JP4117078B2 - Inkjet recording device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a continuous ink jet recording apparatus configured to deflect ink particles ejected from ejection nozzles by a necessary amount and send them out to be printed on a target to form a desired pattern.
[0002]
[Prior art]
Conventionally, continuous ink jet recording apparatuses have been widely used as convenient recording apparatuses for forming various patterns such as characters and figures on various industrial products. FIG. 7 is a schematic diagram illustrating a configuration of a recording head provided in a continuous-type inkjet recording apparatus. As shown in the figure, the recording head 2 includes an ejection nozzle 20, a gutter 21, a charging electrode 22, and a deflection electrode 23 inside a housing 24 having a rectangular box shape.
[0003]
A liquid supply pipe 3a is connected to the ejection nozzle 20, and an ink tube 30 and a solvent tube 31 are connected to the liquid supply pipe 3a by separate electromagnetic on-off valves K. ₁ , K ₂ It is connected so that it can be switched by opening and closing, and the inside of the injection nozzle 20 has an electromagnetic on-off valve K ₁ Is opened, ink for recording is supplied through the ink tube 30 and the liquid supply pipe 3a, and the electromagnetic on-off valve K ₂ When the ink is opened, the solvent of the ink is supplied through the solvent tube 31 and the liquid supply pipe 3a, and these (ink or solvent) pass through the small-diameter ejection holes provided on one side of the ejection nozzle 20, It is injected as shown by an arrow.
[0004]
The gutter 21 is disposed so as to face the injection nozzle 20 in the injection direction as described above. A collection tube 32 is connected to the gutter 21 so that the ink or the solvent that is jetted straight from the jet nozzle 20 reaches the gutter 21 and is captured and collected in the collection tube 32. It is. A solvent recovery tube 33 is connected to the injection nozzle 20. The solvent recovery tube 33 is opened when a solvent is supplied to the inside of the injection nozzle 20, and most of the solvent is recovered in the solvent recovery tube 33. The charging electrode 22 and the deflection electrode 23 are arranged in parallel along an injection path from the injection nozzle 20 to the gutter 21.
[0005]
In the recording head 2 configured as described above, the electromagnetic on-off valve K ₁ When the ink tube 30 is connected to the liquid supply pipe 3a, the ink maintained at a predetermined pressure is introduced into the ejection nozzle 20, and this ink is ejected at a predetermined speed through the ejection holes. The The ejection nozzle 20 includes therein a piezo vibrator 20a that vibrates self-excited by application of a high frequency voltage. When the piezo vibrator 20a is vibrated during the above-described ink ejection, the ejection head 20 is ejected from the recording head 2. The inks separated from each other in the middle of the ejection path fly as ink particles arranged at a predetermined interval. At this time, the solvent recovery tube 33 is closed.
[0006]
The charging electrode 22 is disposed at a position where the separation into the ink particles described above occurs, and the deflection electrode 23 is disposed immediately after the position where the separation occurs, and each of the ink particles separated from each other is disposed. Is charged according to the applied voltage of the charging electrode 22 when passing through the position where the charging electrode 22 is disposed, and passes through the position where the deflection electrode 23 is disposed with different charges. An electric field having a predetermined intensity is formed at the position where the deflection electrode 23 is disposed by applying a high-voltage DC voltage, and the ink particles are deflected in accordance with the electric charges by the action of the electric field.
[0007]
The ink particles deflected in this way are ejected to the outside through a delivery port 25 formed in the housing 24 of the recording head 2 and printed on an object not shown. The printing position at this time is controlled by synchronizing the voltage applied to the charging electrode 22 with the separation of each ink particle, and changing the charge amount of each ink particle to the position where the deflection electrode 23 is disposed. It is changed by increasing or decreasing the amount of deflection due to the action of the formed electric field. Note that most of the ink particles ejected from the ejection nozzle 20 are not charged when passing through the charging electrode 22, are moved straight without being deflected by the action of the electric field, are captured by the gutter 21, and are collected in the collection tube 32. . In this way, by connecting the ejection nozzle 20 to the ink tube 30 and controlling the voltage applied to the charging electrode 22 while continuously ejecting ink from the ejection nozzle 20, it moves in a direction crossing the direction of the deflection. A desired pattern such as characters and figures can be formed on the surface of the object to be squeezed.
[0008]
On the other hand, the electromagnetic on-off valve K ₂ When the spray nozzle 20 is connected to the solvent tube 31, the solvent is supplied into the spray nozzle 20, and the solvent is sprayed at a predetermined speed. This supply is performed, for example, by washing the ejection nozzle 20 in a state where the ejection of ink is suspended during the pause of the above-described printing operation with a solvent, and including the inside of the ejection nozzle 20 by coagulation of the remaining ink. This is to prevent clogging occurring in each part of the ink supply system and recovery system. At this time, most of the solvent supplied to the injection nozzle 20 is recovered in the solvent recovery tube 33 connected to the injection nozzle 20, and the remaining solvent is injected as described above and captured by the gutter 21 and recovered. Collected in the tube 32.
[0009]
[Problems to be solved by the invention]
Now, in the ink jet recording apparatus having the recording head 2 as described above, the inside of the ejection nozzle 20 during the suspension of the printing operation is kept clean by the above-described cleaning operation. When the rest period is long, the ink component slightly remaining after the cleaning may solidify inside the ejection nozzle 20, and such solidification is caused by the ink ejection holes formed as extremely small diameter holes. When the ink is ejected to resume the printing operation, there is a possibility that a slight deviation occurs in the ejection path.
[0010]
The conventional ink jet recording apparatus does not have a function of detecting such a deviation in the ink ejection path, and performs a printing operation without noticing the deviation until an abnormality such as a pattern formation failure occurs. The ink ejected during this time is not captured by the gutter 21 but scattered inside the housing 24, and the components of the recording head 2 including the charging electrode 22 and the deflection electrode 23 are There was a problem that it was soiled and it took a lot of time and labor to repair the soil.
[0011]
The present invention has been made in view of such circumstances, and when restarting after pausing the printing operation, it is possible to examine the injection state of the injection nozzle and determine whether the printing operation can be started, An object of the present invention is to provide an ink jet recording apparatus capable of preventing the above-described inconveniences after resuming the printing operation.
[0012]
[Means for Solving the Problems]
An ink jet recording apparatus according to a first aspect of the present invention is switchably connected to an ink supply path and a solvent supply path, and is connected to an ejection nozzle for ejecting the ink or solvent, and an ink and solvent recovery path. A gutter disposed opposite to the ejection nozzle, and deflects a part of the ink particles continuously ejected from the ejection nozzle to print on the object, while capturing the undeflected ink particles in the gutter. In the ink jet recording apparatus that performs a printing operation for collecting in the collecting path, a gutter sensor that detects whether or not the solvent or ink is captured by the gutter, and before the printing operation is started, the jet nozzle is connected to the solvent. A control means connected to the supply passage and for injecting the solvent from the injection nozzle; and when the solvent is detected by the gutter sensor during the injection, the injection nozzle Switching Le of the connection to the supply path of the ink, by ejecting ink from the ejection nozzle, characterized by including a start-up control means for permitting the shift to the indicia shooting operation.
[0013]
In the present invention, when starting the printing operation, first, a solvent is supplied to the injection nozzle to be injected, and whether or not the injected solvent is captured by the gutter facing the injection nozzle is detected by the gutter sensor, For example, when solvent capture is detected for a predetermined time, it is determined that the ejection state of the ejection nozzle is normal and the printing operation can be started, and the connection of the ejection nozzle is connected to the ink supply path. The ink is switched and ejected, and the transition to the printing operation by this ink is permitted. Since such a determination is made by injecting the solvent, even if there is an abnormality in the injection state and the solvent is scattered around, the degree of contamination of the other components of the recording head, such as the charging electrode and the deflection electrode, is low and repaired. The time and effort required for is reduced.
[0014]
An ink jet recording apparatus according to a second aspect of the present invention is switchably connected to an ink supply path and a solvent supply path, and is connected to the ejection nozzle for ejecting the ink or the solvent and an ink and solvent recovery path. A gutter disposed opposite to the ejection nozzle, and deflects a part of the ink particles continuously ejected from the ejection nozzle to print on the object, while capturing the undeflected ink particles in the gutter. In the ink jet recording apparatus that performs a printing operation for collecting in the collecting path, a gutter sensor that detects whether or not the solvent or ink is captured by the gutter, and before the printing operation is started, the jet nozzle is connected to the solvent. A control means connected to the supply passage and for injecting the solvent from the injection nozzle; and when the solvent is detected by the gutter sensor during the injection, the injection nozzle Switching control means for switching the ink connection to the ink supply path and ejecting ink from the ejection nozzle, and when the ink is detected by the gutter sensor during this ejection, the transition to the printing operation is permitted. And a startup control means.
[0015]
In this invention, after the solvent is ejected from the ejection nozzle to determine the quality of the ejection state, the ink is further ejected from the ejection nozzle and detected by the gutter sensor. When this detection is made, that is, the ink ejection is normal. When it is detected that the printing operation has been performed, it is determined that the printing operation can be started, and the transition to the printing operation is permitted. As a result, it is possible to prevent the occurrence of ejection failure due to other than the clogging of the ejection nozzle, such as clogging of the ink supply system, and a normal printing operation is started immediately according to the permission of the transition.
[0016]
In the ink jet recording apparatus according to the third invention of the present invention, when the start-up control means in the first invention or the second invention does not detect the solvent or ink by the gutter sensor during the ejection of the solvent or ink, It is characterized in that the transition to the printing operation is prohibited and the prohibition of the transition is notified.
[0017]
In this invention, when the solvent or ink is not detected by the gutter sensor, it is determined that the ink is not properly ejected by the ejecting nozzle, and the transition of the printing operation is not permitted. The user is notified by means such as ringing and lighting of an alarm lamp.
[0018]
An ink jet recording apparatus according to a fourth aspect of the present invention comprises a thermistor in which the gutter sensor in the ink jet recording apparatus according to the first, second or third aspect of the present invention is attached in the vicinity of the solvent or ink capturing position of the gutter. It is characterized by being.
[0019]
In the present invention, the gutter sensor is simply configured by the thermistor that is located near the solvent or ink capturing position and is attached to the gutter. Whether or not the solvent or ink is trapped is determined by, for example, allowing the thermistor to self-heat and when the solvent or ink is trapped in the vicinity of the thermistor, the temperature of the thermistor decreases due to the heat of vaporization, and the output It can be detected by changing.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings illustrating embodiments thereof. FIG. 1 is a schematic diagram showing the overall configuration of an ink jet recording apparatus according to the present invention. As shown in the drawing, the ink jet recording apparatus according to the present invention is configured by connecting a main body case 1 and a recording head 2 by a connecting tube 3.
[0021]
In the main body case 1, an ink tank T in which printing ink is stored is stored. ₁ And replenishment ink tank T ₂ And a solvent tank T in which the solvent of the ink is stored. _Three And are provided. Ink tank T ₁ 1 includes a feeding pipe 10 for feeding ink or a solvent, and feeding ink or a solvent recovered from the recording head 2 as described later, and a feeding pipe 11 for supplying ink to the recording head 2. The exhaust pipe 12 communicated with the outside air is connected.
[0022]
In the middle of the supply pipe 10, the pump P ₁ Is installed and this pump P ₁ By the operation of the ink tank T. ₁ Ink or solvent is supplied to the printer. In the middle of the supply pipe 11, the pump P ₂ And filter F ₁ Is installed, and ink tank T ₁ The ink stored inside the pump P ₂ Filter F ₁ As a result, the foreign matter such as dust is removed and the recording head 2 is supplied to the recording head 2 through the inside of the connecting tube 3.
[0023]
Refill ink tank T ₂ Ink tank T ₁ A replenishment pipe 13 for feeding replenishment ink is connected to the. This replenishment pipe 13 has an electromagnetic on-off valve V ₁ Is connected to the feeding pipe 10 via the refilling ink tank T. ₂ The replenishment ink stored in the inside is the electromagnetic on-off valve V. ₁ When is opened, the pump P ₁ The ink tank T passes through the refilling pipe 13 and the feeding pipe 10 by the operation of ₁ It is supposed to be supplied inside. This supply is performed by an ink tank T by a printing operation described later. ₁ When the ink inside decreases, the decrease is compensated and the ink tank T ₁ This is done in order to keep the ink remaining amount in the inside appropriately.
[0024]
Solvent tank T _Three Is connected to a feeding pipe 14 for feeding the solvent stored therein. This feed pipe 14 is provided with an electromagnetic on-off valve V ₁ Solenoid valve V installed in parallel ₂ Is connected to the feed pipe 10 via the solvent tank T _Three The solvent stored in the electromagnetic valve V ₂ When is opened, the pump P ₁ The ink tank T passes through the feed pipe 14 and the feed pipe 10 by the operation of ₁ It is supposed to be supplied inside. This supply is the ink tank T ₁ When the solvent component contained in the ink is lost due to evaporation, this loss is compensated and the concentration of the ink is maintained appropriately.
[0025]
The feeding pipe 14 is provided with an electromagnetic on-off valve V. ₂ Is connected to the branch pipe 14a on the upstream side of the pump P. _Three And filter F ₂ Is installed in the solvent tank T _Three Solvent in the solenoid valve V ₂ With the pump closed, the pump P _Three By driving the filter F ₂ As a result, the foreign matter such as dust is removed and introduced into the branch pipe 14a, and is supplied directly to the recording head 2 through the inside of the connecting tube 3 as will be described later.
[0026]
For example, when the printing operation of the ink jet recording apparatus is stopped, the supply of such a solvent is performed by using an ejection nozzle 20 incorporated in the recording head 2 as described later, when the printing operation of the ink jet recording apparatus is stopped. In the inkjet recording apparatus according to the present invention, when the printing operation is resumed after pausing, the ejection state of the ejection nozzle 20 is examined, and the procedure described later is performed. This is performed to determine whether or not the printing operation can be started.
[0027]
The feed pipe 10 includes an electromagnetic on-off valve V. ₁ , V ₂ Solenoid valve V in parallel with _Three The solvent recovery pipe 16 is connected via the ₁ , V ₂ , V _Three A recovery pipe 15 for recovering ink and solvent is connected to the downstream side. The solvent recovery pipe 16 is provided to recover the solvent used for cleaning the spray nozzle 20, and the solvent recovered in the solvent recovery pipe 16 is the electromagnetic on-off valve V. _Three Open the pump P ₁ By operating the ink tank T through the feed pipe 10 ₁ Returned inside and collected. The recovery pipe 15 is provided to recover ink or solvent ejected from the ejection nozzle 20 as described later. The ink or solvent recovered in the recovery pipe 15 is supplied to the pump P ₁ Ink tank T through feed pipe 10 ₁ Returned inside and collected.
[0028]
FIG. 2 is a schematic diagram showing the internal configuration of the recording head 2. The configuration of the recording head 2 of the ink jet recording apparatus according to the present invention is the same as that of the conventional recording head 2 shown in FIG. 7, and an ejection nozzle 20 that ejects ink or a solvent fed in one direction as described later, A collection gutter 21 arranged so as to face the injection path by the injection nozzle 20, and a charging electrode 22 and a deflection electrode 23 arranged in parallel along the injection path from the injection nozzle 20 to the gutter 21. , Provided inside a box-shaped housing 24.
[0029]
The ejection nozzle 20 includes an ink tube 30 as an ink supply path and a solvent tube 31 as a solvent supply path. ₁ , K ₂ And a common liquid supply pipe 3a, and a solvent recovery tube 33 for recovering a solvent used for cleaning, which will be described later.
[0030]
The gutter 21 is a bottomed cylindrical member having a small-diameter opening that faces the arrival position of ink or solvent ejected from the ejection nozzle 20 as indicated by an arrow in the figure. The gutter 21 is connected to a collection tube 32 for collecting the captured ink or solvent. The gutter 21 is provided with a gutter sensor 4 for detecting whether or not the solvent or ink is captured.
[0031]
The gutter sensor 4 can have various configurations. For example, a thermistor is attached to the outside of the bottom surface of the gutter 21 that becomes a collision surface of the ink or the solvent, and the thermistor is self-heated by energizing itself. This can be realized simply by the configuration. In the gutter sensor 4 configured in this way, when ink or solvent is trapped on the inner surface of the gutter 21, the temperature of the thermistor is lowered due to heat removal due to vaporization of the ink or solvent, resulting in a change in output. The presence or absence of the capture can be detected. At this time, since the vaporization property differs between the ink and the solvent, the ink and the solvent can be distinguished from each other according to the degree of change in the output of the thermistor.
[0032]
The connection tube 3 for connecting the recording head 2 and the main body case 1 as described above is a hollow tube made of a flexible resin material. The ink tube 30, the solvent tube 31, the recovery tube 32, and the solvent recovery tube 33 is extended into the inside of the main body case 1 through the inside of the connecting tube 3, the extended end of the ink tube 30 is branched to the ink supply pipe 11, and the extended end of the solvent tube 31 is branched from the solvent supply pipe 14. An extension end of the collection tube 32 is connected to the branch pipe 14a, and an extension end of the solvent collection tube 33 is connected to the solvent collection pipe 16, respectively.
[0033]
Printing by the ink jet recording apparatus configured as described above is performed by the electromagnetic on-off valve K. ₁ Is opened and the liquid supply pipe 3a is connected to the ink tube 30 while the pump P inside the main body case 1 is connected. ₁ , P ₂ It is done by driving. At this time, ink tank T ₁ The ink stored inside the pump P ₂ Filter F ₁ The foreign matter such as dust is removed by the passage of the liquid and is supplied to the jet nozzle 20 through the ink tube 30 and the liquid supply pipe 3a inside the connecting tube 3 and jetted from the jet nozzle 20. At this time, the electromagnetic on-off valve V inside the main body case 1 _Three Is closed, and the solvent recovery tube 33 connected to the ejection nozzle 20 is closed at the end of the solvent recovery tube 16, so that the entire amount of ink supplied to the ejection nozzle 20 is ejected at a predetermined speed. .
[0034]
Inside the ejection nozzle 20, there is a piezo vibrator 20a that vibrates when a high frequency voltage is applied, and the ink ejected from the ejection nozzle 20 is separated from each other in the middle of the ejection path by the action of the vibration. The ink particles fly in the form of ink particles arranged at a predetermined interval, and some of the ink particles are composed of the charging electrode 22 disposed at the separation position and the deflection electrode 23 disposed immediately after the separation position. It is deflected by the above action, sent to the outside through the delivery port 25 formed at the corresponding position of the housing 24 and used for pattern formation, and the remaining ink particles go straight without being deflected and are captured by the gutter 21 The
[0035]
The ink captured by the gutter 21 is pump P in the main body case 1. ₁ The ink tank T is sucked by the operation of the ink tank T and passes through the collection tube 32 and the supply pipe 10 ₁ To be recovered. At this time, the pump P ₁ In this case, air is sucked together with the ink captured by the gutter 21, and this air is absorbed by the ink tank T. ₁ It is discharged to the outside air through the exhaust pipe 12 connected to the outside.
[0036]
As the printing operation continues, the ink tank T ₁ When the remaining amount of ink in the inside decreases, the electromagnetic on-off valve V inside the main body case 1 ₁ Is released. At this time, the replenishment ink tank T ₂ The refilling ink stored in the pump P ₁ The ink tank T passes through the refilling pipe 13 and the feeding pipe 10 by the operation of ₁ The ink tank T ₁ The ink remaining amount can be kept appropriate. Furthermore, as the printing operation continues, the ink tank T ₁ When the density (viscosity) of the ink inside changes, the electromagnetic on-off valve V inside the main body case 1 ₂ Is released. As a result, the solvent tank T _Three The solvent stored in the pump P _Three Operation, the ink tank T passes through the supply pipe 14 and the supply pipe 10. ₁ The ink tank T ₁ The density of the ink inside can be kept appropriate.
[0037]
On the other hand, the electromagnetic on-off valve K inside the recording head 2 ₂ Is opened, the liquid supply pipe 3a is connected to the solvent tube 31, and the solvent supply pump P inside the main body case 1 is connected. _Three , The solvent tank T _Three The solvent stored in is supplied to the injection nozzle 20 through the supply pipe 14, the branch pipe 14a, and the solvent tube 31. At this time, the electromagnetic on-off valve V inside the body case 1 _Three Is opened, most of the solvent supplied to the ejection nozzle 20 returns to the main body case 1 through the solvent recovery tube 33, and passes through the solvent recovery tube 16 and the feed tube 10 to form the ink tank T. ₁ Returned to Further, a part of the solvent supplied to the injection nozzle 20 is injected to one side of the injection nozzle 20, is captured by the gutter 21, returns to the main body case 1 through the recovery pipe 32, and passes through the supply pipe 10. Ink tank T ₁ Returned to
[0038]
For example, when the above-described printing operation is suspended, the supply of such a solvent is performed inside the ejection nozzle 20 that halts the ejection of ink, the interior of the collection pipe 32 that serves as a path for the collected ink, and the inside of the feed pipe 10. Such a cleaning operation is caused by clogging that occurs in each part of the ink supply system and the recovery system including the inside of the ejection nozzle 20 due to coagulation of the remaining ink. It is indispensable to prevent the problem.
[0039]
In the printing operation and the cleaning operation as described above, the pump P is disposed inside the main body case 1. ₁ , P ₂ , P _Three Drive control and electromagnetic on-off valve V ₁ , V ₂ , V _Three Open / close control of the electromagnetic open / close valve K in the recording head 2 ₁ , K ₂ Open / close control, and energization control of the injection nozzle 20 (piezo vibrator 20a), the charging electrode 22 and the deflection electrode 23 are required. These controls are performed by the operation control unit 5 provided inside the main body case 1. It is done by action.
[0040]
FIG. 3 is a block diagram of the control system of the ink jet recording apparatus according to the present invention, and the output of the operation control unit 5 is the pump P to be controlled. ₁ , P ₂ , P _Three , Solenoid valve V ₁ , V ₂ , V _Three , Solenoid valve K ₁ , K ₂ The spray nozzle 20, the charging electrode 22, and the deflection electrode 23 are provided.
[0041]
An operation unit 50 used by a user for driving operation is connected to the input side of the operation control unit 5. In the operation unit 50, various operations including the designation of the pattern to be formed are performed in addition to the operation for starting and stopping the printing operation, and the operation control unit 5 receives inputs from the operation unit 50. To recognize the user's operation and to perform the above-mentioned printing operation and cleaning operation in accordance with this operation, the output side pump P ₁ , P ₂ , P _Three , Solenoid valve V ₁ , V ₂ , V _Three , Solenoid valve K ₁ , K ₂ In this configuration, control signals are emitted to the ejection nozzle 20, the charging electrode 22, and the deflection electrode 23.
[0042]
Further, the detection result of the gutter sensor 4 is given to the input side of the operation control unit 5, and further the detection results of the pressure sensor 51 and the temperature sensor 52 are given respectively. As shown in FIG. 1, the pressure sensor 51 is attached in the middle of the solvent recovery pipe 16 inside the main body case 1 so as to detect its internal pressure. The solvent recovery pipe 16 is connected to the electromagnetic on-off valve V during the above-described printing operation. _Three The internal pressure of the tube is equal to the internal pressure of the injection nozzle 20 communicated via the solvent recovery tube 33. The temperature sensor 52 is attached in the middle of the supply pipe 11 inside the main body case 1 and detects the temperature of the ink supplied to the ejection nozzle 20 through the supply pipe 11.
[0043]
The operation control unit 5 recognizes the pressure of the ink to be ejected from the ejection nozzle 20 based on the input from the pressure sensor 51, and the ink to be ejected from the ejection nozzle 20 based on the input from the temperature sensor 52. 4 is used to perform a characteristic operation according to the flowchart shown in FIG. 4 during the above-described printing operation.
[0044]
During the above-described printing operation, the operation control unit 5 captures the output of the temperature sensor 52 connected to the input side at a predetermined sampling period (step 1), monitors the ink temperature t, and this temperature t is Predetermined reference temperature t ₀ (Step 2), if not, the process proceeds to step 5 to check whether a stop operation has been performed in the operation unit 50, and if the stop operation has not been performed, step 1 is performed. The monitoring of the ink temperature t is continued until the stop operation is performed.
[0045]
On the other hand, in step 2, the current ink temperature t is changed to the reference temperature t. ₀ If it is determined that the temperature exceeds the value, the operation control unit 5 refers to the applied voltage data of the piezo vibrator 20a attached to the ejection nozzle 20 stored in correspondence with the ink temperature, and the current ink temperature. In order to perform an appropriate vibration with respect to t, a control signal is issued to the jet nozzle 20 on the output side, and the applied voltage of the piezo vibrator 20a is changed (step 3).
[0046]
Further, the operation control unit 5 refers to the ejection pressure data stored in correspondence with the ink temperature, and in order to perform ejection at an appropriate pressure with respect to the current ink temperature t, the operation control unit 5 Pump P ₂ A control signal is issued to adjust the injection pressure (step 4). This adjustment is performed based on the input from the pressure sensor 51 given to the input side. ₂ It is possible to perform this by feedback control that changes the rotation speed. Thereafter, the process proceeds to step 5 to check whether or not a stop operation has been performed in the operation unit 50, and the above-described operation is repeated until the stop operation is performed.
[0047]
During the above-described printing operation, most of the ink ejected from the ejection nozzle 20 is captured by the gutter 21 facing the ejection nozzle 20, and the ink tank T ₁ It is returned to and reused. In the middle of such an ink circulation path, the pump P ₁ , P ₂ , Solenoid valve K ₁ Therefore, it is inevitable that the temperature of the ink rises as the printing operation continues. When the temperature of the ink rises, the viscosity of the ink decreases, and when such a viscosity decrease occurs, the ejection speed of the ink from the ejection nozzle 20 increases and the ejection is performed according to the excitation by the piezo vibrator 20a. Since the separation position to the ink particles that occur later changes, charging by the charging electrode 22 disposed corresponding to the separation position and subsequent deflection by the deflection electrode 23 are not performed normally, and the printing quality is deteriorated. Invite
[0048]
The control operation shown in FIG. 4 is intended to solve such a problem, and the detected value t of the ink temperature by the temperature sensor 52 is a predetermined temperature t. ₀ When the pressure exceeds the value, the excitation frequency by the piezo vibrator 20a is changed by the operation of step 3, and the ink ejection pressure is adjusted by the operation of step 4. As a result, the ink after ejection from the ejection nozzle 20 is adjusted. The separation position to the grains is optimized, and it is possible to prevent the printing quality from being lowered.
[0049]
In FIG. 4, both the excitation frequency and the injection pressure are adjusted, but only one of them may be changed. In FIG. 4, the excitation frequency and the ejection pressure are changed based on the detection result of the ink temperature. However, the temperature around the ejection nozzle 20 is detected, and the change is performed based on the detection result. It is good also as a structure to perform.
[0050]
In addition, since the viscosity of the ink changes not only due to the temperature of the ink but also due to evaporation of the solvent contained in the ink over time, the above-described control of the excitation frequency and / or the ejection pressure is performed by the ink tank T ₁ It is more desirable to measure the viscosity of the ink fed from the nozzle to the ejection nozzle 20 and to perform the measurement based on the result.
[0051]
FIG. 5 is a schematic diagram showing the overall configuration of the ink jet recording apparatus according to the present invention that enables measurement of ink viscosity. The ink jet recording apparatus shown in FIG. ₁ And a return pipe 17 for measuring the viscosity connecting the inside of the supply pipe 11 and the middle part of the supply pipe 11. This return pipe 17 is connected to the ink tank T ₁ The viscometer 53 is attached to the rising portion. In the middle of the return pipe 17, an electromagnetic on-off valve V _Four And filter F _Three However, the viscometer 53 is interposed in this order on the supply pipe 11 side. The other configurations are the same as those of the ink jet recording apparatus shown in FIG. 1, and the same reference numerals are assigned to corresponding components, and detailed description thereof is omitted.
[0052]
As the viscometer 53, a small-diameter orifice is provided in the middle of the rising portion of the return pipe 17, and the ink tank T passes through the rising portion. ₁ A configuration in which the viscosity is measured based on the time during which a predetermined amount of ink returning to the inside passes through the orifice, an impeller is arranged in the middle of the rising portion of the return pipe 17, and the ink tank T passes through the rising portion. ₁ Various known configurations such as a configuration in which the viscosity is measured by the rotation of the impeller generated by the action of a predetermined amount of ink that circulates inside can be employed. Such a viscosity measurement by the viscometer 53 is performed by measuring the electromagnetic on-off valve V every predetermined time. _Four Is opened and closed to generate an ink flow in the return pipe 17, and the measurement result is given to the operation control unit 5.
[0053]
The operation control unit 5 directly recognizes the viscosity of the ink supplied to the ejection nozzle 20 by the input from the viscometer 53, and replaces the result with the ink temperature t in the operation according to the flowchart shown in FIG. Used to control the excitation frequency and / or injection pressure.
[0054]
At this time, the temperature of the ink input from the temperature sensor 52 is contrasted with the viscosity of the ink supplied from the viscometer 53, and the ink tank T ₁ This is used to determine whether or not the ink inside has an appropriate viscosity according to its temperature. ₁ It is used for adjusting the concentration (viscosity) of ink stored in the inside. As described above, the ink concentration (viscosity) is adjusted by the electromagnetic on-off valve V. ₂ Open the pump P _Three Drive the solvent tank T _Three The ink stored in the ink tank T passes through the supply pipe 14 and the supply pipe 10. ₁ It is made by supplying the inside.
[0055]
Filter F installed in the middle of the return pipe 17 _Three Is an electromagnetic on-off valve V _Four Ink tank T through return pipe 17 when opening ₁ In addition to acting to capture dust contained in the ink that circulates back to the ink, a resistance is given to the ink flow that flows in the return pipe 17, and the electromagnetic on-off valve V _Four As a result, the pressure of the ink supplied to the ejection nozzle 20 through the supply pipe 11 is prevented from fluctuating with the opening and closing of the nozzle.
[0056]
Further, it is possible to cause the above-described change of the excitation frequency and / or the injection pressure to be performed by a predetermined operation of the operation unit 50. The deterioration of the printing quality is caused by the above-described change in the viscosity of the ink, and also due to the change in the characteristics of the components of the recording head 2 including the ejection nozzle 20, the charging electrode 22, and the deflection electrode 23 over time. In the case where the excitation frequency and the injection pressure can be changed by the operation of the operation unit 50, the deterioration of the printing quality with time can be changed by the operation.
[0057]
The gutter sensor 4 detects whether or not the ink or solvent ejected from the ejection nozzle 20 has been captured by the gutter 21 facing the ejection nozzle 20 as described above. The operation control unit 5 recognizes the quality of the injection state by the injection nozzle 20 based on the input from the gutter sensor 4, and uses this result to perform the start-up control operation for shifting to the printing operation as shown below. .
[0058]
FIG. 6 is a flowchart showing the contents of the startup control operation performed by the operation control unit 5 before the start of the printing operation. During the suspension of the above-described printing operation, the operation control unit 5 performs a cleaning operation for cleaning the spray nozzle 20 by supplying the solvent, and then performs an operation for starting the printing operation by an input from the operation unit 50. The operation waits while monitoring whether or not it has been made (step 11). When an operation for starting printing is performed, first, the solvent supply pump P on the output side is first _Three And solenoid valve K ₁ , K ₂ Control signal to pump P _Three And an electromagnetic on-off valve K ₁ Is closed, solenoid valve K ₂ Open the solvent tank T _Three The internal solvent is supplied to the injection nozzle 20, and the solvent is ejected from the injection nozzle 20 (step 12).
[0059]
Thereafter, the operation control unit 5 captures the output of the gutter sensor 4 at a predetermined sampling period, and determines whether or not the solvent is detected, that is, whether or not the solvent ejected from the spray nozzle 20 is captured by the gutter 21. Inspect (step 13), if the solvent is not detected, it is determined that there is an abnormality in the injection state of the injection nozzle 20, and the transition to the subsequent printing operation is prohibited (step 14), and the operation ends. .
[0060]
When the thermistor attached to the gutter 21 as described above is used as the gutter sensor 4, the output voltage of the thermistor increases due to contact with the solvent. This is realized by comparing the output voltage of the thermistor with a predetermined threshold voltage. In addition, when the transition to the printing operation is prohibited in the step 14, it is possible to notify the user of this by appropriate notification means such as sounding an alarm buzzer or lighting an alarm lamp. .
[0061]
On the other hand, if the solvent is detected in step 13, this detection is continued until a predetermined time has elapsed (step 15), and the solvent is continuously detected for a predetermined time. The operation control unit 5 determines that the injection by the injection nozzle 20 is normally performed, and proceeds to step 16.
[0062]
With the operation of the operation control unit 5, when the printing operation is started, first, a solvent is injected from the injection nozzle 20, and whether the injection state is good or not is determined by whether or not the solvent is captured by the gutter 21. The Accordingly, when the printing operation is stopped, when the ejection nozzle 20 is abnormal, such as clogging, and the ejection path is deviated, the printing operation is not started without noticing this. In addition, since the above-described determination is performed by ejecting the solvent, even when there is a deviation in the ejection path, not the ink but the solvent is scattered inside the housing 24 of the recording head 2, and charging is performed. The degree of contamination of the components of the recording head 2 including the electrode 22 and the deflection electrode 23 is reduced, and the effort required to repair this contamination can be reduced.
[0063]
When it is determined that the ejection by the ejection nozzle 20 is normal, the operation control unit 5 determines that the output side ink supply pump P ₂ And solenoid valve K ₁ , K ₂ Control signal to pump P ₂ And an electromagnetic on-off valve K ₁ Open, solenoid valve K ₂ Is closed and the ink tank T ₁ The ink inside is supplied to the ejection nozzle 20, and the ink is ejected from the ejection nozzle 20 (step 16).
[0064]
At this time, the electromagnetic on-off valve K ₁ Opening operation and electromagnetic on-off valve K ₂ The closing operation of the nozzles is performed slowly in synchronism with each other, and the switching from the solvent to the ink is continuously performed without any pressure change, so that the ejection from the ejection nozzle 20 continues without interruption. Is desirable.
[0065]
After the ink is ejected in this way, the operation control unit 5 takes in the output of the gutter sensor 4 at a predetermined sampling period and determines whether ink is detected, that is, the ink ejected from the ejection nozzle 20. Is detected by the gutter 21 (step 17), and if no ink is detected, it is determined that there is an abnormality in the ejection state of the ejection nozzle 20, and the process proceeds to step 14 to proceed to the printing operation. This operation is forbidden and the operation is terminated. Even in this case, the user can be notified by appropriate notification means such as the alarm buzzer sounding and the alarm lamp lighting.
[0066]
If ink is detected, the detection is continued until a predetermined time has elapsed (step 18). If ink is continuously detected for a predetermined time, the ejection nozzle 20 is detected. It is determined that the ink can be ejected normally, and the transition to the printing operation is permitted (step 19), and the start-up control operation performed before the start of the printing operation is terminated.
[0067]
By such an operation of the operation control unit 5, an ink supply system reaching the ejection nozzle 20, that is, a malfunction in the ejection state due to an abnormality such as clogging in the supply pipe 11 and the ink tube 30 is detected and noticed. The printing operation is not started with no ink, and the contamination inside the recording head 2 due to ink scattering can be reduced.
[0068]
Note that step 17 and step 18 are omitted, and when it is determined in step 13 and step 15 that the solvent has been detected for a predetermined time, the process proceeds to step 19 to allow the transition to the printing operation. May be.
[0069]
【The invention's effect】
As described above in detail, in the ink jet recording apparatus according to the first aspect of the present invention, the gutter disposed opposite to the ejection nozzle is provided with a gutter sensor for detecting the capture of the ink or solvent ejected from the ejection nozzle, and performs the printing operation. At the time of start, since the solvent is injected from the injection nozzle and the transition to the printing operation is permitted based on the detection of the solvent by the gutter sensor at this time, the printing operation starts without noticing the abnormality of the injection state. Thus, it is possible to avoid the possibility that the inside of the recording head is soiled by the ink ejected from the ejection nozzle, and to perform the printing operation with certainty. In addition, even when the ejection state is abnormal, the solvent only scatters to the periphery, and the degree of contamination inside the recording head is light compared to the case where the ink splatters, reducing the labor required for repair. Can be dealt with promptly.
[0070]
In the ink jet recording apparatus according to the second aspect of the invention, after the solvent is detected by the gutter sensor, the ink is ejected from the ejection nozzle, and the transition to the printing operation is performed on condition that the ink is detected by the gutter sensor. Since the configuration is permitted, it is possible to prevent the occurrence of defective ink ejection based on the abnormality of the parts other than the ejection nozzle, such as an abnormality in the ink supply system, and to ensure that the subsequent printing operation is performed. it can.
[0071]
Further, in the ink jet recording apparatus according to the third aspect of the present invention, when the solvent or ink is not detected by the gutter sensor, the shift to the printing operation is prohibited, and this is notified so that an abnormality in the ejection state is used. Can be surely noticed and appropriate measures can be taken promptly.
[0072]
Further, in the ink jet recording apparatus according to the fourth aspect of the present invention, the thermistor is attached to the gutter in the vicinity of the solvent or ink capturing position, and this thermistor is used as a gutter sensor. The present invention has an excellent effect that it can be reliably detected by the configuration.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing an overall configuration of an ink jet recording apparatus according to the present invention.
FIG. 2 is a schematic diagram showing an internal configuration of a recording head of an ink jet recording apparatus according to the present invention.
FIG. 3 is a block diagram of a control system of the ink jet recording apparatus according to the present invention.
FIG. 4 is a flowchart showing a procedure for adjusting the excitation frequency and the injection pressure performed during the printing operation.
FIG. 5 is a schematic diagram showing an overall configuration of another embodiment of the ink jet recording apparatus according to the present invention.
FIG. 6 is a flowchart showing the operation content of a start-up control operation performed before the start of the printing operation.
FIG. 7 is a schematic diagram showing an internal configuration of a recording head of a conventional ink jet recording apparatus.
[Explanation of symbols]
1 Body case
2 Recording head
3 Connecting tube
4 Gutter sensor
5 Operation control unit
50 Control section
51 Pressure sensor
52 Temperature sensor
53 Viscometer
T ₁ Ink tank
T _Three Solvent tank

Claims (4)

An ink supply path and a solvent supply path are switchably connected to each other, and include an ejection nozzle that ejects the ink or the solvent, and a gutter that is connected to the ink and solvent recovery path and is disposed to face the ejection nozzle. Ink jet for performing a printing operation in which some of the ink particles continuously ejected from the ejection nozzle are deflected and printed on the object, while the non-deflected ink particles are captured by the gutter and collected in the collection path. In the recording apparatus, a gutter sensor for detecting whether or not the solvent or ink is captured by the gutter, and before the start of the printing operation, the injection nozzle is connected to the solvent supply path, and the solvent is injected from the injection nozzle. And when the solvent is detected by the gutter sensor during the ejection, the connection of the ejection nozzle is switched to the ink supply path, and the ejection nozzle By injecting the Luo ink jet recording apparatus characterized by comprising a start-up control means for permitting the shift to the indicia shooting operation. An ink supply path and a solvent supply path are switchably connected to each other, and include an ejection nozzle that ejects the ink or the solvent, and a gutter that is connected to the ink and solvent recovery path and is disposed to face the ejection nozzle. Ink jet for performing a printing operation in which some of the ink particles continuously ejected from the ejection nozzle are deflected and printed on the object, while the non-deflected ink particles are captured by the gutter and collected in the collection path. In the recording apparatus, a gutter sensor for detecting whether or not the solvent or ink is captured by the gutter, and before the start of the printing operation, the injection nozzle is connected to the solvent supply path, and the solvent is injected from the injection nozzle. And when the solvent is detected by the gutter sensor during the ejection, the connection of the ejection nozzle is switched to the ink supply path, and the ejection nozzle And a switching control means for ejecting ink, and a start-up control means for permitting the transition to the printing operation when the ink is detected by the gutter sensor during the ejection. Recording device. When the solvent or ink is not detected by the gutter sensor during the ejection of the solvent or ink, the start-up control means prohibits the transition to the printing operation and notifies the prohibition of the transition. The ink jet recording apparatus according to claim 1 or 2. 4. The ink jet recording apparatus according to claim 1, wherein the gutter sensor is constituted by a thermistor attached in the vicinity of a capture position of the solvent or ink of the gutter.

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