and an angular velocity adjustment unit of
may further include

The gravure printing device is
further comprising a third peripheral speed detection unit that detects a peripheral speed of the first plate roll at a position where the printing target is in contact with the drum roll,
The first angular velocity adjustment unit adjusts the peripheral speed of the first plate roll detected by the third peripheral speed detection unit and The angular velocity of the first plate roll may be adjusted so that the difference from the peripheral velocity of the drum roll becomes zero.

The gravure printing device is
a third peripheral speed detection unit that detects a peripheral speed of the first plate roll at a position where the drum roll contacts the printing target;
a fourth peripheral speed detector that detects a peripheral speed of the second plate roll at a position where the drum roll contacts the printing target;
further comprising
The first angular velocity adjustment unit adjusts the peripheral speed of the first plate roll detected by the third peripheral speed detection unit and Adjusting the angular velocity of the first plate roll so that the difference from the peripheral velocity of the drum roll is 0;
The second angular velocity adjustment unit adjusts the peripheral speed of the second plate roll detected by the fourth peripheral speed detection unit and The angular velocity of the second plate roll may be adjusted so that the difference from the peripheral velocity of the drum roll becomes zero.

The manufacturing method of the multilayer ceramic capacitor of the present invention comprises:
a step of forming an internal electrode pattern on the ceramic green sheet using the gravure printing apparatus according to any one of the above;
producing a laminate by laminating a plurality of the ceramic green sheets including the ceramic green sheet on which the internal electrode pattern is formed;
a step of firing the laminate;
A step of providing an external electrode on the laminated body after firing;
characterized by comprising

According to the gravure printing apparatus of the present invention, the peripheral speed of the drum roll at the position in contact with the first plate roll is detected, and the detected peripheral speed of the drum roll matches the peripheral speed of the first plate roll. Adjust the angular velocity of the first plate roll so that Therefore, even if the cross-sectional shape of the drum roll is not a perfect circle, it is possible to match the peripheral speeds at the contact positions of the first plate roll and the drum roll, thereby improving the printing accuracy.

Further, according to the method for manufacturing a laminated ceramic capacitor of the present invention, the internal electrode patterns are formed on the ceramic green sheets using the gravure printing apparatus described above, so that the internal electrode patterns can be formed at desired positions. , a desired multilayer ceramic capacitor can be manufactured.

It is a figure showing typically composition of the principal part of the gravure printing device in a 1st embodiment. It is a perspective view which shows the external appearance of a 1st plate roll typically. It is a sectional view of a drum roll. It is a figure for demonstrating an example of the method of printing on a printing target object using a gravure printing apparatus. FIG. 5 is a flowchart for explaining the procedure of a method for adjusting the angular velocity of the first plate roll when printing is performed by the gravure printing apparatus in the first embodiment; FIG. It is a figure which shows typically the structure of the principal part of the gravure printing apparatus in 2nd Embodiment. (a) is a diagram showing a state in which an internal electrode pattern is formed on a ceramic green sheet formed on a carrier film, and (b) is a diagram showing a state in which a ceramic paste pattern is formed around the internal electrode pattern. is. FIG. 10 is a flow chart for explaining a procedure of a method for adjusting the angular velocities of the first plate roll and the second plate roll when printing is performed by the gravure printing apparatus according to the second embodiment; FIG. It is a figure which shows typically the structure of the principal part of the gravure printing apparatus in 3rd Embodiment. FIG. 11 is a flow chart for explaining a procedure of a method for adjusting the angular velocity of the first plate roll when printing is performed by the gravure printing apparatus according to the third embodiment; FIG. It is a figure which shows typically the structure of the principal part of the gravure printing apparatus in 4th Embodiment. FIG. 11 is a flow chart for explaining procedures of a method for adjusting the angular velocities of the first printing roll and the second printing roll when printing is performed by the gravure printing apparatus according to the fourth embodiment; FIG. It is a figure which shows typically the structure of the principal part of the gravure printing apparatus in 5th Embodiment. (a) is a diagram showing the relationship between the rotational position of the drum roll and the peripheral speed of the drum roll at the peripheral speed measurement position; 1 is a diagram showing the relationship between the peripheral speed of a drum roll at a position in contact with a plate roll of No. 1. FIG. FIG. 12 is a flow chart for explaining a procedure of a method for adjusting the angular velocity of the first plate roll when printing is performed by the gravure printing apparatus according to the fifth embodiment; FIG. It is a figure which shows typically the structure of the principal part of the gravure printing apparatus in 6th Embodiment. FIG. 12 is a flow chart for explaining procedures of a method for adjusting the angular velocities of the first plate roll and the second plate roll when printing is performed by the gravure printing apparatus according to the sixth embodiment; FIG. It is a figure which shows typically the structure of the principal part of the gravure printing apparatus in 7th Embodiment. FIG. 12 is a flow chart for explaining a procedure of a method for adjusting the angular velocity of the first plate roll when printing is performed by the gravure printing apparatus according to the seventh embodiment; FIG. It is a figure which shows typically the structure of the principal part of the gravure printing apparatus in 8th Embodiment. FIG. 20 is a flowchart for explaining the procedure of a method for adjusting the angular velocities of the first printing roll and the second printing roll when printing is performed by the gravure printing apparatus according to the eighth embodiment; FIG. 4 is a flow chart for explaining a method of manufacturing a multilayer ceramic capacitor;

Embodiments of the present invention will be shown below to specifically describe features of the present invention.

The gravure printing apparatus of the present invention sandwiches the printing object between the plate roll and the drum roll, and prints by transferring the ink filled in the cells formed on the outer peripheral surface of the plate roll to the printing object. I do.

<First embodiment>
FIG. 1 is a diagram schematically showing the configuration of main parts of a gravure printing apparatus 10 according to the first embodiment. The gravure printing apparatus 10 includes a first plate roll 1, a drum roll 2, a first circumferential speed detector 3, a first angular speed adjuster 4, a first motor 5, and a drum roll motor 6. and

FIG. 2 is a perspective view schematically showing the appearance of the first plate roll 1. As shown in FIG. As shown in FIG. 2, the outer peripheral surface 1a of the first printing roll 1 is formed with a plurality of cells 11 having shapes corresponding to figures to be printed. During printing, the cells 11 are filled with ink. A first motor 5 drives the rotation of the first plate roll 1 .

FIG. 3 is a cross-sectional view of the drum roll 2. As shown in FIG. In this embodiment, the drum roll 2 includes a central portion 2a made of metal and an elastic member 2b provided so as to cover the central portion 2a. The elastic member 2b is provided at a portion of the outer peripheral surface of the drum roll 2 that comes into contact with the first plate roll 1 at least through the print target. The elastic member 2b is, for example, rubber. Rotational driving of the drum roll 2 is performed by a drum roll motor 6 .

It is preferable that the cross section of the drum roll 2 cut in the direction perpendicular to the rotation axis direction is a perfect circle, but due to processing accuracy, it may not be a perfect circle as shown in FIG. In this case, since the radius r _d of the drum roll 2 varies depending on the position on the outer peripheral surface, the peripheral speed on the outer peripheral surface also varies depending on the position.

FIG. 4 is a diagram for explaining an example of a method of printing on the print target 20 using the gravure printing apparatus 10. As shown in FIG. As shown in FIG. 4, a printing object 20 is sandwiched between a first plate roll 1 and a drum roll 2, and by rotating the first plate roll 1 and the drum roll 2 respectively, a cell 11 (Fig. 2) is transferred onto the object 20 to be printed. A pressure is applied to the first plate roll 1 by a pusher, which is a pressing member, so that the first plate roll 1 does not separate from the drum roll 2 .

The print target 20 is, for example, a ceramic green sheet formed on a carrier film. Ink filled in the cells 11 of the first printing roll 1 is, for example, a conductive paste for forming internal electrode patterns. Therefore, the ceramic green sheets on which the internal electrode patterns are formed are obtained by printing by the method described above. A ceramic green sheet on which an internal electrode pattern is formed is used, for example, for manufacturing a laminated ceramic capacitor, which is a laminated ceramic electronic component.

The first peripheral speed detection unit 3 detects the peripheral speed _Vd1 of the drum roll 2 at the position where it contacts the first plate roll 1 through the printing object 20 . As an example, the first peripheral speed detection unit 3 is provided with a camera, and a plurality of speed detection markers are provided on the outer peripheral surface of the drum roll 2 . Then, the speed detection marker is imaged by a camera, and the peripheral speed _Vd1 of the drum roll 2 at the position where it contacts the first plate roll 1 is detected based on the position of the speed detection marker in the imaged image.

However, the method for detecting the peripheral speed _Vd1 of the drum roll 2 at the position where it comes into contact with the first plate roll 1 is not limited to the method described above, and can be detected by any method. For example, a well-known Doppler speedometer may be used as the first peripheral speed detector 3 .

The first angular velocity adjuster 4 adjusts the first angular velocity so that the peripheral velocity V _h1 of the first plate roll 1 coincides with the peripheral velocity V _d1 of the drum roll 2 detected by the first peripheral velocity detector 3 . adjust the angular velocity ω _h1 of the plate roll 1 of . Since the rotation of the first plate roll 1 is performed by the first motor 5 , the first angular velocity adjustment unit 4 controls the first motor 5 to adjust the angular velocity ω Adjust _h1 .

Specifically, assuming that the radius of the cross section of the first plate roll 1 cut in the direction perpendicular to the rotation axis direction is r ₁ , the first angular velocity adjustment unit 4 adjusts the angular velocity of the first plate roll 1 The first motor 5 is controlled so that ω _h1 becomes V _d1 /r ₁ .

FIG. 5 is a flowchart for explaining the procedure of the method for adjusting the angular velocity of the first plate roll 1 when printing is performed by the gravure printing apparatus 10 according to the first embodiment.

In step S1, the rotation of the drum roll 2 is started so as to rotate at the angular velocity _ωd . For example, a controller (not shown) controls the drum roll motor 6 to rotate the drum roll 2 at an angular velocity _ωd .

In step S2 following step S1, the rotation of the first plate roll ₁ is started so as to rotate at an angular velocity ω1. For example, a controller (not shown) controls the first motor 5 to rotate the first plate roll 1 at an angular velocity ω ₁ .

In step S3 subsequent to step S2, the first circumferential speed detector 3 detects the circumferential speed _Vd1 of the drum roll 2 at the position where it contacts the first plate roll 1 through the printing object 20. FIG.

In step S4 subsequent to step S3, the peripheral speed V _h1 of the first printing roll 1 is detected by the first angular velocity adjusting unit 4, and the peripheral speed V _d1 of the drum roll 2 detected by the first peripheral speed detecting unit 3 is detected. The angular velocity ω _h1 of the first plate roll 1 is adjusted so as to match with . As described above, the first angular velocity adjuster 4 controls the first motor 5 so that the angular velocity ω _h1 of the first plate roll 1 becomes V _d1 /r ₁ .

In step S5 following step S4, if the rotation of the drum roll 2 continues, the process returns to step S3 and the process of adjusting the angular velocity _ωh1 of the first plate roll 1 is performed again. On the other hand, when the gravure printing is finished and the rotation of the drum roll 2 is stopped, the process of the flowchart is finished.

According to the gravure printing apparatus 10 of the first embodiment, the peripheral speed _Vd1 of the drum roll 2 at the position where it contacts the first plate roll 1 via the printing object 20 is detected, and the detected drum roll 2 The angular velocity of the first plate roll 1 is adjusted so that the peripheral speed _Vd1 of the first plate roll 1 coincides with the peripheral speed _Vh1 of the first plate roll 1 . Therefore, even if the cross-sectional shape of the drum roll 2 is not a perfect circle, the circumferential speeds at the contact positions of the first plate roll 1 and the drum roll 2 can be matched to improve the printing accuracy.

Further, in the structure in which the elastic member 2b is provided on the surface of the drum roll 2, even if the elastic member 2b is deformed, the peripheral speed Vh1 of the first plate roll 1 and the peripheral speed _Vd1 of the drum roll 2 are _maintained . Since they can be matched, the deformed elastic member 2b can be used as it is, and the cost can be reduced.

<Second embodiment>
FIG. 6 is a diagram schematically showing the configuration of main parts of a gravure printing apparatus 10A according to the second embodiment. A gravure printing apparatus 10A according to the second embodiment differs from the gravure printing apparatus 10 according to the first embodiment in that it includes a second plate roll 31, a second peripheral speed detector 32, and a second angular velocity Further provided is an adjustment unit 33 and a second motor 34 . Note that the first angular velocity adjustment section 4 and the second angular velocity adjustment section 33 may be configured as one angular velocity adjustment section.

A plurality of cells having shapes corresponding to figures to be printed are formed on the outer peripheral surface of the second printing roll 31 . During printing, the cells are filled with ink. Rotational drive of the second plate roll 31 is performed by a second motor 34 .

As described above, the printing object 20 is, for example, a ceramic green sheet formed on a carrier film, and the ink filled in the cells of the first printing roll 1 is a conductive material for forming the internal electrode pattern. It is a sexual paste.

FIG. 7(a) is a diagram showing a state in which an internal electrode pattern 43 is formed on a ceramic green sheet 42 formed on a carrier film 41 by the first plate roll 1. FIG.

The ink with which the cells of the second printing roll 31 are filled is, for example, a ceramic paste applied to eliminate the step between the internal electrode pattern 43 and its surrounding area. FIG. 7B is a diagram showing a state in which a ceramic paste pattern 44 is formed around the internal electrode pattern 43 by the second plate roll 31. As shown in FIG. By forming the ceramic paste pattern 44 around the internal electrode pattern 43, the above-described steps are eliminated, and structural defects due to the density difference inside the laminate, which are likely to occur when ceramic green sheets with steps are used, are eliminated. , delamination, short-circuiting between internal electrodes, etc., can be suppressed, and a highly reliable laminated ceramic electronic component can be manufactured.

The second peripheral speed detection unit 32 detects the peripheral speed V _d2 of the drum roll 2 at the position where the second plate roll 31 contacts the printing object 20 . The peripheral speed _Vd2 may be detected using the same detection method as the detection of the peripheral speed _Vd1 by the first peripheral speed detector 3, or a different detection method may be used.

The second angular velocity adjuster 33 adjusts the second angular velocity so that the peripheral velocity V _h2 of the second plate roll 31 matches the peripheral velocity V _d2 of the drum roll 2 detected by the second peripheral velocity detector 32 . to adjust the angular velocity ω _h2 of the plate roll 31 of . Since the rotation of the second printing roll 31 is performed by the second motor 34 , the second angular velocity adjustment unit 33 controls the second motor 34 to adjust the angular velocity ω Adjust _h2 .

Specifically, if the radius of the cross section of the second plate roll 31 cut in the direction perpendicular to the rotation axis direction is r ₂ , the second angular velocity adjustment unit 33 adjusts the angular velocity of the second plate roll 31 to The second motor 34 is controlled so that ω _h2 becomes V _d2 /r ₂ .

FIG. 8 is a flowchart for explaining the procedure of the angular velocity adjustment method of the first plate roll 1 and the second plate roll 31 when printing is performed by the gravure printing apparatus 10A in the second embodiment.

In step S11, the rotation of the drum roll 2 is started so as to rotate at the angular velocity _ωd . For example, a controller (not shown) controls the drum roll motor 6 to rotate the drum roll 2 at an angular velocity _ωd .

In step S12 following step S11, the rotation of the first plate roll ₁ is started so as to rotate at the angular velocity ω1. For example, a controller (not shown) controls the first motor 5 to rotate the first plate roll 1 at an angular velocity ω ₁ .

In step S13 following step S12, the rotation of the _second plate roll 31 is started so as to rotate at an angular velocity ω2. For example, a controller (not shown) controls the second motor 34 to rotate the second plate roll 31 at an angular velocity ω ₂ .

In step S14 subsequent to step S13, the first circumferential speed detector 3 detects the circumferential speed _Vd1 of the drum roll 2 at the position where it contacts the first plate roll 1 through the printing object 20. FIG.

In step S15 following step S14, the peripheral speed V _h1 of the first plate roll 1 detected by the first peripheral speed detection unit 3 is detected by the first angular speed adjustment unit 4, and the peripheral speed V _d1 of the drum roll 2 is detected by the first speed detection unit 3. The angular velocity ω _h1 of the first plate roll 1 is adjusted so as to match with . That is, the first angular velocity adjusting section 4 controls the first motor 5 so that the angular velocity ω _h1 of the first plate roll 1 becomes V _d1 /r ₁ .

In step S<b>16 following step S<b>15 , the second circumferential speed detector 32 detects the circumferential speed V _d2 of the drum roll 2 at the position where the second plate roll 31 abuts through the printing object 20 .

In step S17 following step S16, the peripheral speed V _h2 of the second printing roll 31 is detected by the second angular velocity adjusting unit 33, and the peripheral speed V _d2 of the drum roll 2 detected by the second peripheral speed detecting unit 32 is detected. The angular velocity ω _h2 of the second plate roll 31 is adjusted so as to match with . That is, the second angular velocity adjusting section 33 controls the second motor 34 so that the angular velocity ω _h2 of the second plate roll 31 becomes V _d2 /r ₂ .

In step S18 following step S17, when the rotation of the drum roll 2 continues, the process returns to step S14, and the processes after step S14 are performed again. On the other hand, when the gravure printing is finished and the rotation of the drum roll 2 is stopped, the process of the flowchart is finished.

According to the gravure printing apparatus 10A of the second embodiment, even when the cross-sectional shape of the drum roll 2 is not a perfect circle, the circumferential speeds at the contact positions of the first plate roll 1 and the drum roll 2 are matched, Printing accuracy can be improved by matching the circumferential speeds at the contact positions of the second plate roll 31 and the drum roll 2 . Therefore, for example, as shown in FIG. 43 and the ceramic paste pattern 44 formed therearound can be formed with high accuracy.

<Third Embodiment>
FIG. 9 is a diagram schematically showing the configuration of main parts of a gravure printing apparatus 10B according to the third embodiment. A gravure printing apparatus 10B according to the third embodiment further includes a third peripheral speed detection unit 51 in addition to the configuration of the gravure printing apparatus 10 according to the first embodiment.

The third peripheral speed detection unit 51 detects the peripheral speed V _h1 of the first plate roll 1 at the position where the printing object 20 is in contact with the drum roll 2 . As an example, the third peripheral speed detection unit 51 includes a camera, and a plurality of speed detection markers are provided on the outer peripheral surface of the first plate roll 1 . Then, a camera captures an image of the speed detection marker, and based on the position of the speed detection marker in the captured image, the peripheral speed V of the first plate roll 1 at the position where it contacts the drum roll 2 through the printing object 20 is calculated. Detect _h1 .

However, the method for detecting the peripheral speed V _h1 of the first plate roll 1 at the position where it contacts the drum roll 2 via the printing object 20 is not limited to the above-described method, and any method may be used for detection. can be done. For example, a well-known Doppler speedometer may be used as the third peripheral speed detector 51 .

The first angular velocity adjuster 4 controls the peripheral velocity V _h1 of the first plate roll 1 detected by the third peripheral velocity detector 51 and the velocity of the drum roll 2 detected by the first peripheral velocity detector 3 . The angular velocity ω _h1 of the first plate roll 1 is adjusted so that the difference from the peripheral velocity V _d1 becomes zero. More specifically, the first angular velocity adjuster 4 adjusts the peripheral velocity V h1 of the first plate roll 1 detected by the third peripheral velocity detector 51 and the peripheral velocity V _h1 detected by the first peripheral velocity detector 3 . is _greater than the first threshold value V _th1 , the above difference (V _h1 -V _d1 ) _becomes 0 _. Then, the angular velocity ω _h1 of the first plate roll 1 is adjusted. The first threshold V _th1 is a threshold for determining whether or not the absolute value of the difference |V _h1 −V _d1 | described above is within the allowable range.

For example, when the peripheral speed V _h1 of the first printing roll 1 is higher than the peripheral speed V _d1 of the drum roll 2, the first printing plate is adjusted so that the angular velocity is reduced by (V _h1 −V _d1 )/r ₁ . Angular velocity ω _h1 of roll 1 is adjusted. Further, when the peripheral speed V _h1 of the first plate roll 1 is smaller than the peripheral speed V _d1 of the drum roll 2, the first plate roll is rotated so that the angular velocity increases by (V _d1 −V _h1 )/r ₁ . Angular velocity ω _h1 of roll 1 is adjusted.

FIG. 10 is a flowchart for explaining the procedure of the method for adjusting the angular velocity of the first plate roll 1 when printing is performed by the gravure printing apparatus 10B in the third embodiment.

In step S31, the rotation of the drum roll 2 is started so as to rotate at the angular velocity _ωd . For example, a controller (not shown) controls the drum roll motor 6 to rotate the drum roll 2 at an angular velocity _ωd .

In step S32 following step S31, the rotation of the first plate roll ₁ is started so as to rotate at the angular velocity ω1. For example, a controller (not shown) controls the first motor 5 to rotate the first plate roll 1 at an angular velocity ω ₁ .

In step S 33 following step S 32 , the first circumferential speed detector 3 detects the circumferential speed V _d1 of the drum roll 2 at the position where it contacts the first plate roll 1 through the printing object 20 .

In step S34 following step S33, the third peripheral speed detection unit 51 detects the peripheral speed _Vh1 of the first plate roll 1 at the position where the drum roll 2 contacts with the printing object 20 interposed therebetween.

In step S35 following step S34, the peripheral speed _Vh1 of the first plate roll 1 detected by the third peripheral speed detector 51 and the peripheral speed of the drum roll 2 detected by the first peripheral speed detector 3 are detected. It is determined whether or not the absolute value |V _h1 −V _d1 | of the difference from the speed V _d1 is equal to or less than the first threshold value V _th1 . This determination is made by the first angular velocity adjustment unit 4, for example. of the difference between the peripheral speed V _h1 of the first plate roll ₁ and the peripheral speed V _d1 of the drum roll 2 is less than or _equal to the first threshold value V _th1 , The process of step S37 is performed without adjusting the angular velocity ω _h1 of the plate roll 1, and if it is determined that the angular velocity ω h1 is greater than the first threshold value V _th1 , the process of step S36 is performed.

In step S36, the peripheral speed V _h1 of the first plate roll 1 detected by the third peripheral speed detection unit 51 and the peripheral speed V h detected by the first peripheral speed detection unit 3 are The angular velocity ω _h1 of the first plate roll 1 is adjusted so that the difference from the peripheral velocity V _d1 of the drum roll 2 becomes zero.

In step S37, when the rotation of the drum roll 2 continues, the process returns to step S33, and the processes after step S33 are performed again. On the other hand, when the gravure printing is finished and the rotation of the drum roll 2 is stopped, the process of the flowchart is finished.

According to the gravure printing apparatus 10B of the third embodiment, the peripheral speed V h1 of the first plate roll 1 detected by the third peripheral speed detection unit 51 and the peripheral speed V _h1 detected by the first peripheral speed detection unit 3 Since the angular velocity ω _h1 of the first plate roll 1 is adjusted so that the difference between the peripheral speed V _d1 of the drum roll 2 and the peripheral speed V d1 of the drum roll 2 becomes 0, the peripheral speed V _h1 of the first plate roll 1 and that of the drum roll 2 are The angular velocity ω _h1 of the first plate roll 1 can be adjusted according to the actual difference between it and the peripheral velocity V _d1 . Therefore, even if there is an error in the radius r1 of the first plate roll 1, the circumferential speeds at the contacting positions of the first plate roll 1 and the drum roll 2 can be matched, and the printing accuracy can be further improved. can be done.

<Fourth Embodiment>
FIG. 11 is a diagram schematically showing the configuration of main parts of a gravure printing apparatus 10C according to the fourth embodiment. A gravure printing apparatus 10C according to the fourth embodiment further includes a third peripheral speed detection unit 51 and a fourth peripheral speed detection unit 52 in addition to the configuration of the gravure printing apparatus 10A according to the second embodiment. The third peripheral speed detector 51 is the same as the third peripheral speed detector 51 of the gravure printing apparatus 10B in the third embodiment.

The fourth peripheral speed detection unit 52 detects the peripheral speed _Vh2 of the second plate roll 31 at the position where the drum roll 2 contacts with the printing object 20 interposed therebetween. The peripheral speed _Vh2 of the second printing roll 31 can be detected using the same detection method as the detection of the peripheral speed _Vh1 of the first printing roll 1 by the third peripheral speed detector 51. FIG.

The second angular velocity adjustment section 33 is configured to adjust the peripheral velocity V _h2 of the second plate roll 31 detected by the fourth peripheral velocity detection section 52 and the velocity of the drum roll 2 detected by the second peripheral velocity detection section 32 . The angular velocity ω _h2 of the second plate roll 31 is adjusted so that the difference from the peripheral velocity V _d2 becomes zero. More specifically, the second angular velocity adjuster 33 adjusts the peripheral velocity V h2 of the second plate roll 31 detected by the fourth peripheral velocity detector 52 and the peripheral velocity V _h2 detected by the second peripheral velocity detector 32 . is _greater than the second threshold value V _th2 , the above difference (V _h2 -V _d2 ) _becomes 0 _. Then, the angular velocity ω _h2 of the second plate roll 31 is adjusted. The second threshold V _th2 is a threshold for determining whether or not the absolute value of the difference |V _h2 −V _d2 | described above is within the allowable range. As described above, the second angular velocity adjuster 33 adjusts the angular velocity ω _h2 of the second plate roll 31 by controlling the second motor 34 .

FIG. 12 is a flowchart for explaining the procedure of the angular velocity adjusting method of the first plate roll 1 and the second plate roll 31 when printing is performed by the gravure printing apparatus 10C in the fourth embodiment.

In step S41, the rotation of the drum roll 2 is started so as to rotate at the angular velocity _ωd . For example, a controller (not shown) controls the drum roll motor 6 to rotate the drum roll 2 at an angular velocity _ωd .

In step S42 following step S41, the rotation of the first plate roll ₁ is started so as to rotate at an angular velocity ω1. For example, a controller (not shown) controls the first motor 5 to rotate the first plate roll 1 at an angular velocity ω ₁ .

In step S43 following step S42, the rotation of the _second plate roll 31 is started so as to rotate at an angular velocity ω2. For example, a controller (not shown) controls the second motor 34 to rotate the second plate roll 31 at an angular velocity ω ₂ .

In step S44 following step S43, the first circumferential speed detector 3 detects the circumferential speed _Vd1 of the drum roll 2 at the position where the first plate roll 1 contacts with the printing object 20 interposed therebetween.

In step S45 subsequent to step S44, the third circumferential speed detector 51 detects the circumferential speed _Vh1 of the first plate roll 1 at the position where the drum roll 2 contacts with the print object 20 interposed therebetween.

In step S46 following step S45, the peripheral speed V _h1 of the first plate roll 1 detected by the third peripheral speed detector 51 and the peripheral speed of the drum roll 2 detected by the first peripheral speed detector 3 are detected. It is determined whether or not the absolute value |V _h1 −V _d1 | of the difference from the speed V _d1 is equal to or less than the first threshold value V _th1 . This determination is made by the first angular velocity adjustment unit 4, for example. of the difference between the peripheral speed V _h1 of the first plate roll ₁ and the peripheral speed V _d1 of the drum roll 2 is less than or _equal to the first threshold value V _th1 , The process of step S48 is performed without adjusting the angular velocity ω _h1 of the plate roll 1, and if it is determined that the angular velocity ω h1 is greater than the first threshold value V _th1 , the process of step S47 is performed.

In step S47, the peripheral speed V _h1 of the first plate roll 1 detected by the third peripheral speed detection unit 51 and the peripheral speed V h detected by the first peripheral speed detection unit 3 are The angular velocity ω _h1 of the first plate roll 1 is adjusted so that the difference from the peripheral velocity V _d1 of the drum roll 2 becomes zero.

In step S48, the second peripheral speed detection unit 32 detects the peripheral speed _Vd2 of the drum roll 2 at the position where the second plate roll 31 comes into contact with the printing object 20 therebetween.

In step S49 subsequent to step S48, the fourth peripheral speed detector 52 detects the peripheral speed _Vh2 of the second plate roll 31 at the position where it contacts the drum roll 2 via the printing object 20. FIG.

In step S50 following step S49, the peripheral speed V _d2 of the drum roll 2 detected by the third peripheral speed detector 51 and the peripheral speed of the second plate roll 31 detected by the fourth peripheral speed detector 52 are detected. It is determined whether or not the absolute value |V _h2 -V _d2 | of the difference from the speed V _h2 is equal to or less than the second threshold value V _th2 . This determination is made by the second angular velocity adjustment unit 33, for example. of the difference between the peripheral speed V _h2 of the second plate roll 31 and the peripheral speed V _d2 of the drum roll ₂ is _equal to or less than the second threshold value V _th2 , the second The process of step S52 is performed without adjusting the angular velocity _ωh2 of the plate roll 31. If it is determined that the angular velocity _ωh2 is greater than the second threshold value Vth2, the process of step S51 is performed.

In step S51, the second angular velocity adjuster 33 detects the peripheral velocity _Vh2 of the second plate roll 31 detected by the fourth peripheral velocity detector 52 and the third peripheral velocity detector 51 detects The angular velocity _ωh2 of the second plate roll 31 is adjusted so that the difference from the peripheral velocity _Vd2 of the drum roll 2 becomes zero.

In step S52, when the rotation of the drum roll 2 continues, the process returns to step S44 and the processes after step S44 are performed again. On the other hand, when the gravure printing is finished and the rotation of the drum roll 2 is stopped, the process of the flowchart is finished.

According to the gravure printing apparatus 10C of the fourth embodiment, the peripheral speed V h1 of the first plate roll 1 detected by the third peripheral speed detection unit 51 and the peripheral speed V _h1 detected by the first peripheral speed detection unit 3 The angular velocity ω _h1 of the first plate roll 1 is adjusted so that the difference from the peripheral speed V _d1 of the drum roll 2 detected by the fourth peripheral speed detector 52 is 0, and the second plate detected by the fourth peripheral speed detector 52 is adjusted. The angular velocity ω _h2 of the second plate roll 31 is adjusted so that the difference between the peripheral velocity V _h2 of the roll 31 and the peripheral velocity V _d2 of the drum roll 2 detected by the third peripheral velocity detector 51 becomes zero. adjust. That is, the angular velocity ω _h1 of the first printing roll 1 is adjusted according to the actual difference between the peripheral speed V _h1 of the first printing roll 1 and the peripheral speed V _d1 of the drum roll 2, and The angular velocity ω _h2 of the second plate roll 31 is adjusted according to the actual difference between the peripheral speed V _h2 of the second plate roll 31 and the peripheral speed V _d2 of the drum roll 2 . Therefore, even if there is an error in the radius r1 of the first printing roll 1, the circumferential speeds at the contact positions of the first printing roll 1 and the drum roll 2 can be matched, and the second printing roll Even if there is an error in the radius r2 of the plate roll 31, the circumferential speeds at the contact positions of the second plate roll 31 and the drum roll 2 can be matched, so that the printing accuracy can be further improved.

<Fifth Embodiment>
FIG. 13 is a diagram schematically showing the configuration of main parts of a gravure printing apparatus 10D according to the fifth embodiment. A gravure printing apparatus 10D in the fifth embodiment includes a first plate roll 1, a drum roll 2, a first motor 5, a drum roll motor 6, a first angular velocity adjustment unit 61, a storage unit 62 and a rotational position detector 63 .

The rotational position detector 63 is an encoder, for example, and detects the rotational position θ of the rotation reference point of the drum roll 2 .

The storage unit 62 stores peripheral speed data V _d (θ) representing the relationship between the rotational position θ of the drum roll 2 and the peripheral speed of the drum roll 2 .

FIG. 14(a) is a diagram showing the relationship between the rotational position θ of the drum roll 2 and the peripheral speed of the drum roll 2 at the peripheral speed measurement position. By measuring the peripheral speed corresponding to the rotational position θ of the drum roll 2, peripheral speed data V _d (θ ) is obtained in advance.

The peripheral speed data V _d (θ) is peripheral speed data for at least one round of the drum roll 2 . However, after measuring the peripheral speed for a plurality of revolutions, the average peripheral speed for each rotational position may be obtained and stored in the storage unit 62 as the peripheral speed data V _d (θ). .

of the drum roll 2 detected by the rotational position detector 63 and the peripheral speed data V _d (θ) stored in the storage unit 62. The peripheral speed V _d1 of the drum roll 2 at the position where it contacts the first plate roll 1 through the object 20 is obtained, and the obtained peripheral speed V _d1 of the drum roll 2 and the peripheral speed V _h1 of the first plate roll 1 are obtained. The angular velocity ω _h1 of the first plate roll 1 is adjusted so that Specifically, the first angular velocity adjusting section 4 controls the first motor 5 so that the angular velocity ω _h1 of the first plate roll 1 becomes V _d1 /r ₁ .

Here, if the position where the peripheral speed of the drum roll 2 is measured does not match the position where the drum roll 2 contacts the first plate roll 1 via the printing object 20, the drum roll 2 It needs to be corrected by the angle between the two positions in the direction of rotation. For example, if the angle between the circumferential speed measurement position and the contact position with the first plate roll 1 via the printing object 20 in the rotation direction of the drum roll 2 is θ ₁ , then the rotation position of the drum roll 2 is and the peripheral speed of the drum roll 2 at the position where it comes into contact with the first plate roll 1 via the printing object 20, as shown in FIG. _The speed data is shifted by θ1.

FIG. 15 is a flowchart for explaining the procedure of the method for adjusting the angular velocity of the first plate roll 1 when printing is performed by the gravure printing apparatus 10D in the fifth embodiment.

In step S61, the rotation position detector 63 detects the rotation position θ of the rotation reference point of the drum roll 2. As shown in FIG.

In step S62 following step S61, the peripheral speed data V _d (θ) stored in the storage unit 62 is read out by the first angular speed adjustment unit 61 .

In step S63 following step S62, the rotation of the drum roll 2 is started so as to rotate at the angular velocity _ωd . For example, a controller (not shown) controls the drum roll motor 6 to rotate the drum roll 2 at an angular velocity _ωd .

In step S64 following step S63, based on the rotational position θ of the drum roll 2 detected by the rotational position detection unit 63 and the peripheral speed data V _d (θ) read from the storage unit 62, the printing object 20 is detected. The circumferential speed _Vd1 of the drum roll 2 at the position where it _contacts the first plate roll ₁ through the The angular velocity ω _h1 of the first plate roll 1 is adjusted so that As described above, the first angular velocity adjusting section 61 adjusts the angular velocity ω _h1 of the first plate roll 1 by controlling the first motor 5 .

In step S65 following step S64, if the rotation of the drum roll 2 continues, the process returns to step S64 to adjust the angular velocity ω _h1 of the first plate roll 1 again. On the other hand, when the gravure printing is finished and the rotation of the drum roll 2 is stopped, the process of the flowchart is finished.

Since the process of step S64 is performed at predetermined time intervals until the rotation of the drum roll 2 is stopped, once the rotation position θ of the rotation reference point of the drum roll 2 is first detected, it is detected each time thereafter. The rotation position θ of the rotation reference point of the drum roll 2 can be grasped without doing this.

According to the gravure printing apparatus 10D in the fifth embodiment, it is not necessary to detect the peripheral speed _Vd1 of the drum roll 2 at the position where it contacts the first plate roll 1 via the printing object 20. Therefore, the drum roll 2, the peripheral speed detector for detecting the peripheral speed _Vd1 can be omitted, and the cost can be reduced.

<Sixth embodiment>
FIG. 16 is a diagram schematically showing the configuration of main parts of a gravure printing apparatus 10E according to the sixth embodiment. A gravure printing apparatus 10E according to the sixth embodiment differs from the gravure printing apparatus 10D according to the fifth embodiment in that it includes a second plate roll 31, a second angular velocity adjustment unit 71, and a second motor 34. and further. Note that the first angular velocity adjustment section 61 and the second angular velocity adjustment section 71 may be configured as one angular velocity adjustment section.

of the drum roll 2 detected by the rotational position detector 63 and the peripheral speed data V _d (θ) stored in the storage unit 62. The peripheral speed _{Vd2 of the drum roll 2 at the position where it contacts the second plate roll 31 through the object 20 is obtained, and the obtained peripheral speed Vd2 of} the drum roll 2 and the peripheral speed _Vh2 of the second plate roll 31 are calculated. The angular velocity ω _h2 of the second plate roll 31 is adjusted so that Specifically, the second angular velocity adjusting section 71 controls the second motor 34 so that the angular velocity ω _h2 of the second plate roll 31 becomes V _d2 /r ₂ .

If the position at which the peripheral speed of the drum roll 2 is measured does not match the position at which the second plate roll 31 contacts the print object 20, two It needs to be corrected by the angle between positions.

FIG. 17 is a flowchart for explaining the procedure of the angular velocity adjusting method of the first plate roll 1 and the second plate roll 31 when printing is performed by the gravure printing apparatus 10E in the sixth embodiment.

In step S71, the rotation position detector 63 detects the rotation position θ of the rotation reference point of the drum roll 2. As shown in FIG.

In step S72 following step S71, the peripheral speed data V _d (θ) stored in the storage unit 62 is read out by the first angular speed adjustment unit 61 and the second angular speed adjustment unit 71 .

In step S73 following step S72, the rotation of the drum roll 2 is started so as to rotate at the angular velocity _ωd . For example, a controller (not shown) controls the drum roll motor 6 to rotate the drum roll 2 at an angular velocity _ωd .

In step S74 following step S73, based on the rotational position θ of the drum roll 2 detected by the rotational position detection unit 63 and the peripheral speed data V _d (θ) read from the storage unit 62, the printing object 20 is detected. The circumferential speed _Vd1 of the drum roll 2 at the position where it _contacts the first plate roll ₁ through the The angular velocity ω _h1 of the first plate roll 1 is adjusted so that As described above, the first angular velocity adjusting section 61 adjusts the angular velocity ω _h1 of the first plate roll 1 by controlling the first motor 5 .

In step S75 following step S74, based on the rotational position θ of the drum roll 2 detected by the rotational position detection unit 63 and the peripheral speed data V _d (θ) read from the storage unit 62, the printing object 20 is detected. The _peripheral speed _Vd2 of the drum roll 2 at the position where it contacts the second _printing roll 31 through the The angular velocity ω _h2 of the second plate roll 31 is adjusted so that The second angular velocity adjusting section 71 adjusts the angular velocity ω _h2 of the second plate roll 31 by controlling the second motor 34 .

According to the gravure printing apparatus 10E of the sixth embodiment, the peripheral speed V _d1 of the drum roll 2 at the position where it comes into contact with the first plate roll 1 via the printing object 20 and the contact with the second plate roll 31 Since it is not necessary to detect the peripheral speed Vd2 of the drum roll 2 at the contact position, the peripheral speed detection unit for detecting the peripheral _{speeds Vd1} and _Vd2 of the drum roll 2 can be omitted, resulting in cost reduction. can do.

<Seventh Embodiment>
FIG. 18 is a diagram schematically showing the configuration of main parts of a gravure printing apparatus 10F according to the seventh embodiment. A gravure printing apparatus 10F according to the seventh embodiment further includes a third peripheral speed detection unit 51 in addition to the configuration of the gravure printing apparatus 10D according to the fifth embodiment shown in FIG.

The third peripheral speed detector 51 in this embodiment is the same as the third peripheral speed detector 51 of the gravure printing apparatus 10B in the third embodiment. That is, the third peripheral speed detection unit 51 detects the peripheral speed _Vh1 of the first plate roll 1 at the position where the drum roll 2 contacts with the printing object 20 interposed therebetween.

The first angular velocity adjustment unit 61 first adjusts the rotation position θ of the drum roll 2 detected by the rotation position detection unit 63 and the peripheral speed data V _d (θ) stored in the storage unit 62. The peripheral speed _Vd1 of the drum roll 2 at the position where it contacts the first plate roll 1 through the printing object 20 is obtained. Subsequently, the first angular velocity adjusting section 61 determines the peripheral velocity V _h1 of the first plate roll 1 detected by the third peripheral velocity detecting section 51 and the peripheral velocity V of the drum roll 2 obtained by the method described above. The angular velocity ω _h1 of the first plate roll 1 is adjusted so that the difference (V _h1 −V _d1 ) with _d1 becomes zero. The adjustment of the angular velocity _ωh1 of the first printing roll 1 here is performed by the first angular velocity adjustment unit 4 in the gravure printing apparatus 10B of the third embodiment, the peripheral velocity _Vh1 of the first printing roll 1 and the drum The same method as the method for adjusting the angular velocity ω _h1 of the first plate roll 1 can be used so that the difference (V _h1 −V _d1 ) with the peripheral speed V _d1 of the roll 2 becomes zero.

FIG. 19 is a flowchart for explaining the procedure of the method for adjusting the angular velocity of the first plate roll 1 when printing is performed by the gravure printing apparatus 10F according to the seventh embodiment.

In step S81, the rotation position detector 63 detects the rotation position θ of the rotation reference point of the drum roll 2. As shown in FIG.

In step S82 following step S81, the peripheral speed data V _d (θ) stored in the storage unit 62 is read out by the first angular speed adjustment unit 61 .

In step S83 following step S82, the rotation of the drum roll 2 is started so as to rotate at the angular velocity _ωd . For example, a controller (not shown) controls the drum roll motor 6 to rotate the drum roll 2 at an angular velocity _ωd .

In step S84 following step S83, the third circumferential speed detector 51 detects the circumferential speed _Vh1 of the first plate roll 1 at the position where the drum roll 2 contacts with the printing object 20 interposed therebetween.

In step S85 following step S84, the rotational position θ of the drum roll 2 detected by the rotational position detector 63 and the peripheral speed data V _d (θ ), the peripheral speed V _d1 of the drum roll 2 at the position where it comes into contact with the first plate roll 1 via the printing object 20 is obtained, and the first peripheral speed V d1 detected by the third peripheral speed detection unit 51 is obtained. It is determined whether or not the absolute value |V _h1 −V _d1 | of the difference between the circumferential speed V _h1 of the plate roll 1 and the obtained circumferential speed V _d1 of the drum roll 2 is equal to or less than the first threshold value V _th1 . of the difference between the peripheral speed V _h1 of the first plate roll ₁ and the peripheral speed V _d1 of the drum roll 2 is less than or _equal to the first threshold value V _th1 , The process of step S87 is performed without adjusting the angular velocity ω _h1 of the plate roll 1, and if it is determined that the angular velocity ω h1 is greater than the first threshold value V _th1 , the process of step S86 is performed.

In step S86, the first angular velocity adjuster 61 determines the difference between the peripheral velocity _Vh1 of the first plate roll 1 detected by the third peripheral velocity detector 51 and the obtained peripheral velocity _Vd1 of the drum roll 2. The angular velocity ω _h1 of the first plate roll 1 is adjusted so that the difference becomes zero.

In step S87, when the rotation of the drum roll 2 continues, the process returns to step S84 and the processes after step S84 are performed again. On the other hand, when the gravure printing is finished and the rotation of the drum roll 2 is stopped, the process of the flowchart is finished.

According to the gravure printing apparatus 10F of the seventh embodiment, similarly to the gravure printing apparatus 10D of the fifth embodiment, the peripheral speed detection unit for detecting the peripheral speed _Vd1 of the drum roll 2 can be omitted. can reduce costs. Further, as in the gravure printing apparatus 10B in the third embodiment, even if there is an error in the radius r1 of the first plate roll 1, the peripheral speed at the position where the first plate roll 1 and the drum roll 2 contact can be matched, and printing accuracy can be further improved.

<Eighth embodiment>
FIG. 20 is a diagram schematically showing the configuration of main parts of a gravure printing apparatus 10G according to the eighth embodiment. A gravure printing apparatus 10G according to the eighth embodiment further includes a third peripheral speed detection unit 51 and a fourth peripheral speed detection unit 52 in addition to the gravure printing apparatus 10E according to the sixth embodiment shown in FIG. .

The third peripheral speed detector 51 in this embodiment is the same as the third peripheral speed detector 51 of the gravure printing apparatus 10C in the fourth embodiment. That is, the third peripheral speed detection unit 51 detects the peripheral speed _Vh1 of the first plate roll 1 at the position where the drum roll 2 contacts with the printing object 20 interposed therebetween.

The fourth peripheral speed detector 52 in this embodiment is the same as the fourth peripheral speed detector 52 of the gravure printing apparatus 10C in the fourth embodiment. That is, the fourth peripheral speed detector 52 detects the peripheral speed _Vh2 of the second plate roll 31 at the position where the drum roll 2 contacts with the printing object 20 interposed therebetween.

The second angular velocity adjustment unit 71 is first based on the rotational position θ of the drum roll 2 detected by the rotational position detection unit 63 and the peripheral speed data V _d (θ) stored in the storage unit 62, A peripheral speed V _d2 of the drum roll 2 at the position where it contacts the second plate roll 31 via the printing object 20 is obtained. Subsequently, the second angular velocity adjuster 71 adjusts the peripheral velocity V _h2 of the second plate roll 31 detected by the fourth peripheral velocity detector 52 and the peripheral velocity V of the drum roll 2 obtained by the method described above. The angular velocity ω _h2 of the second plate roll 31 is adjusted so that the difference (V _h2 −V _d2 ) with _d2 becomes zero. The adjustment of the angular _{velocity ωh2} of the second printing roll 31 here is performed by the second angular velocity adjustment unit 33 in the gravure printing apparatus 10C according to the fourth embodiment. The same method as the method for adjusting the angular velocity ω _h2 of the second plate roll 31 can be used so that the difference (V _h2 −V _d2 ) from the peripheral velocity V _d2 of the roll 2 becomes zero.

FIG. 21 is a flowchart for explaining the procedure of the angular velocity adjustment method of the first plate roll 1 and the second plate roll 31 when printing is performed by the gravure printing apparatus 10G in the eighth embodiment.

In step S91, the rotation position detector 63 detects the rotation position θ of the rotation reference point of the drum roll 2. As shown in FIG.

In step S92 following step S91, the peripheral speed data V _d (θ) stored in the storage unit 62 is read out by the first angular speed adjustment unit 61 .

In step S93 following step S92, the rotation of the drum roll 2 is started so as to rotate at the angular velocity _ωd . For example, a controller (not shown) controls the drum roll motor 6 to rotate the drum roll 2 at an angular velocity _ωd .

In step S94 following step S93, the third circumferential speed detector 51 detects the circumferential speed _Vh1 of the first plate roll 1 at the position where the drum roll 2 contacts with the print object 20 interposed therebetween.

In step S95 following step S94, the rotational position θ of the drum roll 2 detected by the rotational position detector 63 and the peripheral speed data V _d (θ ), the peripheral speed V _d1 of the drum roll 2 at the position where it comes into contact with the first plate roll 1 via the printing object 20 is obtained, and the first peripheral speed V d1 detected by the third peripheral speed detection unit 51 is obtained. It is determined whether or not the absolute value |V _h1 −V _d1 | of the difference between the circumferential speed V _h1 of the plate roll 1 and the obtained circumferential speed V _d1 of the drum roll 2 is equal to or less than the first threshold value V _th1 . of the difference between the peripheral speed V _h1 of the first plate roll ₁ and the peripheral speed V _d1 of the drum roll 2 is less than or _equal to the first threshold value V _th1 , The process of step S97 is performed without adjusting the angular velocity ω _h1 of the plate roll 1, and if it is determined that the angular velocity ω h1 is greater than the first threshold value V _th1 , the process of step S96 is performed.

In step S96, the first angular velocity adjuster 61 determines the difference between the peripheral velocity _Vh1 of the first plate roll 1 detected by the third peripheral velocity detector 51 and the obtained peripheral velocity _Vd1 of the drum roll 2. The angular velocity ω _h1 of the first plate roll 1 is adjusted so that the difference becomes zero.

In step S97, the fourth circumferential speed detection unit 52 detects the circumferential speed _Vh2 of the second plate roll 31 at the position where it contacts the drum roll 2 through the printing object 20. FIG.

In step S98 following step S97, the rotational position θ of the drum roll 2 detected by the rotational position detector 63 and the peripheral speed data V _d (θ ), the peripheral speed V _d2 of the drum roll 2 at the position where it contacts the second plate roll 31 via the printing object 20 is obtained, and the second speed V d2 detected by the fourth peripheral speed detection unit 52 is obtained. It is determined whether or not the absolute value |V _h2 −V _d2 | of the difference between the circumferential speed V _h2 of the plate roll 31 and the obtained circumferential speed V _d2 of the drum roll 2 is equal to or less than the second threshold value V _th2 . of the difference between the peripheral speed V _h2 of the second plate roll 31 and the peripheral speed V _d2 of the drum roll ₂ is _equal to or less than the second threshold value V _th2 , the second The process of step S100 is performed without adjusting the angular velocity _ωh2 of the plate roll 31, and if it is determined that the angular velocity _ωh2 is greater than the second threshold value Vth2, the process of step S99 is performed.

In step S99, the second angular velocity adjuster 71 determines the difference between the circumferential velocity _Vh2 of the second plate roll 31 detected by the fourth circumferential velocity detector 52 and the obtained circumferential velocity _Vd2 of the drum roll 2. The angular velocity ω _h2 of the second plate roll 31 is adjusted so that the difference becomes zero.

In step S100, when the rotation of the drum roll 2 continues, the process returns to step S94, and the processes after step S94 are performed again. On the other hand, when the gravure printing is finished and the rotation of the drum roll 2 is stopped, the process of the flowchart is finished.

According to the gravure printing apparatus 10G of the eighth embodiment, similarly to the gravure printing apparatus 10E of the sixth embodiment, the peripheral speed detection unit for detecting the peripheral _{speeds Vd1} and _Vd2 of the drum roll 2 is omitted. can be used and the cost can be reduced. Further, similarly to the gravure printing apparatus 10C in the fourth embodiment, even if there is an error in the radius r1 of the first plate roll 1, the peripheral speed at the position where the first plate roll 1 and the drum roll 2 contact can be matched, and even if there is an error in the radius r2 of the second printing roll 31, the peripheral speed at the contact position of the second printing roll 31 and the drum roll 2 can be matched. , printing accuracy can be further improved.

(Manufacturing method of multilayer ceramic capacitor)
FIG. 22 is a flow chart for explaining a method of manufacturing a laminated ceramic capacitor.

In step S111, a plurality of ceramic green sheets are prepared. A well-known thing can be used as a ceramic green sheet.

In step S112 following step S111, an internal electrode pattern is formed on a specific one of the plurality of ceramic green sheets using one of the gravure printing apparatuses in the first to eighth embodiments described above. do. That is, the internal electrode pattern is formed by printing the conductive paste for internal electrodes on the ceramic green sheets using the gravure printing apparatus described above.

In step S113 following step S112, a laminate is produced by laminating a plurality of ceramic green sheets including a ceramic green sheet on which internal electrode patterns are formed. Specifically, a predetermined number of ceramic green sheets on which internal electrode patterns are not formed are laminated, ceramic green sheets on which internal electrode patterns are formed are successively laminated thereon, and internal electrode patterns are formed thereon. A laminate is produced by laminating a predetermined number of ceramic green sheets that have not been laminated. This laminate is an unfired mother laminate.

In step S114 following step S113, after pressing the laminate, it is separated into chips by various methods such as dicing and press cutting.

In step S115 following step S114, a ceramic laminate is produced by firing the individualized chips. The firing temperature is, for example, 900° C. or higher and 1300° C. or lower, although it depends on the materials of the ceramic layers and internal electrodes. After that, the corners and ridges of the ceramic laminate are rounded by barrel polishing or the like.

In step S116 following step S115, external electrodes are formed on both end surfaces of the ceramic laminate.

A laminated ceramic capacitor, which is a laminated ceramic electronic component, is produced by the above-described method.

The present invention is not limited to the above embodiments, and various applications and modifications can be made within the scope of the present invention. For example, the characteristic configurations in each of the above-described embodiments can be combined as appropriate.

In the gravure printing apparatus 10A of the second embodiment, the first angular velocity adjustment unit 4 adjusts the angular velocity _ωh1 of the first plate roll 1, and the second angular velocity adjustment unit 33 adjusts the angular velocity of the second plate roll 31. Although it is configured to adjust the angular velocity _ωh2 , the angular velocity of only one of the first printing roll 1 and the second printing roll 31 is adjusted, and the other printing roll is the drum It may be passively rotated so as to rotate together with the rotation of the roll 2 . In that case, in order to improve the printing accuracy between printing by the first printing roll 1 and printing by the second printing roll 31, the first printing roll 1 is passively rotated and the second printing roll 31 is rotated. 31 is preferably controlled to adjust the angular velocity ω _h2 . The same applies to the gravure printing apparatus 10C in the fourth embodiment, the gravure printing apparatus 10E in the sixth embodiment, and the gravure printing apparatus 10G in the eighth embodiment, each having two plate rolls.

In the above-described embodiment, the plate roll on which printing is first performed is the first plate roll 1, and the plate roll on which printing is performed later is the second plate roll 31. It is also possible to call the second plate roll and the plate roll that is subsequently printed the first plate roll.

The number of plate rolls is not limited to one or two, and may be three or more.

1 first plate roll 2 drum roll 2b elastic member 3 first peripheral speed detector 4 first angular speed adjuster 5 first motor 6 drum roll motors 10, 10A, 10B, 10C, 10D, 10E, 10F , 10G gravure printing device 11 cell 20 printing object 31 second plate roll 32 second peripheral speed detection unit 33 second angular speed adjustment unit 34 second motor 51 third peripheral speed detection unit 52 fourth peripheral Speed detector 61 First angular velocity adjuster 62 Storage part 63 Rotational position detector 71 Second angular velocity adjuster

Claims (9)

A gravure printing apparatus that performs printing by sandwiching a print target between a plate roll and a drum roll and transferring ink filled in cells formed on the outer peripheral surface of the plate roll to the print target. There is
a first printing plate roll formed with the cells having a shape corresponding to a figure to be printed on the outer peripheral surface;
the drum roll;
a first peripheral speed detection unit that detects the peripheral speed of the drum roll at a position where it contacts the first plate roll through the printing object;
A first method for adjusting the angular velocity of the first plate roll so that the peripheral speed of the drum roll detected by the first peripheral speed detection unit and the peripheral speed of the first plate roll match. an angular velocity adjustment unit;
with
The object to be printed is a ceramic green sheet formed on a carrier film,
the ink is at least one of a conductive paste and a ceramic paste;
A gravure printing apparatus , wherein an elastic member is disposed on at least a portion of the outer peripheral surface of the drum roll that contacts the first plate roll through the print target . a second plate roll having, on its outer peripheral surface, the cells having a shape corresponding to a figure to be printed;
a second peripheral speed detection unit that detects the peripheral speed of the drum roll at a position where it contacts the second plate roll through the printing object;
A second method for adjusting the angular velocity of the second plate roll so that the peripheral speed of the drum roll detected by the second peripheral speed detection unit and the peripheral speed of the second plate roll match. an angular velocity adjustment unit;
The gravure printing apparatus of claim 1, further comprising: a. further comprising a third peripheral speed detection unit that detects a peripheral speed of the first plate roll at a position where the printing target is in contact with the drum roll,
The first angular velocity adjuster adjusts the peripheral velocity of the first plate roll detected by the third peripheral velocity detector and the peripheral velocity of the drum roll detected by the first peripheral velocity detector. 3. The gravure printing apparatus according to claim 1, wherein the angular velocity of the first plate roll is adjusted so that the difference between the speed and the speed becomes zero. a third peripheral speed detection unit that detects a peripheral speed of the first plate roll at a position where the drum roll contacts the printing target;
a fourth peripheral speed detector that detects a peripheral speed of the second plate roll at a position where the drum roll contacts the printing target;
further comprising
The first angular velocity adjuster adjusts the peripheral velocity of the first plate roll detected by the third peripheral velocity detector and the peripheral velocity of the drum roll detected by the first peripheral velocity detector. Adjust the angular velocity of the first plate roll so that the difference between
The second angular velocity adjustment section adjusts the peripheral velocity of the second plate roll detected by the fourth peripheral velocity detection section and the peripheral velocity of the drum roll detected by the second peripheral velocity detection section. 3. The gravure printing apparatus according to claim 2, wherein the angular velocity of the second plate roll is adjusted so that the difference between is zero. A gravure printing apparatus that performs printing by sandwiching a print target between a plate roll and a drum roll and transferring ink filled in cells formed on the outer peripheral surface of the plate roll to the print target. There is
a first printing plate roll formed with the cells having a shape corresponding to a figure to be printed on the outer peripheral surface;
the drum roll;
a storage unit that stores peripheral speed data indicating the relationship between the rotational position of the drum roll and the peripheral speed of the drum roll;
a rotational position detection unit that detects the rotational position of the drum roll;
Based on the rotational position of the drum roll detected by the rotational position detection section and the peripheral speed data stored in the storage section, contact is made with the first plate roll via the print target. A first method for obtaining the peripheral speed of the drum roll at the position and adjusting the angular speed of the first plate roll so that the obtained peripheral speed of the drum roll and the peripheral speed of the first plate roll match. and an angular velocity adjustment unit of
with
The object to be printed is a ceramic green sheet formed on a carrier film,
the ink is at least one of a conductive paste and a ceramic paste;
A gravure printing apparatus , wherein an elastic member is disposed on at least a portion of the outer peripheral surface of the drum roll that contacts the first plate roll through the print target . a second plate roll having, on its outer peripheral surface, the cells having a shape corresponding to a figure to be printed;
Based on the rotational position of the drum roll detected by the rotational position detection unit and the peripheral speed data stored in the storage unit, contact is made with the second plate roll via the print target. A second method for obtaining the peripheral speed of the drum roll at the position and adjusting the angular speed of the second plate roll so that the obtained peripheral speed of the drum roll matches the peripheral speed of the second plate roll. and an angular velocity adjustment unit of
6. The gravure printing apparatus of claim 5, further comprising: a. further comprising a third peripheral speed detection unit that detects a peripheral speed of the first plate roll at a position where the printing target is in contact with the drum roll,
The first angular velocity adjustment unit adjusts the peripheral speed of the first plate roll detected by the third peripheral speed detection unit and 7. A gravure printing apparatus according to claim 5, wherein the angular velocity of said first plate roll is adjusted so that the difference from the peripheral velocity of said drum roll is zero. a third peripheral speed detection unit that detects a peripheral speed of the first plate roll at a position where the drum roll contacts the printing target;
a fourth peripheral speed detector that detects a peripheral speed of the second plate roll at a position where the drum roll contacts the printing target;
further comprising
The first angular velocity adjustment unit adjusts the peripheral speed of the first plate roll detected by the third peripheral speed detection unit and Adjusting the angular velocity of the first plate roll so that the difference from the peripheral velocity of the drum roll is 0;
The second angular velocity adjustment unit adjusts the peripheral speed of the second plate roll detected by the fourth peripheral speed detection unit and 7. A gravure printing apparatus according to claim 6, wherein the angular velocity of said second plate roll is adjusted so that the difference from the peripheral velocity of said drum roll is zero. A step of forming an internal electrode pattern on a ceramic green sheet using the gravure printing apparatus according to any one of claims 1 to 8 ;
producing a laminate by laminating a plurality of the ceramic green sheets including the ceramic green sheet on which the internal electrode pattern is formed;
a step of firing the laminate;
A step of providing an external electrode on the laminated body after firing;
A method for manufacturing a multilayer ceramic capacitor, comprising:

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