JPS6315914B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to a method for preventing clogging in an ink droplet ejecting device that controls the main part of an inkjet printer.

(B) Prior Art Ink droplet ejecting devices are currently classified into electric field control type, charge control type, on-demand type, etc. depending on the type of ink droplet ejection control. It is widely known that the biggest drawback common to all these ink droplet ejecting devices is that the orifice through which the ink droplets are ejected is clogged, and the following suggestions are available to prevent such clogging. is being done.

(a) Put a lid on the orifice (110847/1984
issue).

(b) Keep the area near the orifice humid to prevent it from drying out (Utility Model Publication No. 50-35624).

(c) Coat the orifice (nozzle) with anti-drying liquid (Japanese Patent Publication No. 54-24661).

(d) The ink itself is mixed with chemicals that do not dry, such as polyethylene glycol or ethylene glycol.

There is also a self-recovery method in which dried ink is removed by applying great pressure to the ink.

However, in the case of an on-demand type ink droplet ejecting device that ejects ink droplets by applying a minute pressure change to the ink near the orifice, as mentioned above, the ink droplets are ejected due to the minute pressurizing force. Once the clogging occurs, the clogging cannot be easily recovered by itself, and therefore, it is necessary to prevent the clogging in advance during non-printing operations.

(c) Problems to be Solved by the Invention The present invention attempts to prevent clogging of the orifice for ejecting ink droplets, which is the biggest drawback in the ink droplet ejecting device that controls the main part of an inkjet printer. It is something.

(d) Means for Solving the Problems The method for preventing clogging in the ink droplet ejecting device of the present invention is such that when the ink droplet ejecting device is not in a printing operation, the first orifice for ejecting ink droplets is replaced with the orifice. The front chamber is covered with ink filled in the chamber, and the completion of filling of the ink is detected by a change in resistance value.

(E) Effect As mentioned above, during non-printing operation, by detecting the end of filling the front chamber with ink by the change in resistance value, the ink filled in the front chamber can be reliably used for printing operation. act to cover the first orifice from which the ink droplets are ejected.

(f) Examples The method for preventing clogging of the present invention will be described below in detail with reference to the drawings for an on-demand type ink droplet ejecting device.

FIG. 1 shows a cross-sectional view of the ink droplet ejecting device during printing operation. In the figure, 1 is an on-demand type ink droplet ejecting device, and the ejecting device 1 curves in response to an image signal. A vibrating piezoelectric diaphragm 2, a horn-shaped pressure chamber 3 in which the piezoelectric diaphragm 2 is arranged at the opening on the long diameter side, and a thin plate-shaped vibrator 4 provided in the short diameter side of the pressure chamber 3 so as to be able to vibrate freely. , an ink chamber 5 that holds ink in front of the vibrator 4, a front plate 6 that faces the vibrator 4 with the ink chamber 5 in between, and a center of vibration of the vibrator 4 on the front plate 6. It has a first orifice 7 with a minute diameter bored at an opposite location, and further has a front chamber 8 provided in front of the first orifice 7, and a hole opened from the chamber 8 and the first orifice 7. The second orifice 10 has an opening diameter twice or more larger than that of the first orifice 7 through which the ink droplets 9 ejected from the orifice 7 pass. 1
Reference numeral 1 denotes an ink tank for supplying ink to the ink chamber 5 of the ink droplet ejecting device 1, and several hundred c.c. of ink is stored in a bag made of polymer film or the like with low air permeability. 12 is the ink tank 11 and the ink chamber 5
The ink supply pipe 13 that communicates with the ink tank 11 is an ink coupler inserted in the middle of the ink supply pipe 12.
The ink supply pipe 12 extending from the ink tank 12 is freely attachable, and ink can be replenished by replacing each ink tank 11. Reference numeral 14 denotes an air pump that appropriately adds an air flow 16 as indicated by the arrow to the chamber 8 and the ink tank 11 at the front of the ink droplet ejecting device 1 through the air supply pipe 15; A valve device provided in the air supply pipe 15 between the two, for example, is a three-way electromagnetic valve, and communicates the air pump 14 with the front chamber 8 during the printing operation. A recording medium 18 is placed in front of the second orifice 10 of the ink droplet ejecting device 1 at a short distance, and is wound around a rotating drum 19 and main-scanned in the rotational direction.

FIG. 2 shows the state during non-printing operation, in which the second orifice 10 of the ink droplet ejecting device 1 is covered with a lid 20 made of an elastic material such as rubber.
During this non-printing operation, the first orifice 7 is covered with ink supplied to the front chamber 8. During such a non-printing operation, the ink droplet ejecting device 1 is located at a home position HP away from the recording medium 18 and the drum 19, as shown in FIG. In the figure, PP is a print position where the ink droplet ejecting device 1 is in a printing operation by ejecting ink droplets 9, and the ink droplet ejecting device 1 is in a state as shown in FIG. SP is a standby position located between the print position PP and the home position HP, where the ink droplet ejecting device 1 waits for printing operation. The orifice 10 faces the gutter 21 as shown in FIGS. 4 and 5.

When an image signal is applied to the piezoelectric diaphragm 2 of the ink droplet ejecting device 1 at the print position PP, the piezoelectric diaphragm 2 suddenly curves and vibrates in its thickness direction, pressurizing the pressure chamber 3. This pressurization is carried out in pressure chamber 3.
Together with the horn shape, the pressure is amplified and propagated to the vibrator 4, causing the vibrator 4 to bend significantly.
That is, the piezoelectric diaphragm 2, the pressure chamber 3, and the vibrator 4
acts as a pressure changing means that rapidly changes the pressure on the ink in the ink chamber 5. Therefore, the ink chamber 5 receives a sudden pressure change from the vibrator 4.
The ink is pushed out from the first orifice 7,
The ink becomes an ink droplet 9 and is ejected from a coaxial second orifice 10 while being surrounded by an air flow 16. The ejection of the ink droplets 9 by the air flow 16 is described in more detail in Japanese Patent Laid-Open No. 51-37541, so a detailed explanation thereof will be omitted here.
These ink droplets 9 ultimately adhere to a recording medium 18 that is being rotated and scanned by a drum 19 to print images such as characters and figures.

After the printing operation is completed, the ink droplet ejecting device 1 passes through the standby position SP and returns to the home position HP. After returning, the second orifice 10 is closed to the lid body 2.
0 and the front chamber 8 is sealed off from the outside. Next, in order to supply ink to the front chamber 8 through the ink system from the ink tank 11 to the first orifice 7, the valve device 17 is switched to communicate the front chamber 8 with the outside air. This switching of the valve device 17 brings the front chamber 8 and the air pump 14 into a closed state. When the air pump 14 is operated in this state, the air flow 16 flows toward the ink tank 11 and pressurizes the ink in the ink tank 11. This pressure increase of the ink in the ink tank 11 is caused by the ink supply pipe 12,
The ink is transmitted through the ink connector 13 and further through the ink supply pipe 12 to pressurize the ink in the ink chamber 5.
Therefore, the pressure of ink in the ink chamber 5 near the first orifice 7 gradually increases compared to the pressure in the chamber 8 in front. When this pressure difference reaches a threshold value that breaks the equilibrium state of the ink in the first orifice 7, the ink flows out from the first orifice 7 into the chamber 8 in front. When an electric signal is applied to the piezoelectric diaphragm 2 to cause the vibrator 4 to continuously vibrate in a curved manner in order to assist the ink to flow out, the balance of the ink immediately collapses and the ink flows from the first orifice 7 into the front chamber 8. It starts to flow. Once the ink starts flowing, even if the application of the electric signal to the piezoelectric diaphragm 2 is stopped, the pressure (air pressure) in the front chamber 8 is lower than the ink pressure in the ink chamber 5, so the ink supply will continue. Ru. Furthermore, such ink supply is achieved by opening the valve device 17, which is located at a higher position than the first orifice 7, which is the ink supply hole, and which currently communicates the front chamber 8 with the atmosphere, as shown in FIG. Mouth 17 out,
It acts as an exhaust port for the front chamber 8 pushed out by the ink supply. In this way, the first orifice 7 is covered with the supplied ink without leaving any air bubbles in the front chamber 8. The supply of this ink is controlled by the detection output of a resistance detection means provided in the front chamber 8 or the air supply pipe 15 in the vicinity of the front chamber 8.

In this embodiment, the body 22 of the ink droplet ejecting device 1 and the detection electrode 2 in the insulated air supply pipe 15 are used.
The resistance value between 3 and 3 is detected. That is, when the ink in the air supply pipe 15 rises and immerses the detection electrode 23, the resistance value between the body 22 and the detection electrode 23 is drastically reduced by the ink, and the completion of ink filling is detected. By detecting the end of ink filling, ink will not overflow from the atmosphere opening 17out and contaminate the apparatus.

Further, if the vibration of the piezoelectric diaphragm 2 is continued until the filling is completed, the ink filling is not only done quickly but also completely, so this method is usually adopted.

When the detection means detects that the front chamber 8 has been filled with ink, the air pump 14 stops operating and the pressure in the ink tank 11 gradually decreases. On the other hand, the front chamber 8 is in communication with the outside air via the air supply pipe 15, and when the pressure in the ink tank 11 decreases as described above in this state, the ink supplied and filled in the front chamber 8 is removed from the ink tank. Valve device 17 is closed for back flow towards 11. Therefore, the system of the front chamber 8 and the air supply pipe 15 is closed, and the backflow of ink is prevented by the so-called Torricelli principle.

As a result, when the ink droplet ejecting device 1 is in the home position during non-printing operation, the front chamber 8 is filled with ink, and the first orifice 7 is covered with the ink, preventing it from drying and getting dust. The main cause of clogging is prevented.

In this way, the ink droplet ejecting device 1, which had been supplied with ink into the front chamber 8 in the home position HP to prevent clogging of the first orifice 7, is moved to the standby position SP prior to the printing operation. Move and face the gutter 21. In this state, the valve device 17 is operated to establish communication between the air pump 14 and the front chamber 8, and to operate the air pump 14. Then, the ink filled in the front chamber 8 is pressurized from the outer circumferential direction by the air flow 16 as shown by the arrow in FIG. is discharged from. This discharged ink is captured by the gutter 21 disposed opposite to each other. When the ejection operation is completed, the air flow 16 is stopped, the ink is kept in equilibrium in the first orifice 7, and the ink drop ejecting device 1 is placed in a standby state as shown in FIG. Each time this ink is discharged, the second orifice 10 is cleaned by discharging even a small amount of ink coagulation that had adhered during the previous printing operation, and waits for the next printing operation.

The cleaning action described above is also performed on the first orifice 7 when ink is supplied from the first orifice 7 during non-printing operations.

Incidentally, the ink droplet ejecting device 1 used in the present invention is not limited to the above-mentioned embodiment, but for example, the ink droplet ejecting device 1 used in the present invention is
Similar to the present invention, as disclosed in No. 109738, the first
Most desirable is an ink drop ejector in which an air flow 16 is applied to the orifice 7 of the ink droplet ejector. Also air flow 1
6, the ink tank 11 can be pressurized with an appropriate pressurizing means to supply ink, and the ink can be discharged by flowing out to the lowest part of the front chamber 8 by its own weight. This can be dealt with by providing an outlet for the leakage.

(g) Effects of the Invention As is clear from the above explanation, the method for preventing clogging in the ink droplet ejecting device of the present invention detects the completion of filling of the ink in the front chamber by a change in resistance value. The ink in the front chamber acts to reliably cover the first orifice during non-printing operations, thereby completely preventing clogging of the first orifice mainly caused by drying of the ink. In addition, by detecting the end of ink filling, ink will not overflow from the atmosphere opening and contaminate the device. Furthermore, if the first orifice is covered, even if an impact is applied to the ink droplet ejecting device or inkjet printer for some reason, air bubbles will not be sucked into the ink chamber, and even if air bubbles are sucked, they will not be in the front chamber. Since the air bubbles in the lever are removed at least when the ink is discharged, it is also possible to substantially eliminate the air bubble suction accident, which was the biggest drawback along with clogging in on-demand type ink droplet ejecting devices. .

[Brief explanation of the drawing]

1 to 5 are sectional views and schematic diagrams for explaining each operation of an embodiment of the prevention method of the present invention, in which 1 is an ink droplet ejecting device, 5 is an ink chamber, and 7
is the first orifice, 8 is the front chamber, 10 is the second
orifice, 11 is an ink tank, 14 is an air pump, 17 is a valve device, 17 out is an atmosphere opening port, 20
21 represents a lid, 21 represents a gutter, and 23 represents a detection electrode.

Claims (1)

[Claims] 1: an ink chamber filled with ink; a pressure change means for applying a pressure change to the ink chamber; a first orifice that ejects ink droplets from the ink chamber by the pressure change of the pressure change means; An ink drop ejecting device comprising: a front chamber provided in front of the orifice; and a second orifice opened from the chamber through which ink droplets ejected from the first orifice pass; During non-printing operation of the ink droplet ejecting device, the second orifice is covered with a lid, and the first orifice connected to the front chamber is
Ink is supplied from the first orifice to the chamber provided in the front with an air vent provided at a higher position than the orifice opened, and the completion of filling of the ink is determined by a change in resistance value. A method for preventing clogging in an ink drop ejecting device, characterized in that the first orifice is covered with ink filled in a front chamber.