JP2018051813A - Printing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a printing device that allows a user to scan so as to easily draw a circular arc.SOLUTION: A printing device 1 comprises: a head part 2 having a plurality of nozzles 2a for performing printing on a recording medium 30; a rotation part 20, provided so that a distance between the part and the head part 2 can be changed, which serves as a rotation center when rotating the head part 2 relatively to the recording medium 30; a movement amount detecting part 4 that detects amounts of relative movement of the head part 2 accompanying the rotation; and a control part 10 that controls printing on the basis of the detected movement amounts of the head part 2 detected by the movement amount detecting part 4 and the distance between the head part 2 and the rotation part 20.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a printing apparatus.

2. Description of the Related Art Printing apparatuses that perform printing while being held in a printing direction (main scanning direction) held by a user are known (see Patent Documents 1 and 2).
These are intended for cases where the main scanning direction is substantially straight.

JP-A-5-330150 JP 2008-55680 A

By the way, for example, when a label is attached to a CD, DVD, BD, etc., it may be preferable in terms of appearance to print in an arc instead of printing in a straight line.
However, when the user moves the printing apparatus by hand, there is a problem that it is difficult to perform printing so as to draw a beautiful arc.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a printing apparatus that can be scanned by a user so as to easily draw an arc.

In order to achieve the above object, the present invention is grasped by the following configuration.
(1) A printing apparatus according to the present invention is provided with a head unit having a plurality of nozzles for printing on a recording medium, and a distance from the head unit that can be changed, and the head unit is relative to the recording medium. A rotation part that is a rotation center when the head part is rotated, a movement amount detection part that detects a relative movement amount of the head part accompanying the rotation, and the movement of the head part detected by the movement amount detection part A control unit that controls the printing based on the amount and the distance between the head unit and the rotating unit.

  ADVANTAGE OF THE INVENTION According to this invention, the printing apparatus which can be made to scan so that a user can draw an arc easily can be provided.

It is the perspective view which looked at the printing apparatus which concerns on one Embodiment of this invention from the lower surface side. 1 is a block diagram illustrating a schematic configuration of a printing apparatus. It is explanatory drawing which shows the printing procedure with respect to the recording medium of a printing apparatus. FIG. 6 is a plan view of a recording medium showing an example of printing in a rotational printing mode of the printing apparatus. It is explanatory drawing of the 1st coordinate (X coordinate) based on the rotation angle on the plane represented by the 1st reference axis (X) and the 2nd reference axis (Y). It is explanatory drawing of the 2nd coordinate (Y coordinate) based on the rotation angle on the plane represented by the 1st reference axis (X) and the 2nd reference axis (Y). It is a flowchart which shows the process sequence of the rotation printing mode of a control part. It is a flowchart which shows the process sequence of the subroutine (assignment process) of rotation printing mode. It is a flowchart which shows the process sequence of the subroutine (printing process) of rotation printing mode.

DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as “embodiments”) will be described in detail with reference to the accompanying drawings.
Note that the same number is assigned to the same element throughout the description of the embodiment.

FIG. 1 is a perspective view of a printing apparatus 1 according to an embodiment of the present invention as viewed from the lower surface side, and FIG. 2 is a block diagram illustrating a schematic configuration of the printing apparatus 1.
The printing apparatus 1 according to the embodiment of the present invention is a handy printer that prints graphic characters on a print object while being moved in a printing direction (main scanning direction) by a user holding the hand.
The graphic characters include not only letters, numbers, punctuation marks, symbols, spaces, etc., but also figures that can be handled in units of one character.

  As shown in FIG. 2, the printing apparatus 1 includes a head unit 2 (see FIG. 1), a nozzle control IC 3, a movement amount detection unit 4, a wireless communication unit 5, an external memory connection unit 6, an operation key 7, a display unit 8, A storage unit 9 and a control unit 10 are provided.

  The head unit 2 is configured using, for example, a thermal inkjet cartridge with nozzles that can be replaced when ink runs out, and includes a plurality of nozzles 2a (see FIG. 1) arranged in a direction orthogonal to the printing direction.

  As shown in FIG. 1, the plurality of nozzles 2 a are arranged on the lower surface of the printing apparatus 1, and are applied to a print object based on ink ejection control by a nozzle control IC 3 (see FIG. 2) according to the movement of the printing apparatus 1. Print graphic characters.

The movement amount detection unit 4 detects the movement amount of the head unit 2 in the main scanning direction.
As the movement amount detection device constituting the movement amount detection unit 4, for example, the same device as the movement amount detection device (LED type, laser type, ball type, etc.) applied to a mouse (computer input device) is used. be able to.

The wireless communication unit 5 is an interface that performs wireless communication (for example, Wi-Fi) with a terminal capable of wireless communication such as a smartphone or a personal computer.
Then, using the wireless communication unit 5, the user can cause the printing apparatus 1 to capture the user's print setting data (graphic character data to be printed, print mode, etc.).

  The user may input graphic character data to be printed in a form that is directly input to the printing apparatus 1, and the user selects the print mode by operating the operation key 7 or the like of the printing apparatus 1. Needless to say.

The external memory connection unit 6 is an external connection port for connecting an external memory (for example, a USB memory).
If user print setting data is stored in an external memory such as a USB memory, the external memory connection unit 6 is connected to the external memory so that the user's print setting data is taken into the printing apparatus 1. Can do.

The operation key 7 is, for example, a push button type operation switch disposed on the upper surface of the printing apparatus 1.
The operation keys 7 include, for example, a power key for turning on / off the power, a plurality of setting keys for performing various setting operations, a printing start key for starting printing, and the like.

The display unit 8 is a display screen made up of, for example, a liquid crystal screen disposed on the upper surface of the printing apparatus 1.
The display unit 8 may be a display screen including a liquid crystal screen having a touch panel function. For this reason, the display unit 8 may be configured to serve as one end of the operation key 7.

  The display unit 8 includes, for example, a status display of the printing apparatus 1 (for example, power ON / OFF, print mode, ink remaining amount, etc.) and operation guide display (for example, “Please read the print setting data”, “Print Please start "etc.) is displayed.

The storage unit 9 includes a memory such as a RAM or a ROM, and stores a program for operating the control unit 10, font data of graphic characters to be printed, print execution data for executing printing, and the like.
In addition, the storage unit 9 may temporarily store data generated under the control of the control unit 10.

  The control unit 10 generates print execution data for executing printing based on the user's print setting data, controls the nozzle 2a based on the print execution data and the detection value of the movement amount detection unit 4, and the head Causes part 2 to print graphic characters.

For example, after a graphic character to be printed is read as print setting data into the printing apparatus 1 and the user moves the printing apparatus 1 in the printing direction (main scanning direction) by hand, the graphic character is printed along the moving direction. Is done.
Conventionally, this type of printing apparatus 1 is intended for a case where the main scanning direction is substantially a straight line.

  By the way, for example, when labeling a disc-shaped recording medium 30 such as a CD, DVD, or BD, it is sometimes preferable to print in an arc instead of printing in a straight line. However, when the user moves the printing apparatus 1 by hand, there is a problem that it is difficult to perform printing so as to draw a beautiful arc.

Therefore, the printing apparatus 1 according to the embodiment of the present invention is provided at a position away from the head unit 2 as shown in FIG. 1 so that the user can scan the head unit 2 so as to easily draw an arc. The rotating unit 20 is provided as a rotation center O when the head unit 2 is rotated.
The rotating unit 20 includes a base 25 and a rotation center shaft 21 that is rotatably supported by a bearing or the like with respect to the base 25.

  Specifically, as illustrated in FIG. 1, the rotation unit 20 includes a rotation center shaft 21 that protrudes from the lower surface of the printing apparatus 1 and a rotation center distance that adjusts the distance between the rotation center shaft 21 and the head unit 2. An adjustment unit 22, a distance measurement unit 23 that measures the distance between the rotation center shaft 21 and the head unit 2, and a rotation center shaft storage unit 24 that stores the rotation center shaft 21 are provided.

As shown in FIG. 3, the rotation center shaft 21 has an outer diameter dimension that can be disposed in a round hole 31 formed in the central portion of the recording medium 30.
In addition, it is preferable that the rotation center shaft 21 has an outer diameter dimension that can be fitted into the round hole 31 and can be positioned with respect to the round hole 31.
However, the rotation center axis 21 is not limited to a cylindrical axis, and may be a prismatic axis or a thin axis such as a needle.
By using a thin shaft like a needle, not only a disc-shaped recording medium such as a CD, DVD, or BD with a round hole formed in the center but also a flat recording medium without a round hole. It becomes possible to fix the shaft and facilitate rotation.
When printing on a disc-shaped recording medium such as a CD, DVD, or BD with a thin shaft such as a needle, a jig for fixing the disc may be used.

  As shown in FIG. 1, the rotation center distance adjusting unit 22 is formed along the arrangement direction of the nozzles 2 a on the lower surface portion of the printing apparatus 1 and a base 25 that rotatably supports the rotation center shaft 21. Left and right guide grooves 26 that are slidably supported and an opening 27 that causes the rotation center shaft 21 to protrude from the lower surface of the printing apparatus 1, and based on the sliding operation of the base 25 along the guide grooves 26, the rotation center It is comprised so that the distance between the axis | shaft 21 and the head part 2 can be changed.

  In this embodiment, an appropriate frictional resistance is applied between the base 25 and the guide groove 26 so that the base 25 can be held at an arbitrary slide position by the frictional resistance. However, the sliding of the base 25 is restricted. A mechanism may be provided separately.

As shown in FIG. 1, the distance measuring unit 23 is arranged on the lower surface of the printing apparatus 1 so as to be parallel to the guide groove 26, and detects the slide position of the base 25.
As a distance measuring device constituting the distance measuring unit 23, for example, a variable resistor whose resistance value changes in accordance with a change in the position of the movable part interlocked with the base 25 is provided, and the distance is measured in accordance with the change in the resistance value. A linear potentiometer or a linear encoder that magnetically measures a change in the position of the movable portion interlocked with the base 25 can be used.

  The distance measuring unit 23 does not automatically measure the distance between the rotation center axis 21 and the head unit 2 but is a scale that allows the distance between the rotation center axis 21 and the head unit 2 to be read visually. In this case, the printing apparatus 1 is configured so that the scale value read by the user can be manually input.

As shown in FIG. 1, the rotation center shaft storage portion 24 includes a storage recess 28 that can store the rotation center shaft 21 between the left and right guide grooves 26.
That is, after the base 25 is extracted from the guide groove 26, when the base 25 is turned upside down and inserted into the guide groove 26, the rotation center shaft 21 is stored in the storage recess 28.
Accordingly, it is possible to avoid the rotation center shaft 21 from interfering when the head unit 2 is linearly scanned to perform printing.

As described above, since the printing apparatus 1 includes the rotation unit 20 (the rotation center axis 21) that serves as the rotation center O when the head unit 2 is rotated, the head unit 2 can easily draw an arc. Can be scanned.
Since the rotating unit 20 is configured to be rotatable as described above, the recording medium 30 can be rotated.
Therefore, the rotation of the head unit 2 with respect to the recording medium 30 has been described in the case where the head unit 2 is rotated. However, the recording medium 30 may be rotated. It may be a relative rotation with the part 2.

  Specifically, as shown in the flow of FIG. 3, the printing apparatus 1 is arranged and rotated so that the rotation center axis 21 of the rotation unit 20 is positioned in the round hole 31 formed in the center of the recording medium 30. If printing is performed while rotating the printing apparatus 1 with respect to the recording medium 30 as shown by the arrows in the middle diagram about the central axis 21, printing can be easily performed on the annular region A shown in the lower row. it can.

  Since the rotation center shaft 21 of the printing apparatus 1 is configured to be rotatable as described above, even if the rotation center shaft 21 is arranged so as to contact the recording medium to be printed, the head There is no problem in rotating the portion 2.

  Therefore, in FIG. 3 and the like, the case where the recording medium 30 has a round hole 31 at the center is shown, but the recording medium 30 to be printed does not have a hole like the round hole 31. The illustration of the present embodiment is merely a CD or the like having a round hole 31 as a print target (recording medium) considered to have many opportunities to print graphic characters in an arc shape. Please keep in mind.

  By the way, when printing is performed while moving the head portion 2 in an arc shape, the moving distance of the nozzle 2a changes between the inside and the outside of the arc-shaped region where printing is performed, so that the printing is performed while moving linearly. When the printing process is performed, fan-shaped distortion occurs in the printed graphic character as shown in the lower diagram of FIG.

  This distortion is caused when the graphic character is printed at a position far away from the rotation center O, among the nozzles 2a that actually eject ink, the nozzle 2a closest to the rotation center O and the outermost side away from the rotation center O. Since the difference in the moving distance from the nozzle 2a is small, it is inconspicuous, but it is conspicuous when a graphic character is printed at a position near the rotation center O, and it is desirable to eliminate the distortion.

  Therefore, in the printing apparatus 1, a linear printing mode selected when printing is performed while moving the head unit 2 linearly, and a rotational printing mode selected when printing is performed while moving the head unit 2 arcuately. As described below, when printing is performed while the head unit 2 is moved in an arc shape, the fan-shaped distortion of the printed graphic characters is eliminated. It has become.

  Specifically, when the rotation printing mode is selected, the control unit 10 performs various processes based on the polar coordinate start line with the rotation center O (the center of the rotation center axis 21) of the head unit 2 as the origin. Therefore, before describing specific processing, how each nozzle 2a is represented with reference to the polar coordinate start line will be described with reference to FIGS.

  As shown in FIG. 4, the polar coordinate start line with the rotation center O of the head unit 2 as the origin is set as an axis from the rotation center O to the nozzle 2a row of the head unit 2 in a state before the head unit 2 is rotated. This axis is the first reference axis (X), and the axis orthogonal to the first reference axis (X) is the second reference axis (Y).

When a certain point P rotates on the plane represented by the first reference axis (X) and the second reference axis (Y) while maintaining a certain distance from the rotation center O (origin), the point P To see what coordinates are represented.
Note that the movement of the point P described below is the same movement as the nozzle 2a rotating around the rotation center O (origin) without changing the distance from the rotation center O (origin).

  As shown in FIG. 5, when the point P moves on the circumference of the radius W, the rotation center φ is whatever the rotation angle φ from the first reference axis (X) that is the starting line. The distance between O and point P is W.

  Then, if the axis line connecting the movement start point where the point P starts to move and the rotation center O, that is, the starting line is defined as the first reference axis (X), two two-dimensional planes defining this point P are defined. The other of the orthogonal axes is determined as an axis orthogonal to the first reference axis (X), and the axis orthogonal to the first reference axis is defined as the second reference axis (Y).

  Here, assuming that the point P has moved to the position advanced by the rotation angle φ on the circumference of the radius W around the rotation center O, the first coordinate (X coordinate) of the moved point P is shown in FIG. As shown, it is a distance X1 from the rotation center O to the point B on the first reference axis (X).

  This point B is an intersection of the perpendicular and the first reference axis (X) when a perpendicular is drawn from the moved point P to the first reference axis (X), so that the rotation center O, the moved point P and A triangle having the point B as a vertex is a right triangle.

Therefore, the relationship of the formula (1) holds among the distance (radius W) between the rotation center O and the moved point P, the distance X1 between the rotation center O and the point B, and the rotation angle φ.
cos (φ) = X1 / W (1)

Then, when W is applied to both sides of the formula (1), the formula (1) is transformed as the formula (2), and the right side is in a state of only X1.
W × cos (φ) = X1 (2)
Here, since the distance X1 on the right side is the first coordinate (X coordinate) of the moved point P as described above, the first coordinate (X coordinate) is represented by W × cos (φ).

Next, the second coordinate (Y coordinate) of the moved point P will be examined with reference to FIG.
Similarly to the above, if the point P moves to the position advanced by the rotation angle φ on the circumference of the radius W with the rotation center O as the center, the second coordinate (Y coordinate) of the moved point P is as shown in FIG. 6, the distance Y1 from the rotation center O to the point C on the second reference axis (Y).

  As can be seen from FIG. 6, the distance Y1 is equal to the distance between the moved point P and the point B, and the triangle having the rotation center O, the moved point P and the point B as vertices is a right triangle. This is as already described.

Therefore, the distance between the rotation center O and the moved point P (radius W), the distance between the moved point P and point B (distance Y1), and the rotation angle φ are expressed by the following equation (3). A relationship is established.
sin (φ) = Y1 / W (3)

Then, when W is applied to both sides of the expression (3), the expression (3) is transformed as the expression (4), and the right side is in a state of only Y1.
W × sin (φ) = Y1 (4)
Here, since the distance Y1 on the right side is the second coordinate (Y coordinate) of the moved point P as described above, the second coordinate (Y coordinate) is represented by W × sin (φ).

  As described above, the point that moves on the radius W about the rotation center O is the first reference axis (X) that is the starting line connecting the rotation center O and the rotation start point, and the first reference axis (X) and the first reference axis (X). In the plane represented by the second reference axis (Y) orthogonal to the one reference axis (X), the coordinates (X, Y) are obtained using the rotation angle φ of the moving point from the first reference axis (X). Can be expressed as (W × cos (φ), W × sin (φ)).

  As mentioned earlier, when the distance from the rotation center O shown in FIG. 4 to the innermost nozzle 2a is the first distance r1, the movement of the nozzle 2a rotating around the rotation center O is as follows. This is the same as the movement of the point P that moves on the circumference of the radius whose distance from the rotation center O is the first distance r1.

  Therefore, if the rotation angle from the first reference axis (X) when the nozzle 2a rotates is the rotation angle φ, a plane represented by the first reference axis (X) and the second reference axis (Y). The coordinates (X, Y) of the nozzle 2a above are (r1 × cos (φ), r1 × sin (φ)).

  Similarly, in the case of the eighth nozzle 2a from the inside shown in FIG. 4, when the distance from the rotation center O is the second distance r2, the first nozzle 2a when the eighth nozzle 2a rotates around the rotation center O is the first. The coordinates (X, Y) of the eighth nozzle 2a on the plane represented by the reference axis (X) and the second reference axis (Y) are (r2 × cos (φ), r2 × sin (φ). )

  The first distance r1 from the rotation center O to the innermost nozzle 2a is a distance that can be acquired in advance. If the nozzles 2a are arranged at an interval d, the second distance r2 is obtained by r2 = r1 + 7d. It is done.

  As described above, on the assumption that the coordinates (X, Y) of each nozzle 2a are expressed, the processing procedure (printing flow) in the rotational printing mode of the control unit 10 will be described with reference to FIGS. This will be described with reference to FIG.

When the user sets a graphic character to be printed on the printing apparatus 1 and the rotation printing mode is selected, the printing flow of FIG. 7 is started.
The graphic characters to be printed are set from a terminal capable of wireless communication, such as a smartphone or a personal computer, using the wireless communication function (wireless communication unit 5) of the printing apparatus 1, for example.

  However, the graphic characters to be printed may be set by connecting an external memory storing graphic characters to be printed to the external memory connection unit 6 and reading from the external memory. (Key input) may be performed.

  As shown in FIG. 7, when the rotation printing mode process is started, the control unit 10 firstly has a first distance between the rotation center O shown in FIG. 4 and the nozzle 2a (1) closest to the rotation center O. r1 and the n-th distance rn between the rotation center O shown in FIG. 4 and the nozzle 2a (n) farthest from the rotation center O are calculated (step S1).

Next, when the head unit 2 shown in FIG. 4 is rotated, the control unit 10 has the inner circular orbit K1 drawn by the nozzle 2a (1) closest to the rotation center O and the farthest rotation center O shown in FIG. An assignment process is performed in which graphic characters to be printed are assigned to an area between the outer circular orbit Kn drawn by the nozzle 2a (n) (step S2).
The processing in step S2 is specifically a subroutine processing shown in FIG. 8, and will be described later.

  The inner circular orbit K1 is a circular orbit whose radius from the rotation center O is the first distance r1, and the outer circular orbit Kn is a circular orbit whose radius from the rotation center O is the nth distance rn. There is an annular area A sandwiched between these two circular orbits (the inner circular orbit K1 and the outer circular orbit Kn), which is an area to which graphic characters are assigned.

Next, the control unit 10 sets the polar coordinate start line with the rotation center O as the origin as the first reference axis (X), and the second reference orthogonal to the first reference axis (X) and the first reference axis (X). A position calculation process for calculating the dot position of the graphic character on the plane represented by the axis (Y) is performed (step S3).
The dot position of the graphic character is a position coordinate of a dot point where the nozzle 2a actually ejects ink in order to print the graphic character.

Next, the control unit 10 causes the head unit 2 to print a graphic character on the recording medium 30 based on the rotation angle of the head unit 2, the position of the nozzle 2a, and the dot position of the graphic character of the printing apparatus 1 (step S2). S4).
The processing in step 4 is specifically a subroutine processing shown in FIG. 9 and will be described later.

  The rotary printing mode process by the control unit 10 is completed as described above. However, the processes in steps S1 to S3 (including a subroutine) virtually set the first reference axis (X) and the second reference axis (Y). When printing is actually performed, a line connecting the nozzle 2a row from the rotation center O immediately before the printing apparatus 1 is placed on the recording medium 30 and rotated is used as a start line. Since the second reference axis (Y) may be adopted as the first reference axis (X) and the axis orthogonal to the first reference axis (X) may be used, before the printing apparatus 1 is actually placed on the recording medium 30 Processing can be completed.

Next, the process of step S2 in FIG. 7 will be described in more detail with reference to FIG.
As shown in FIG. 8, in the assignment process in step S2 of FIG. 7, the control unit 10 first divides the annular area A in the rotation direction based on the number m of graphic characters (including blanks) to be printed. A region dividing process is performed for the divided region Am (step S21).
For example, in the example shown in FIG. 4, since the print character is set to 8 and the blank is set to 2, the annular area A is divided into 10 divided areas Am by 10 dividing lines L passing through the rotation center O. Has been.

Next, as shown in FIG. 4, the control unit 10 sets the size of the graphic character within the divided area Am and is orthogonal to the tangent S that is in contact with the center position of the inner circular orbit K1 of the divided area Am. A process of assigning a graphic character to the divided area Am is performed with the direction CL as the height direction of the graphic character (step S22).
As shown in FIG. 4, the center position of the inner circular orbit K1 of the divided area Am is a position obtained by dividing the circumferential rear angle between the adjacent divided lines L so that θ1 = θ2.

Specifically, the size of the graphic character that can be accommodated in the divided area Am in step S22 is the largest rectangular area Ak that is located on the tangent line S and that can be accommodated in the divided area Am, as shown in FIG. Is a size that fits within the rectangular area Ak.
The largest rectangular area Ak that can be accommodated in the divided area Am is divided into two dividing lines L that are boundaries of the divided area Am when the tangent S that touches the center position of the inner circular orbit K1 of the divided area Am is drawn. An inner side (one side on the tangent line S) having the intersection with the tangent S as both ends, a pair of sides (two side sides) extending in a direction perpendicular to the one side from both ends of the one side, and 2 And one outer side parallel to one inner side with the intersection of one side and the outer circular orbit Kn as both ends.

Next, the process of step S4 in FIG. 7 will be described in more detail with reference to FIG.
As shown in FIG. 9, in the printing process of step S <b> 4 in FIG. 7, the control unit 10 firstly starts the rotation of the head unit 2 as the starting point and detects the movement amount of the head unit 2 (detection of the movement amount detection unit 4). Value), a rotation angle calculation process for calculating the rotation angle φ of the head unit 2 from the first reference axis (X) is performed (step S41).

More specifically, in the printing in the rotation printing mode, the movement amount detection unit 4 also moves in a circle around the rotation center O, so the distance D from the rotation center O to the movement amount detection unit 4 is the radius. The movement amount detection unit 4 moves on the circular orbit, and the length (circumference) of the circular orbit is 2πD (π is the circumference ratio).
That is, when the rotation is 360 degrees, the movement amount of the movement amount detection unit 4 is 2πD, and when the rotation is 90 degrees, the movement amount is ¼ (= πD / 2) of the circumferential movement amount.

On the contrary, when the current movement amount M is πD / 2, [πD / 2] / 2πD is 1/4, and it can be seen that the current movement amount M is at a 1/4 rotation position of 360 degrees.
Therefore, the current rotation angle φ is calculated by multiplying 360 ° by a value T (= M / 2πD) obtained by dividing the current movement amount M by 2πD.

  Next, the control unit 10 determines the first reference axis (X) and the second reference axis (Y) based on the first distance r1 to the nth distance rn and the rotation angle φ from the rotation center O to the plurality of nozzles 2a. Nozzle position calculation processing is performed to calculate the positions of the plurality of nozzles 2a on the plane represented by (Step S42).

  If the rotation angle φ is obtained, the coordinates (X, Y) on the plane represented by the first reference axis (X) and the second reference axis (Y) of the position of each nozzle 2a are obtained. That is, since the fact that the position of the nozzle 2a can be calculated has already been described, the description thereof is omitted.

Next, the control unit 10 displays the dot position of the graphic character on the plane represented by the first reference axis (X) and the second reference axis (Y), the first reference axis (X), and the second reference axis. Based on the positions of the plurality of nozzles 2a on the plane represented by the axis (Y), a process for causing the head unit 2 to print graphic characters on the recording medium 30 is executed (step S43).
Specifically, the graphic character is printed on the recording medium 30 by ejecting ink from the nozzle 2a at the timing when the dot position of the graphic character coincides with the position of the nozzle 2a.
Note that the subroutine shown in FIG. 9 (step S4 in FIG. 7) is actually a loop process that is repeatedly performed each time the rotation angle φ changes in accordance with the rotation of the head unit 2, and the graphic character to be printed is displayed. This is done until there is no more data.

Although the printing apparatus of the present invention has been described based on the specific embodiments, the present invention is not limited to the specific embodiments described above.
In the above-described embodiment, the case where only a character string is printed has been described. However, for example, a frame line surrounding the entire printed graphic character may be provided, or decoration such as an underline may be provided. .

  Specifically, in the case of the underline, the problem of distortion as in the case of a graphic character does not occur. Therefore, the nozzle 2a corresponding to the underline is continuously discharged while the nozzle 2a is moving. Can be done.

  In addition, since the problem of distortion does not occur in the frame line, ink is simultaneously ejected from a plurality of nozzles 2a corresponding to printing the vertical line at the start of the frame line (a line along the height direction of the graphic character). After that, the nozzles 2a corresponding to the inner and outer peripheral sides of the frame line are continuously ejected while the nozzle 2a is moving, and finally the vertical line at the end of the frame line If the ink is ejected from the plurality of nozzles 2a corresponding to the vertical line at the end of the frame line after the last graphic character is printed, the graphic character printed in a fan shape is printed. A frame that surrounds the outer periphery of the row in a fan shape can be formed.

  Furthermore, in the above embodiment, the rotation center shaft 21 is provided so that the center of the rotation center shaft 21 is located on the extension line of the nozzle 2a row, but the rotation center is at a position offset from the extension line of the nozzle 2a row. The rotation center shaft 21 may be provided so that the center of the shaft 21 is located.

In addition, in the above-described embodiment, as shown in FIG. 1, the case where there is one nozzle row in which a plurality of nozzles 2 a are arranged is shown, but a plurality of nozzle rows may be provided.
For example, three nozzle rows arranged in parallel may be provided so that each nozzle row corresponds to cyan, magenta, and yellow so that color printing can be performed.

In this case, for example, any two nozzle rows remaining as the nozzle rows (also referred to as reference nozzle rows) described in the above embodiment are subjected to data correction in consideration of deviation from the reference nozzle row. The printing in the rotational printing mode may be performed. Print data based on the rotation radius is individually created for each nozzle row, and the print start position of each nozzle row is determined based on the movement amount by the movement amount detection unit 4. You may control so that it may start at a fixed position.
Needless to say, the plurality of nozzle rows may be the same color, not limited to providing a plurality of nozzle rows for color printing.

  As described above, the present invention is not limited to the above-described embodiment, and various modifications and improvements are also included in the technical scope of the present invention. It is clear from the description of the range.

The invention described in the scope of claims attached to the application of this application will be added below. The item numbers of the claims described in the appendix are as in the scope of the claims initially attached to the application of this application.
<Claim 1>
A head unit having a plurality of nozzles for printing on a recording medium;
A rotation unit provided such that a distance from the head unit can be changed, and serving as a rotation center when the head unit is rotated relative to the recording medium;
A movement amount detection unit for detecting a relative movement amount of the head unit accompanying the rotation;
A control unit that controls the printing based on the movement amount of the head unit detected by the movement amount detection unit and a distance between the head unit and the rotation unit;
A printing apparatus comprising:
<Claim 2>
The controller is
Allocation processing for assigning the graphic character to be printed to an area between the inner circular orbit drawn by the nozzle closest to the rotation center and the outer circular orbit drawn by the nozzle farthest from the rotation center when the head portion is rotated When,
The dot of the graphic character on the plane represented by the first reference axis and the second reference axis orthogonal to the first reference axis, with the polar coordinate start line having the rotation center as the origin as the first reference axis A position calculation process for calculating a position;
The printing apparatus according to claim 1, wherein a printing process is performed to cause the head unit to print the graphic character on the recording medium based on the dot position.
<Claim 3>
The printing apparatus according to claim 2, wherein the first reference axis is an axis from the rotation center toward the head part in a state before the head part is rotated.
<Claim 4>
The controller is
A rotation angle calculation process for calculating a rotation angle of the head unit from the first reference axis based on the amount of movement of the head unit, starting from the start of rotation of the head unit;
Nozzle position calculation for calculating the positions of the plurality of nozzles on a plane represented by the first reference axis and the second reference axis based on the distance from the rotation center to the plurality of nozzles and the rotation angle. Processing,
Based on the dot positions on the plane represented by the first reference axis and the second reference axis, and the positions of the plurality of nozzles on the plane represented by the first reference axis and the second reference axis. The printing apparatus according to claim 2, further comprising: a process for causing the head unit to print the graphic character on the recording medium.
<Claim 5>
As the allocation process, the control unit
Based on the number of graphic characters, a region dividing process in which the region is divided into regions in the rotation direction;
The size of the graphic character is set to a size that fits within the divided region, and a direction perpendicular to a tangent line that touches the center position of the inner circular orbit of the divided region is defined as a height direction of the graphic character in the divided region. The printing apparatus according to any one of claims 2 to 4, wherein a process of assigning the graphic character is performed.
<Claim 6>
The printing according to claim 5, wherein the size is a size that fits in the rectangular area when a maximum rectangular area that has one side located on the tangent line and fits in the divided area is defined. apparatus.
<Claim 7>
The printing apparatus according to claim 1, further comprising a distance measuring unit that measures a distance between the rotation center and the nozzle that is closest to the rotation center.

DESCRIPTION OF SYMBOLS 1 Printing apparatus 2 Head part 2a Nozzle 3 Nozzle control IC
4 Movement amount detection unit 5 Wireless communication unit 6 External memory connection unit 7 Operation key 8 Display unit 9 Storage unit 10 Control unit 20 Rotation unit 21 Rotation center axis 22 Rotation center distance adjustment unit 23 Distance measurement unit 24 Rotation center axis storage unit 25 Base 26 Guide groove 27 Opening 28 Storage recess 30 Recording medium 31 Round hole

Claims (7)

A head unit having a plurality of nozzles for printing on a recording medium;
A rotation unit provided such that a distance from the head unit can be changed, and serving as a rotation center when the head unit is rotated relative to the recording medium;
A movement amount detection unit for detecting a relative movement amount of the head unit accompanying the rotation;
A control unit that controls the printing based on the movement amount of the head unit detected by the movement amount detection unit and a distance between the head unit and the rotation unit;
A printing apparatus comprising: The controller is
Allocation processing for assigning the graphic character to be printed to an area between the inner circular orbit drawn by the nozzle closest to the rotation center and the outer circular orbit drawn by the nozzle farthest from the rotation center when the head portion is rotated When,
The dot of the graphic character on the plane represented by the first reference axis and the second reference axis orthogonal to the first reference axis, with the polar coordinate start line having the rotation center as the origin as the first reference axis A position calculation process for calculating a position;
The printing apparatus according to claim 1, wherein a printing process is performed to cause the head unit to print the graphic character on the recording medium based on the dot position.   The printing apparatus according to claim 2, wherein the first reference axis is an axis from the rotation center toward the head part in a state before the head part is rotated. The controller is
A rotation angle calculation process for calculating a rotation angle of the head unit from the first reference axis based on the amount of movement of the head unit, starting from the start of rotation of the head unit;
Nozzle position calculation for calculating the positions of the plurality of nozzles on a plane represented by the first reference axis and the second reference axis based on the distance from the rotation center to the plurality of nozzles and the rotation angle. Processing,
Based on the dot positions on the plane represented by the first reference axis and the second reference axis, and the positions of the plurality of nozzles on the plane represented by the first reference axis and the second reference axis. The printing apparatus according to claim 2, further comprising: a process for causing the head unit to print the graphic character on the recording medium. As the allocation process, the control unit
Based on the number of graphic characters, a region dividing process in which the region is divided into regions in the rotation direction;
The size of the graphic character is set to a size that fits within the divided region, and a direction perpendicular to a tangent line that is in contact with the center position of the inner circular orbit of the divided region is defined as a height direction of the graphic character in the divided region. The printing apparatus according to any one of claims 2 to 4, wherein a process of assigning the graphic character is performed.   The printing according to claim 5, wherein the size is a size that fits in the rectangular area when a maximum rectangular area that has one side located on the tangent line and fits in the divided area is defined. apparatus.   The printing apparatus according to claim 1, further comprising a distance measuring unit that measures a distance between the rotation center and the nozzle that is closest to the rotation center.

Images