JP6516540B2 - Liquid jet head, information processing apparatus, and discharge speed correction method - Google Patents

Description

  The present invention relates to, for example, a liquid jet head, an information processing apparatus, and a discharge speed correction method.

  As a device for discharging a liquid onto a recording medium, a liquid discharge recording device is known which discharges droplets from a plurality of nozzles toward the recording medium. Some liquid ejection recording apparatuses include, for example, a liquid ejection head that ejects liquid as droplets of several to several tens of picoliters per droplet. Such a liquid discharge head is provided with a plurality of nozzles, and a piezoelectric element is driven by applying a drive pulse from an electrode to each nozzle to discharge droplets from the plurality of nozzles simultaneously. There is. In such a liquid discharge head, if the plurality of nozzles do not have the same discharge characteristics, the sizes and positions of the droplets landed on the recording medium vary even if the droplets are discharged onto the recording medium. It will cause unevenness. In reality, it is difficult to manufacture the nozzles so that they have the same discharge characteristics, and even if the same drive pulse is applied, the discharge characteristics vary, so it is necessary to correct this variation. A target technology has been proposed (see, for example, Patent Document 1).

Unexamined-Japanese-Patent No. 2009-189954

  However, although the technique described in Patent Document 1 enables correction regarding the discharge amount of droplets, among the problems of the variation regarding the discharge characteristics as described above, even if the same drive pulse is applied, the liquid There is also a problem that the discharge speed may vary. If the discharge speed is uneven, there is a problem that the landing position is deviated even if the liquid is discharged to land on the recording medium.

  The present invention has been made to solve the above-mentioned problems, and an object thereof is to provide a liquid jet head, an information processing apparatus, and a discharge speed correction method capable of correcting a variation in discharge speed. .

In order to solve the above problems, one aspect of the present invention is a liquid jet head that jets a liquid as droplets that land on a recording medium, and an application unit that applies a drive pulse having a voltage and a pulse width. A plurality of nozzles for discharging the droplets, wherein the piezoelectric element is driven by application of the drive pulse to each nozzle by the application unit, and the droplets are discharged at the discharge speed according to the drive pulse; Storing a correction pulse width for each relationship between the pulse width and the ejection speed, a storage unit that stores a head chip ejected from the nozzle, the pulse width for each of the nozzles, and a voltage value applied by the application unit; and correcting the pulse width memory, the two or more pulse widths different from each other is predetermined, and the discharge speed storage unit for taking a discharge rate measured for each of the nozzles, the discharge speed storage section taken Elaborate, based on the discharge rate of each of the nozzles in said predetermined are two or more pulse width different from each other, the change characteristic specifying portion which specifies the change characteristic for each of the nozzles, based on the identified the variation characteristics A correction pulse width selection unit which reads the correction pulse width corresponding to each of the nozzles from the correction pulse width storage unit and writes the correction pulse width in the storage unit; and a correction pulse width written in the storage unit by the correction pulse width selection unit. And a voltage value calculation unit that calculates a voltage value that makes the discharge velocity according to the predetermined discharge velocity predetermined and writes the voltage value in the storage unit.

  Further, according to one aspect of the present invention, in the invention described above, the correction pulse width selection unit corresponds to each of the nozzles based on a difference between discharge speeds at two or more different pulse widths which are determined in advance. The correction pulse width may be read out.

  Further, according to one aspect of the present invention, in the invention described above, the correction pulse width selection unit corresponds to each of the nozzles based on a classification according to an ejection speed in a predetermined pulse width. The width may be read out.

Further, according to one aspect of the present invention, there is provided a storage unit storing a plurality of nozzles, a pulse width for each of the nozzles, and a voltage value to be applied, wherein the piezoelectric element is driven by a drive pulse having the pulse width and the voltage value. An information processing apparatus for generating information stored in the storage unit in a liquid jet head which drives a liquid droplet ejection head from the nozzles at a discharge speed corresponding to the drive pulse, the pulse width and the discharge speed storing the correction pulse width for each relationship between the correction pulse width memory, and at least two pulse widths different from each other is predetermined, the discharge speed storage unit for taking a discharge rate measured for each of the nozzles, the discharge The variation characteristic is set for each of the nozzles based on the discharge speed for each of the nozzles at the two or more different predetermined pulse widths that are determined by the speed storage unit. A change characteristic identification unit for constant, based on the identified the change characteristic, and wherein the correction pulse width read out from the correction pulse width memory, written in the storage unit correcting the pulse width selecting unit corresponding to each said nozzle for A voltage value calculation unit that calculates a voltage value that sets the discharge speed according to the correction pulse width written in the storage unit by the correction pulse width selection unit to a predetermined discharge speed that is determined in advance, and writes the voltage value in the storage unit; It is an information processor characterized by having.

Further, according to one aspect of the present invention, a piezoelectric element is driven by a drive pulse having a plurality of nozzles, a pulse width for each of the nozzles, and a predetermined voltage value, and each of the nozzles is driven at an ejection speed corresponding to the drive pulse. a discharge speed correction method in a liquid ejecting head which ejects a liquid droplet from a nozzle, to be stored in the correction pulse width memory the correction pulse width for each change characteristics showing the relationship between the pulse width and the discharge speed, predetermined The discharge speed measured for each nozzle is taken in at two or more different pulse widths different from each other, and for each nozzle based on the discharge speed for each nozzle at the predetermined two or more different pulse widths determined in advance. to identify changes characteristics, based on the identified said variation characteristic, the correction pulse width corresponding to each said nozzle from the correction pulse width memory Out look, the discharge speed of the read-out the correction pulse width, a discharge speed correction method characterized by calculating the voltage value that the desired discharge speed, which is determined in advance.

  According to the present invention, it is possible to correct the variation in the discharge speed.

FIG. 2 is a perspective view showing a schematic configuration of a liquid jet head and a liquid jet recording apparatus according to an embodiment of the present invention. FIG. 6 is a perspective view showing a part of the configuration of a liquid jet head according to the same embodiment. FIG. 7 is an enlarged perspective view showing a head chip of the liquid jet head according to the same embodiment. FIG. 7 is an exploded perspective view of the head chip according to the same embodiment. It is a figure which shows the relationship between the change of the drive pulse by the same embodiment, and the deformation | transformation of a piezoelectric element. FIG. 2 is a block diagram showing an internal configuration of a liquid jet head according to the same embodiment. It is a graph (the 1) which shows the relation between the pulse width by the embodiment, and discharge speed. It is a graph (the 2) which shows the relationship between the pulse width by the embodiment, and discharge speed. It is a graph (the 3) which shows the relationship between the pulse width by the embodiment, and discharge speed. It is a figure which shows the data structure of the correction pulse width table by the embodiment. It is a flowchart which shows the flow of a process of the discharge speed correction method by the same embodiment. It is a graph which shows the discharge speed measured for every nozzle by two pulse widths by the same embodiment. It is a graph which shows the discharge speed in the state without the correction | amendment by the same embodiment. It is a figure explaining the classification to the speed group by the embodiment. It is a graph which shows the discharge speed in the state without correction | amendment by the same embodiment, and the discharge speed corrected. It is a graph which shows the discharge speed in the state without the correction | amendment by the same embodiment, the discharge speed corrected by the discharge speed and voltage which were correct | amended. It is a table | surface which compares the discharge speed in the state without the correction | amendment by the same embodiment, the discharge speed corrected by the correction, and the discharge speed corrected by voltage.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view showing a schematic configuration of a liquid jet head 4 and a liquid jet recording apparatus 1 according to the present embodiment. The liquid jet recording apparatus 1 supplies a liquid to a pair of transport mechanisms 2 and 3 that transport a recording medium S such as paper, a liquid jet head 4 that jets a liquid onto the recording medium S, and a liquid jet head 4. A liquid supply means 5 and a scanning means 6 for scanning the liquid jet head 4 in a direction (sub-scanning direction) substantially orthogonal to the conveyance direction (main scanning direction) of the recording medium S are provided. Although not shown, the liquid jet recording apparatus 1 is electrically connected to the transport mechanisms 2 and 3, the liquid jet head 4, the liquid supply means 5, the scanning means 6 and the like to mutually transmit and receive signals. A main control unit C is provided. Hereinafter, the sub-scanning direction will be described as an X direction, the main scanning direction as a Y direction, and a direction orthogonal to both the X direction and the Y direction as a Z direction.

  The pair of transport mechanisms 2 and 3 are provided with grid rollers 20 and 30 extending in the sub-scanning direction, pinch rollers 21 and 31 extending parallel to the grid rollers 20 and 30, and grids (not shown in detail). A drive mechanism such as a motor for rotating the rollers 20 and 30 about their axes is provided.

  The liquid supply means 5 includes a liquid container 50 containing a liquid, and a liquid supply pipe 51 connecting the liquid container 50 and the liquid jet head 4. A plurality of liquid containers 50 are provided. Specifically, liquid containers 50Y, 50M, 50C, and 50B in which four types of liquid of yellow, magenta, cyan, and black are stored are arranged side by side. A pump motor M (not shown) is provided for each of the liquid containers 50Y, 50M, 50C, and 50B, and can push and move the liquid to the liquid jet head 4 through the liquid supply pipe 51. The liquid supply pipe 51 is formed of a flexible hose having flexibility that can correspond to the operation of the liquid jet head 4 (carriage unit 62).

  The scanning means 6 includes a pair of guide rails 60, 61 extending in the sub scanning direction, a carriage unit 62 slidable along the pair of guide rails 60, 61, and the carriage unit 62 in the sub scanning direction. And a drive mechanism 63 for moving. The drive mechanism 63 rotationally drives a pair of pulleys 64 and 65 disposed between the pair of guide rails 60 and 61, an endless belt 66 wound between the pair of pulleys 64 and 65, and one pulley 64. And a drive motor 67.

  The pair of pulleys 64 and 65 are disposed between both ends of the pair of guide rails 60 and 61, respectively, and are spaced apart in the sub-scanning direction. The endless belt 66 is disposed between the pair of guide rails 60 and 61, and the carriage unit 62 is connected to the endless belt. A plurality of liquid jet heads 4 are mounted on the base end portion 62a of the carriage unit 62. Specifically, the liquid jet heads 4Y and 4M individually correspond to four types of liquid of yellow, magenta, cyan and black. , 4C, 4B are mounted side by side in the sub scanning direction.

  The liquid jet head 4 is mounted on the carriage unit 62 of the liquid jet recording apparatus 1 with the longitudinal direction (Y direction) aligned with the main scanning direction and the short side direction (X direction) aligned with the sub scanning direction. There is. Further, a plurality of liquid jet heads 4 are mounted on the carriage unit 62 side by side in the X direction. Then, recording is performed on the recording medium S by transporting the recording medium S in the Y direction and moving the carriage unit 62 in the X direction while ejecting ink droplets from the liquid jet head 4. .

  FIG. 2 is a perspective view showing the liquid jet head 4. The liquid jet head of the present embodiment jets a liquid as droplets D toward a recording medium S (see FIG. 1). As shown in FIG. 2, the liquid jet head 4 includes a mounting substrate 40, a head chip 41, a flow path substrate 42, a base plate 44, and a circuit substrate 45. The mounting substrate 40 and the base plate 44 may be separate or integrally formed. The mounting substrate 40 also has a mounting mechanism (not shown) for detachably mounting the liquid jet head 4 to the carriage unit 62.

  The flow path substrate 42 is attached to one surface side of the head chip 41. A flow passage (not shown) for flowing ink is formed inside the flow passage substrate 42, and an inlet 42 a communicating with the flow passage is formed on the upper surface of the flow passage substrate 42. A pressure adjustment unit (not shown) that absorbs pressure fluctuation of ink is connected to the inflow port 42a.

  The base plate 44 is erected substantially vertically on the upper surface of the mounting substrate 40, and the circuit substrate 45 is attached to the surface thereof. The circuit board 45 is formed with a control unit 45 a that controls the operation of the head chip 41. The circuit board 45 and the head chip 41 are electrically connected by a flexible board 46.

FIG. 3 is a perspective view showing a head chip. 4 is an exploded perspective view of the head chip 41. As shown in FIG. As shown in FIG. 3 and FIG. 4, the head chip 41 is divided in parallel by an ink chamber plate 16 in which an ink chamber 10 in which ink is stored is formed, and a piezoelectric element deformable by applying a voltage. An actuator plate 15 having a plurality of grooves 15b arranged therein, a nozzle plate 14 having a nozzle 13 for discharging micro droplets SD for forming droplets D toward the recording medium S, and a nozzle And a nozzle cap 8 for supporting the plate 14. The head chip 41 is attached to the mounting substrate 40 (see FIG. 2) with the nozzle plate 14 directed downward so that the recording surface of the recording medium S and the nozzle plate 14 are arranged in parallel.
Further, the head chip 41 is a so-called independent channel type head chip, and the slit forming wall 9 constitutes a groove to which the liquid is supplied and a groove to which the liquid is not supplied, and it is a conductive liquid The droplet D can be discharged without causing a short circuit accident. The actuator plate 15 is provided with electrodes 15c connected to the flexible substrate 46 along the side walls 15a of the grooves 15b.

FIG. 5 is a diagram showing the relationship between the change of the drive pulse applied to the electrode 15c and the deformation of the piezoelectric element constituting the side wall 15a. Below, the length of the application time of the voltage in application of a drive pulse is called pulse width. Specifically, in the example shown in FIG. 5, the pulse width is the time length from time t ₁ to t _2. At time t _0, since no voltage is applied to the electrode 15c, the shape of the groove 15b is rectangular. At time t _1, voltage is applied to the electrode 15c, deformed shape of the piezoelectric element, the side wall 15a is comprised groove 15b spreads the shape shown in FIG. The expansion of the groove 15b generates a negative pressure inside the groove 15b, and the ink is sucked from the ink chamber 10 into the groove 15b. In time t _2, the when the voltage is not applied, the side wall 15a is returned to its original shape. As a result, the ink sucked into the groove 15b is discharged as a droplet. The pulse width at which a droplet is discharged most efficiently in a certain groove-shaped discharge groove has a unique value according to the conditions such as the groove shape. In the discharge groove groups unified shape, the ejection rate during ejection, ideally would be determined and the length from time t ₁ is the width of the driving pulse to time t _2, the two values of the voltage value. However, in practice, due to variations in manufacturing the groove 15b, even if drive pulses of the same pulse width with the same voltage value are applied, variations occur in the droplet discharge speed.

  FIG. 6 is a block diagram showing an internal configuration of the liquid jet head 4 according to the present embodiment. The liquid jet head 4 includes a head chip 41, a control unit 45a, an application unit 73, a speed sensor 74, and the information processing apparatus 100. In the liquid jet head 4, the speed sensor 74 measures the discharge speed of the droplets discharged from each nozzle 13, and outputs the measured discharge speed to the jet control unit 70 for each nozzle 13. The application unit 73 generates a drive pulse for each nozzle 13 from the drive waveform generated by the waveform generation unit 72 based on the timing and voltage value given from the ejection control unit 70 and applies the generated drive pulse to the head chip 41. The head chip 41 discharges droplets from the nozzles 13 in accordance with the drive pulse applied by the applying unit 73.

  The control unit 45 a includes an injection control unit 70, a storage unit 71, and a waveform generation unit 72. The injection control unit 70 outputs a signal for requesting the start of injection to the waveform generation unit 72 and the application unit 73 at the timing of starting the injection. Further, the injection control unit 70 causes the waveform generation unit 72 to generate a drive waveform with the pulse width stored in the storage unit 71 for each nozzle 13. Then, the application unit 73 is controlled, and based on the drive waveform generated by the waveform generation unit 72, the drive pulse is applied with the voltage value stored in the storage unit 71. Further, the injection control unit 70 takes in the discharge speed of the droplets discharged from each nozzle 13 measured by the connected speed sensor 74 from the speed sensor 74, and outputs it to the information processing apparatus 100. The waveform generation unit 72 generates a drive waveform based on the value of the pulse width for each nozzle 13 stored in the storage unit 71, and outputs the drive waveform to the application unit 73. The storage unit 71 stores the voltage value applied to the application unit 73 and the pulse width value for each nozzle 13.

  The information processing apparatus 100 corrects the pulse width for each nozzle 13, calculates the voltage value applied by the application unit 73, and corrects the pulse width and voltage value corrected in the storage unit 71 of the control unit 45a of the liquid jet head 4. The device used to write The information processing apparatus 100 may be configured as the same circuit as the control unit 45a, or may be configured as another circuit. The information processing apparatus 100 includes a correction pulse width storage unit 101, an ejection speed storage unit 102, a change characteristic specification unit 103, a speed group classification unit 104, a correction pulse width selection unit 105, and a voltage value calculation unit 106. Prepare.

  The ejection speed storage unit 102 outputs information on the pulse width of the measurement target to the ejection control unit 70, and takes in information on the ejection speed for each nozzle 13 output from the ejection control unit 70 as a response. The variation characteristic specifying unit 103 calculates, for each of the nozzles 13, identification information that specifies the variation characteristic derived from the ejection velocity, based on the ejection velocity taken in by the ejection velocity accumulation unit 102. Here, the change characteristic means the tendency of the change of the discharge speed according to the change of the pulse width. Further, in the present embodiment, the specific information is, as will be described later, the difference between the ejection speeds at two different predetermined pulse widths. The velocity group classification unit 104 classifies the nozzles 13 into velocity groups based on the ejection velocity taken in by the ejection velocity accumulation unit 102. The speed group is a group classified by division of predetermined speed values. The correction pulse width selection unit 105 corrects the correction pulse width of each nozzle 13 based on the specific information of the change characteristic specified by the change characteristic specification unit 103 and the speed group classified by the speed group classification unit 104. It selects from the correction pulse width table of the part 101. The correction pulse width is a pulse width selected for each nozzle 13, and is a pulse width at which the discharge speed when applying the same voltage is substantially uniform among the nozzles 13. The voltage value calculation unit 106 calculates a voltage value that makes the average value of the ejection speeds obtained by the correction pulse width selected by the correction pulse width selection unit 105 a desired ejection speed that is determined in advance. The correction pulse width storage unit 101 stores a correction pulse width table in advance.

  Hereinafter, the change characteristic of the nozzle 13 and the correction pulse width table will be described. FIG. 7 is a graph showing the relationship between the pulse width of the drive pulse applied to the head chip 41 by the applying unit 73 and the discharge speed of the droplet discharged from the nozzle 13. The graphs indicated by the marks of “Δ”, “◆ (hatching)” and “■” are driving with pulse widths of 7.7 μsec, 8.0 μsec, and 8.2 μsec, respectively. It shows three nozzles 13 where peaks of the discharge speed appear when a pulse is applied. As described above, since the change characteristic of the discharge speed with respect to the pulse width is different for each nozzle 13, even if the drive pulse having the same pulse width is applied, the discharge speed will vary.

  Although there are variations in the change characteristics of the pulse width and the ejection speed for each nozzle 13, the variation is not significantly different for each nozzle 13. As shown in FIG. 7, the change characteristics of the pulse width and the discharge speed are characteristics that can be approximated by a convex upward quadratic curve. Further, the change characteristic of the nozzle 13 indicated by "-" and the change characteristic of the nozzle 13 indicated by "-" have a pulse width of around 7.0 to 8.4 [μsec], 7.0 A discharge speed of about [m / sec] is obtained, and has similar change characteristics. Therefore, if it is possible to store information of several representative change characteristics and identify to which change characteristics the change characteristics of each nozzle 13 are similar, the change characteristics of each nozzle 13 are individually measured. It is possible to suppress the variation in the discharge speed of the droplets discharged from the respective nozzles 13 without performing the process.

FIG. 8 is a diagram showing a generalized difference between the change characteristics shown in FIG. As shown in FIG. 8, even if the positions of the discharge velocity peaks have the same pulse width value, there is a difference in the slope of the change characteristic. As a method of identifying which change characteristic is similar to the peak position or the position near the peak and the position away from the peak position, the droplet can be discharged normally and the discharge velocity can be measured. There is a method of measuring the discharge speed at two points with the position and determining by the difference. Here, for example, it is assumed that the discharge speed at two pulse widths of 8.2 [μsec] near the peak and 10.2 [μsec] slightly apart is measured as two points. The difference between the two points in each of the nozzles α, β, and γ is 0.6, 1.0, and 1.4, and the similar change characteristics are identified depending on which of these values is close. After specifying the change characteristics, in order to make the ejection speed equal to “T”, the pulse widths are 10.0 [μsec], 9.8 [μsec], and 9.4 [Prior to each of the nozzles α, β, and γ. The discharge speed can be made uniform by setting [mu] sec.
As a range of two points to be measured, any position may be used as long as it is a portion on the right side from the peak of the upward convex quadratic curve shown in FIG. 7 to FIG. On the other hand, a position of about 0.8 to 1.0 times and a position of about 1.5 to 1.7 times the pulse width at the peak of the ejection speed are desirable.

  The difference in the relationship between the pulse width and the discharge speed is the difference in discharge speed obtained even if the value of the peak pulse width is the same as shown in FIG. 9 other than the difference as shown in FIG. There are things that occur. In the case of such a difference in characteristics, for example, in order to achieve the same ejection speed as the nozzle A, the nozzle B needs to have a pulse width of 9.4 [μsec], and the nozzles C, D, E, F It is necessary to increase the pulse width little by little in the order of 9.8, 10.0, 10.2, 10.4 [μsec]. In the actual change characteristics of the nozzle, the difference between the change characteristics described with reference to FIG. 8 and the difference between the change characteristics described with reference to FIG. 9 are mixed, and as shown in FIG. There is a slight deviation in the position where the velocity peak appears.

  FIG. 10 is a view showing an example of the data configuration of the correction pulse width table. The correction pulse width table shown in FIG. 10 is a correction to correct droplets to be ejected at substantially the same ejection speed based on the difference between the pulse width of each nozzle 13 and the change characteristic of the ejection speed shown in FIG. It stores the value of the pulse width. In FIG. 10, “waveform group No.” on the vertical axis indicates a waveform group corresponding to the difference in discharge speed between nozzles when a drive pulse having the same pulse width is applied. That is, “waveform group No.” indicates a waveform group to be applied to each nozzle speed group. For example, the waveform group 1 represents the pulse width applied to the nozzle A having a slow discharge speed shown in FIG. The waveform groups 2 and 3 show pulse widths applied to the nozzle B, the waveform group 4 to the nozzle C, the waveforms 5 and 6 to the nozzle D, the waveform group 7 to the nozzle E, and the waveform group 8 to the nozzle F.

The velocity difference on the horizontal axis corresponds to the difference in the slope of the change characteristic shown in FIG. 8, and here, for example, the pulse widths at the two points of 8.2 [μsec] and 10.2 [μsec] It is classified by the difference in speed. That is, if the difference between the discharge speeds at two points is 0.6, then the selection will be from the leftmost column, and if the difference between the discharge speeds is 0.8, 1.0, 1.2, and 1.4 Each will be selected from the corresponding column.
When selecting a row corresponding to each nozzle based on the difference between the discharge speeds at two points of 8.2 [μsec] and 10.2 [μsec], 0.6, 0.8, 1.0 , 1.2, or 1.4, etc., and row selection is performed.

For example, in the classification of the waveform group on the vertical axis, it is assumed that the waveform group 5 is classified. For the nozzles α, β and γ shown in FIG. 8, the difference between the discharge speeds at two points of 8.2 μsec and 10.2 μsec is 0.6, 1.0 and 1.4, respectively. is there. At this time, referring to the correction pulse width table of FIG. 10 and selecting the corresponding row and column values, 10.0 [μsec], 9.8 [μsec] and 9.4 [μsec] are obtained, and these pulses are obtained. If drive pulses of a width are applied to the nozzles α, β and γ, theoretically, the same ejection speed will be obtained. In reality, since the classification of the discharge speed on the vertical axis and the classification based on the difference between the discharge speeds at two points on the horizontal axis include errors, they do not have the same discharge speed, but within a certain error range Almost the same discharge speed will be obtained.
In the example described above, the case of selecting the correction pulse width based on the difference between the discharge speeds at the pulse widths of two different points has been described, but the present invention is not limited thereto. For example, the correction pulse width may be selected based on the difference between the pulse widths of three or more different points. Thus, the inclination of the change characteristic can be specified more accurately, and the accuracy of the correction of the ejection speed can be further improved.

(Discharge speed correction method)
Next, a method of correcting the discharge speed for reducing the variation in the discharge speed for the plurality of nozzles 13 will be described with reference to FIGS. FIG. 11 is a flowchart showing pulse width selection processing. First, the ejection speed storage unit 102 of the information processing apparatus 100 causes the ejection control unit 70 to drive the head chip 41 with pulse widths of 8.2 [μsec] and 10.2 [μsec] as initial waveforms. The pulse is applied by the application unit 73, and a request signal for causing the velocity sensor 74 to measure the ejection velocity is output. When the injection control unit 70 receives the request signal, the injection control unit 70 first causes the waveform generation unit 72 to generate a waveform having a pulse width of 8.2 [μsec]. When the applying unit 73 applies a drive pulse having a pulse width of 8.2 μsec to the head chip 41 based on the waveform of a pulse width of 8.2 μsec generated by the waveform generation unit 72, each nozzle Droplets are discharged from 13.

  The speed sensor 74 measures the discharge speed of the droplets discharged from each nozzle 13, associates the measured discharge speed with the nozzle number of the nozzle 13, and outputs it to the injection control unit 70. Next, the injection control unit 70 causes the waveform generation unit 72 to generate a waveform having a pulse width of 10.2 [μsec]. Then, the ejection control unit 70 causes the applying unit 73 to apply a drive pulse having a pulse width of 10.2 [μsec] to the head chip 41. The velocity sensor 74 measures the ejection velocity of the droplets ejected from the nozzle 13 by the driving pulse having a pulse width of 10.2 [μsec], associates the measured ejection velocity with the nozzle number of the nozzle 13, and controls the ejection control unit Output to 70. The ejection control unit 70 discharges the ejection speed of each nozzle 13 when the pulse width is 8.2 μsec and the ejection speed of each nozzle 13 when the pulse width is 10.2 μsec. It outputs to 102 (step S1).

  FIG. 12 shows the discharge speed for each nozzle 13 when the pulse width is 8.2 [μsec] and the discharge for each nozzle 13 when the pulse width is 10.2 [μsec], which the discharge speed storage unit 102 takes in. It is a graph showing speed. In this graph, the horizontal axis indicates the nozzle number, and the vertical axis indicates the discharge speed. The nozzle numbers exist from the 2nd to the 254th. “◆” is the change characteristic when a drive pulse with a pulse width of 8.2 μsec is applied, and “Δ” is a drive pulse with a pulse width of 10.2 μsec. Change characteristics of The variation characteristic specifying unit 103 applies, for each nozzle 13, a discharge pulse when a drive pulse with a pulse width of 8.2 [μsec] is applied and a drive pulse with a pulse width of 10.2 [μsec]. The difference between the ejection speeds in the case is calculated (step S2).

FIG. 13 is a graph showing the distribution of the discharge speed when a drive pulse having a pulse width of 8.2 [μsec] is applied. The horizontal axis represents the nozzle number, and the vertical axis represents the discharge speed. As shown in FIG. 13, while the discharge speed of the central nozzle 13 is high, the discharge speed decreases as it approaches the end, and the discharge speed tends to increase again near both ends. The speed group classification unit 104 of the information processing apparatus 100 divides the nozzles 13 into groups according to the value of the discharge speed, as shown in FIG. 14 (step S3). For example, waveform groups 1 to 8 shown in FIG. 10 are respectively applied to the speed groups 1 to 8 shown in FIG. At this time, the speed group is divided such that the nozzles 13 having the slowest discharge speed are classified into the speed group 1. In this example, the discharge speed is divided into sections of 6.0 [m / sec] to 0.4 [m / sec], and all the nozzles 13 can be classified up to the speed group 5.
The line segment 200 in FIG. 14 divides the division into four by the nozzle number, calculates the average value of the discharge speed in the division, and displays it on a graph. The sections have nozzle numbers ranging from 2 to 65, 66 to 129, 130 to 193, and 194 to 254, respectively. Further, FIG. 14 shows an example of classification into eight speed groups, but the classification of speed groups may be seven or less, or nine or more.

  The reason why the nozzles 13 having the slowest ejection speed are classified into the speed group 1 in step S3 is that the nozzles 13 having the slowest ejection speed can not eject droplets faster than the ejection speed at the peak. That is, as shown in FIG. 8 and FIG. 9, to align the discharge speed of the group having the slowest discharge speed can be performed by changing the pulse width to reduce the speed in the group having the high discharge speed. . On the other hand, when trying to make the discharge speed of the group with the slow discharge speed equal to the discharge speed of the group with the fast discharge speed, it can not be made just by changing the pulse width. This is because it is necessary to perform processing such as increasing the voltage. Therefore, considering the technical side of the circuit and the cost of manufacturing the circuit, it is necessary to change the pulse width of the liquid jet head 4 rather than reducing the variation in the discharge speed with the change of the circuit configuration. It is desirable to select a method that can reduce the variation in discharge speed only by changing.

  The correction pulse width selection unit 105 uses the correction pulse width table stored in the correction pulse width storage unit 101 based on the speed group classified by the speed group classification unit 104 and the difference calculated by the change characteristic specification unit 103. refer. For example, when the waveform group 1 is classified into the velocity group 1 to which the waveform group 1 is applied, a pulse width of 8.2 [μsec] is selected for any velocity difference. In the example of the change characteristics in FIG. 8 and FIG. 9, the pulse width 8.2 [μsec] is the pulse width at the position where the ejection velocity peaks, and the ejection velocity is applied to the nozzle 13 of the slowest group. The pulse width at which the peak is given will be given. On the other hand, when the waveform group 5 is classified into the speed group 5 to which the waveform group 5 is applied, the change characteristic as shown in the nozzle D of FIG. 9 is obtained. Therefore, a difference in magnitude of P occurs in the ejection speed between the nozzle A to which the waveform group 1 is applied and the nozzle D to which the waveform group 5 is applied. When this is shown in FIG. 8, the discharge speed is made equal to the position T where the discharge speed is reduced by P, and the correction pulse width of the change characteristic corresponding to the speed difference of the discharge speed is selected. For example, when the velocity difference is 0.6, a correction pulse width of 10.0 [μsec] will be selected.

  In this manner, the correction pulse width selection unit 105 selects and selects the correction pulse width of each nozzle 13 with reference to the correction pulse width table, and at the same time, the ejection control unit 70 The selected correction pulse width is written (step S4). Hereinafter, the waveform of the correction pulse width selected by the correction pulse width selection unit 105 may be referred to as a correction waveform. FIG. 15 is a diagram showing the distribution of the discharge speed based on the correction waveform selected by the correction pulse width selection unit 105 for each nozzle 13. In FIG. 15, "-" indicates the discharge speed for each nozzle 13 when the initial waveform having the same pulse width determined in advance is applied. That is, "-" indicates the discharge speed of each nozzle 13 fetched by the discharge speed storage unit 102. Also, “■ (hatching)” indicates the discharge speed for each nozzle 13 when the correction waveform is applied. As shown in FIG. 15, it can be seen that the discharge speed of the nozzle 13 having a high discharge speed near the center is corrected, and as a whole, it is corrected near the speed group 2. Here, while the correction is performed according to the discharge speed of the nozzle 13 of the speed group 1, the correction to the vicinity of the speed group 2 is, as described above, the classification of the discharge speed on the vertical axis and This is because an error is included in the classification based on the difference in discharge speed at two points on the horizontal axis.

  The voltage value calculation unit 106 calculates the average value of the discharge speed obtained by the corrected correction pulse width, and discharges at a desired discharge speed based on the calculated average value and the desired discharge speed determined in advance. Calculate the voltage value. The voltage value calculation unit 106 writes the calculated voltage value in the storage unit 71 through the injection control unit 70 (step S5). In FIG. 16, "-" indicates the discharge speed for each nozzle 13 when the initial waveform (same pulse width) is applied. “H” (hatching) indicates the discharge speed for each nozzle 13 when the correction waveform is applied. “Δ” indicates the discharge speed of each nozzle 13 when a drive pulse (voltage correction pulse) whose correction waveform is adjusted by the voltage value calculated by the voltage value calculation unit 106 is applied. As shown in FIG. 16, when “■” and “Δ” are compared, the discharge speed indicated by “■” is in the vicinity of 6.6 [m / sec], while “Δ” The discharge speed shown is around 7.0 [m / sec], and it can be seen that the speed is generally increased. In FIG. 16, line segments 201 and 202 are divided into four sections according to the nozzle number, as in the case of line segment 200, and the average values of the discharge speeds in the sections are calculated and displayed in a graph. is there.

  FIG. 17 is a table showing numerically the values indicated by line segments 200, 201, 202 corresponding to the initial waveform, the correction waveform, and the voltage correction pulse shown in FIG. The horizontal axis represents, in order, the four nozzle numbers 2 to 65, 66 to 129, 130 to 193, and 194 to 254, and the average value in each of the divisions is shown. "Maximum value" and "minimum value" indicate the maximum and minimum values of the calculated average value, and "maximum value-minimum value" has a value obtained by subtracting the minimum value from the maximum value It is shown and "%" shows the value of the percentage which divided the difference of the maximum and the minimum by the minimum. As indicated by the value of "maximum value-minimum value", the initial waveform has a variation of 0.63, while the correction waveform has 0.07 and the voltage correction pulse has 0.05. It can be seen that the variation in speed is reduced.

  According to the configuration of the above embodiment, a representative change characteristic is selected from the change characteristic of the ejection speed with respect to the pulse width different for each nozzle 13, and a correction pulse width table is generated in advance based on the selected change characteristic. The nozzle 13 discharges a droplet to identify which of the representative change characteristics selected from the discharge speed is similar. Further, each nozzle 13 is classified into several speed groups from the measured discharge speed, and the correction pulse width is selected from the correction pulse width table based on the classified speed groups and change characteristics. As a result, the discharge speed of the nozzle 13 having a high discharge speed can be made equal to the discharge speed of the nozzle 13 having a low discharge speed. And the average value of the discharge speed discharged from all the nozzles 13 calculates the voltage value used as a desired discharge speed. As a result, it is possible to set a desired discharge speed while correcting the variation in the discharge speed.

  Further, according to the configuration of the above-described embodiment, some representative change characteristics are selected in advance, and the pulse width is corrected based on which one of them is approximated. Therefore, it is not necessary to measure the change characteristic of the discharge speed with respect to the pulse width of the drive pulse for each nozzle 13. Therefore, it is possible to reduce the human and time costs required to measure the change characteristics of the individual nozzles 13. Further, in the configuration of the above embodiment, since the correction is made to approximate typical change characteristics, the ejection speed does not become the same speed completely, but an error including a reasonable error It will be in the diffused state. On the other hand, if individual change characteristics of the nozzle 13 are measured and correction is made so that the discharge speed is completely the same, it will be very noticeable if a shift at one point occurs. In the configuration of the present embodiment, since a moderate error is included, there is an effect that it is difficult to be noticeable even if a slight deviation occurs.

  In the configuration of the above embodiment, the variation characteristic specifying unit 103 characterizes the variation characteristic from the difference between the ejection speed at a pulse width of 8.2 μsec and the pulse width of 10.2 μsec. Although the configuration is taken, the present invention is not limited to the embodiment. For example, a method may be used in which the value of the ejection velocity at pulse widths of three or more points is measured, and which of the upward convex quadratic curves is approximated to specify the change characteristic.

  In the configuration of the above embodiment, the velocity group classification unit 104 classifies the nozzles 13 into velocity groups according to the ejection velocity when a drive pulse having a pulse width of 8.2 [μsec] is applied. However, the present invention is not limited to the embodiment. For example, if the discharge speed can be measured in all the nozzles 13 and the pulse width is larger than the pulse width at which the peak of the discharge speed appears, pulse widths other than 8.2 [μsec] are used for speed group classification. It is also good. In that case, the data preset in the correction pulse width table stored in the correction pulse width storage unit 101 needs to be changed to data corresponding to the pulse width used for classification. The reason for setting the value larger than the pulse width at which the peak of the ejection speed appears is that if the value smaller than the pulse width is selected, the ejection becomes unstable.

  Further, in the configuration of the above embodiment, the information processing apparatus 100 is provided inside the liquid jet head 4, but the embodiment of the present invention is not limited to the configuration. For example, the information processing apparatus 100 may be connected to the control unit 45 a of the liquid jet head 4 as a separate apparatus. When the information processing apparatus 100 is configured integrally with the control unit 45a, the user can correct the discharge speed after shipping. On the other hand, when the information processing apparatus 100 is another apparatus, information for each nozzle 13 written in the storage unit 71 of the plurality of liquid jet heads 4 can be generated using one information processing apparatus 100. .

  The information processing apparatus 100 in the embodiment described above may be realized by a computer. In that case, a program for realizing this function may be recorded in a computer readable recording medium, and the program recorded in the recording medium may be read and executed by a computer system. Here, the “computer system” includes an OS and hardware such as peripheral devices. The term "computer-readable recording medium" refers to a storage medium such as a flexible disk, a magneto-optical disk, a ROM, a portable medium such as a ROM or a CD-ROM, or a hard disk built in a computer system. Furthermore, “computer-readable recording medium” dynamically holds a program for a short time, like a communication line in the case of transmitting a program via a network such as the Internet or a communication line such as a telephone line. It may also include one that holds a program for a certain period of time, such as volatile memory in a computer system that becomes a server or a client in that case. Further, the program may be for realizing a part of the functions described above, or may be realized in combination with the program already recorded in the computer system. It may be realized using a programmable logic device such as an FPGA (Field Programmable Gate Array).

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design and the like within the scope of the present invention.

4 liquid jet head 13 nozzle 41 head chip 45a control unit 70 injection control unit 71 storage unit 72 waveform generation unit 73 application unit 74 speed sensor 100 information processing device 101 correction pulse width storage unit 102 discharge speed storage unit 103 change characteristic specification unit 104 Speed group classification unit 105 Correction pulse width selection unit 106 Voltage value calculation unit

Claims (4)

A liquid jet head that jets liquid as droplets that land on a recording medium, comprising:
An application unit that applies a drive pulse having a voltage and a pulse width;
The piezoelectric element is driven by the application of the drive pulse to each nozzle by the application unit, and the droplet is discharged from the nozzle at a discharge speed corresponding to the drive pulse. And a head chip for discharging
A storage unit configured to store the pulse width of each nozzle and a voltage value applied by the application unit;
A correction pulse width storage unit that stores a correction pulse width for each relationship between the pulse width and the ejection speed;
An ejection speed storage unit for acquiring an ejection speed measured for each of the nozzles at predetermined two or more different pulse widths ;
A change characteristic specifying unit that specifies a change characteristic for each of the nozzles based on the discharge speed for each of the nozzles at the two or more different predetermined pulse widths, which are taken in by the discharge speed storage unit;
A correction pulse width selection unit that reads the correction pulse width corresponding to each of the nozzles from the correction pulse width storage unit based on the change characteristic identified by the change characteristic identification unit; and writes the correction pulse width in the storage unit;
A voltage value calculation unit that calculates a voltage value that sets a discharge speed based on the correction pulse width written in the storage unit by the correction pulse width selection unit to a predetermined discharge speed, and writes the voltage value in the storage unit;
A liquid jet head comprising: The correction pulse width selection unit
The liquid jet head according to claim 1, wherein the correction pulse width corresponding to each of the nozzles is read out based on classification according to the discharge speed at a predetermined pulse width. A plurality of nozzles, a pulse width for each of the nozzles, and a storage unit for storing a voltage value to be applied, the piezoelectric element is driven by a drive pulse having the pulse width and the voltage value, and the drive pulse is generated. An information processing apparatus that generates information stored in the storage unit of a liquid jet head that ejects droplets from each nozzle at a corresponding ejection speed,
A correction pulse width storage unit that stores a correction pulse width for each relationship between the pulse width and the ejection speed;
An ejection speed storage unit for acquiring an ejection speed measured for each of the nozzles at predetermined two or more different pulse widths ;
A change characteristic specifying unit that specifies a change characteristic for each of the nozzles based on the discharge speed for each of the nozzles at the two or more different predetermined pulse widths, which are taken in by the discharge speed storage unit;
A correction pulse width selection unit that reads the correction pulse width corresponding to each of the nozzles from the correction pulse width storage unit based on the change characteristic identified by the change characteristic identification unit; and writes the correction pulse width in the storage unit;
A voltage value calculation unit that calculates a voltage value that sets a discharge speed based on the correction pulse width written in the storage unit by the correction pulse width selection unit to a predetermined discharge speed, and writes the voltage value in the storage unit;
An information processing apparatus comprising: A liquid jet that drives a piezoelectric element by a drive pulse having a plurality of nozzles, a pulse width for each of the nozzles, and a predetermined voltage value, and ejects droplets from each nozzle at a discharge speed corresponding to the drive pulse A method for correcting the discharge speed of a head, comprising
The correction pulse width is stored in the correction pulse width storage unit for each change characteristic indicating the relationship between the pulse width and the ejection speed.
The discharge velocity measured for each of the nozzles is captured at two or more different pulse widths that are predetermined.
The variation characteristic is specified for each of the nozzles based on the discharge speed for each of the nozzles at two or more different pulse widths which are determined in advance.
The correction pulse width corresponding to each of the nozzles is read out from the correction pulse width storage unit based on the specified change characteristic .
A discharge velocity correction method, comprising: calculating a voltage value that causes a discharge velocity based on the read correction pulse width to be a predetermined desired discharge velocity.

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