JPH0226590B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an ink jet recording apparatus, and more particularly to an ink droplet charging method in an ink jet recording apparatus capable of performing halftone recording.

Many types of inkjet recording devices have been known in the past. Among these, an ink-on-demand type inkjet recording device using an electroacoustic transducer has advantages such as a simple structure and no need to collect ink because all formed ink droplets are used for recording. Further, by changing the size of the ink droplet using an electric signal applied to the electroacoustic transducer, halftone recording can be performed.

2. Description of the Related Art Conventionally, an apparatus for performing halftone recording is known in which recording paper is wound around a drum and the drum is rotated to perform scanning. However, in such an apparatus, since it is necessary to wind the recording paper around a drum, it is desirable to use a method of scanning by deflecting ink droplets, which makes it easier to handle the recording paper. However, the conventionally known electrical deflection method has a problem in that the amount of deflection changes when the size of the ink droplet changes.

Furthermore, in such an ink-on-demand type inkjet device, in order to increase the dynamic range of halftones, if the size of the ink droplet is varied over a wide range, the fluctuation in flight speed becomes large.
There was a drawback that the positions where the ink droplets were shot onto the recording paper were disturbed. Furthermore, since the initial velocity of the ink droplets ejected from the nozzle is slower than in other methods, the position of the ink droplets hitting the recording paper tends to be disturbed, making it difficult to increase the distance between the recording paper and the nozzle or increase the recording speed. The problem was that it was difficult.

Furthermore, in order to increase the speed of recording, it is known to perform recording by arranging a plurality of inkjet nozzles, but it is desired to use multiple nozzles in this halftone recording apparatus as well.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned drawbacks and to provide an ink droplet charging method for an inkjet recording apparatus that can perform halftone recording by changing the size of the ink droplet while deflecting the ink droplet.

Another object of the present invention is to provide an ink droplet charging method for an inkjet recording apparatus capable of performing halftone recording in which the speed of an ink droplet can be constantly increased by an accelerating electric field even if the size of the ink droplet changes.

A further object of the present invention is to provide an ink droplet charging method for an inkjet recording apparatus that can perform halftone recording by using a common ink droplet charging electrode when multiple inkjet nozzles are used.

According to the present invention, ink droplets of a corresponding weight are ejected from an on-demand type ink jet head based on image information having weight information output at predetermined time intervals, and the ink droplets are placed ahead of the nozzle of the ink jet head. In the ink droplet charging method of an inkjet recording device, which has means for charging the ink droplet proportional to the weight using a charging electrode and accelerating the charged ink droplet by an electric field, the ink droplet is ejected according to the shape of the drive waveform. Using an on-demand type ink jet head whose weight is variable, a drive waveform is selected in advance from among the drive waveforms that ejects ink droplets of a desired weight with a constant flying speed within the range of the ink droplet weight to be used. Then, from among the drive waveforms secured above, a drive waveform corresponding to the weight information is selected and applied to the ink jet head, and a drive waveform is applied when ink droplets are ejected using all the drive waveforms secured above. The relationship between the time it takes for an ink droplet to break off from the nozzle and the weight of the ink droplet formed at that time is determined, a charging waveform that has a similar relationship between this time and the weight of the ink droplet is created, and it is synchronized with the leading edge of the drive waveform. An ink droplet charging method for an inkjet recording device is obtained, which is characterized in that the charging waveform is repeatedly applied to a charging electrode.

The present invention will be described in detail below with reference to the drawings.

FIG. 1 is a schematic diagram for explaining a first embodiment of an inkjet recording apparatus using the ink droplet charging method according to the present invention. This device includes an ink jet head 1 that can control the size of ink droplets formed by electrical signals, a voltage applying means 5 that outputs a waveform with a constant period, and a charging electrode 6 arranged in front of the nozzle 3. a piezo drive circuit 8 that outputs an inkjet head drive signal in accordance with the signal source 7 and the synchronization signal 13 from the voltage application means 5;
and a power source 1 to deflect the charged ink droplets 12.
It consists of a deflection electrode 9 to which a voltage from zero is applied and a recording medium 11 such as paper. The ink jet head shown here consists of a nozzle 3 and an ink chamber 4 filled with conductive ink supplied from an ink supply system (not shown), and a piezo vibrator 2 as an electroacoustic transducer. It is known as an example of the demand type. When forming an ink droplet, first, when an image signal specifying the weight of the ink droplet is given from the signal source 7 to the piezo drive circuit 8, the amplitude and pulse width are selected in synchronization with the synchronization signal 13 from the voltage application means 5. The generated electric signal is applied to the piezo vibrator 2 from the piezo drive circuit 8. Then, the piezo vibrator deforms in response to the pulse signal, increases the pressure in the ink chamber, and ejects ink droplets from the nozzle. The weight of the ink droplet formed here is generally controlled by changing the pulse width while keeping the pulse amplitude constant. However, when a wide range of ink droplet weights is used, the flying speed of the ink droplets may change depending on the weight of the ink droplets.

For example, when forming light ink droplets, sufficient acceleration may not be obtained simply by narrowing the pulse width. At this time, by narrowing the pulse width and increasing the pulse amplitude, the initial velocity can be increased without changing the weight of the ink droplet. However, in either case, the time required to form an ink drop varies depending on the electrical signal that gives the weight of the ink drop to be formed. On the other hand, a voltage of a constant waveform is applied to the charging electrode from the voltage applying means 5 so that each time each ink droplet is formed, the voltage value at the moment when each ink droplet is formed is proportional to the weight of the ink droplet formed at that time. is applied in synchronization with the electrical signal. Then, when an ink droplet is ejected from a nozzle, the ink droplet is charged according to the voltage value applied to the charging electrode, and if the above-mentioned charging method is used, even if the weight of the ink droplet changes, the amount of charge on the ink droplet remains constant. The charge is made such that the ratio between the weight and the weight is constant.

An example of the voltage waveform applied to the charging electrode 6 is shown in FIG. 2a. Further, FIG. 2b shows an example of the relationship between the time required from when an electric signal is applied to the piezoelectric vibrator to form an ink drop until the ink drop is cut off from the nozzle and the weight of the ink drop.

Here, the relationship shown in Figure 2b changes depending on the selection of the amplitude and pulse width of the electrical signal as described above, so it is necessary to apply the electrical signal to the piezo vibrator using all the electrical signals used in advance. For example, if the relationship shown in Figure 2b is found, a voltage waveform similar to this time and weight is created and the light end of the electrical signal is determined. A voltage having a waveform as shown in FIG. 2a is applied to the charging electrode 6 in synchronization with the charging electrode 6.

The ink droplets 12 charged in this manner are deflected by the deflection electrode 9 and are struck onto a recording medium 11 such as paper to perform recording. At this time, even if the weight of the ink droplet changes, since the ratio between the charge amount and the weight of the ink droplet is constant, the acceleration etc. received from the deflection electric field are the same, and the same amount of deflection can be obtained regardless of the size of the ink droplet. The amount of deflection is controlled by changing the voltage applied from the deflection voltage applying means 10 to the deflection electrode 9 in accordance with the amount of deflection.

At this time, the amount of deflection changes in proportion to the voltage applied to the deflection electrode.

Another example of the voltage waveform applied to the charging electrode is shown in Figure 3a.
Shown below. When applying such a sawtooth voltage waveform, a signal is input to the piezo vibrator, ink is ejected from the nozzle, and the number of ink droplets formed is It is effective in a range where the weight changes in a linear relationship. For example, as shown in FIG. 3b, the ink droplet can be used when a signal that changes the pulse width depending on the weight of the ink droplet is used as the signal applied to the piezo vibrator. When a sawtooth voltage is applied to the charging electrode as shown in _FIG . Assume that droplet formation is complete. At this time, a voltage increasing at a constant rate from to is applied to the charging electrode by the voltage applying means, and the amount of charge on the ink droplet is determined by the voltage v ₁ at t ₁ . When the size of the ink droplet is changed, for example, an electric signal is input to the piezoelectric vibrator at t ₂ , and when the formation of the ink droplet is completed at t ₃ , the ink droplet is charged by the voltage v ₂ at t ₃ . . At this time, as mentioned above, there is a linear relationship between the weight of the ink droplet and the ink droplet formation time, and the charging voltage increases at a constant rate with time, so the ratio of the charge amount and weight of the ink droplet remains constant. It can be charged like this.

Further, the phase of this sawtooth wave and the signal for forming an ink droplet is adjusted so that the ratio between the amount of charge charged on the ink droplet and the weight thereof is constant. Further, the sawtooth wave is not limited to the shape shown in this figure, and the initial value does not need to be OV.

Next, when the size of the ink droplet is changed discontinuously, the voltage waveform applied to the charging electrode should be changed to the sawtooth waveform shown in Fig. 3c instead of the sawtooth waveform shown in Fig. 3a. Depending on the size of the ink droplet, a step wave may be applied such that the voltage value at the completion of ink droplet formation is such that the ratio of the charge amount to the weight of the ink droplet is constant.

In this case, the voltage applied to the charging electrode remains constant for a predetermined period of time, so even though the weight of the ink droplet is the same when the ink droplet is formed, the time it takes for the ink to separate from the nozzle is This is effective because it can suppress fluctuations in the amount of charge on the ink droplets even in cases where the amount of charge on the ink droplets fluctuates slightly.

In the above explanation, an example has been shown in which a voltage having a waveform with a constant period is applied to the charging electrode 5, and an electric signal is outputted from the signal source 8 in synchronization with this signal to form an ink droplet. By performing such control, even if the ink jet head is a multi-nozzle head having a plurality of nozzles, the charging electrode for ink droplets can be made common to each nozzle. In other words, a voltage with a constant waveform is applied to this electrode, and an electric signal is applied to the piezo vibrator corresponding to each nozzle according to the size of the ink droplet. In this way, the present invention is directed toward the multiplication of ink jet heads.

As shown here, when ink droplets are ejected from the ink jet head, the ink droplets are slowed down by air resistance. In order to prevent this, it is known to apply a certain charge to the ink droplets and accelerate them using an electric field in the same direction as the flight of the ink droplets.
However, if the weight of the ink droplet changes, the velocity unevenness will become larger due to a change in acceleration or the like. However, by using the charging method according to the present invention, the acceleration that the ink droplet receives from the electric field can be made constant. Furthermore, by making the force received from the electric field larger than the resistance received from the air, it is possible to reduce speed unevenness due to fluctuations in air resistance even if the weight of the ink droplet is changed. Furthermore, even if the speed of the ink droplets ejected from the nozzle is uneven, the rate of speed unevenness can be reduced by accelerating the ink droplets. An embodiment of an inkjet recording apparatus using such an accelerating electric field is shown in FIG. This embodiment uses a means for applying an electric field parallel to the flight direction of the ink droplets, that is, an accelerating electrode 22 as shown in FIG. 4, instead of the deflection electric field of the first embodiment described above. . The formation and charging of ink droplets in this example are carried out in the first step shown in FIG.
This is carried out in the same manner as in the embodiment.

Therefore, the ratio between the charge amount and the weight of the ink droplet is constant, so even if the size of the ink droplet changes, the flying speed of the ink droplet after passing through the accelerating electrode does not change. This is an inkjet recording device that can achieve high-quality recording with little deviation in the position of ink droplets ejected onto the recording medium by accelerating with an accelerating electric field, and can also record intermediate tones by changing the size of the ink droplets. is obtained.

In the first and second embodiments of the inkjet recording device described above, the case where an electrical signal is inputted to the inkjet head in synchronization with the voltage signal applied to the charging electrode has been explained, but conversely, the case where the electrical signal is inputted to the inkjet head in synchronization with the voltage signal applied to the charging electrode is explained. Alternatively, a voltage with a constant waveform may be input to the charging electrode.

Furthermore, in each of the embodiments of the present invention, the formation of ink droplets has been described using an inkjet head as shown in FIGS. The present invention is not limited to the illustrated ink jet head, and can be applied to various types of ink jet heads.

[Brief explanation of drawings]

1 and 4 are schematic diagrams of an inkjet recording device for explaining first and second embodiments of the inkjet recording device using the charging method according to the present invention, and FIG. 2a shows the voltage applied to the charging electrode. An example of the voltage waveform, FIG. 2b is a diagram showing an example of the relationship between the time required for ink droplet formation and the weight of the ink droplet, and FIGS. 3a and c are other examples of the voltage waveform applied to the charging electrode. FIG. 3b is a diagram showing the electrical signals input to the inkjet head. In the figure, 1 is the inkjet head, 2
is a piezo vibrator, 3 is a nozzle, 4 is an ink chamber, 5
6 and 21 are charging electrodes; 7 is a signal source; 8 is a piezo drive circuit; 9 is a deflection electrode;
0 is a deflection voltage applying means, 11 is a recording medium, 12
is an ink droplet, 13 is a synchronization signal, 22 is an acceleration electrode,
23 indicates a power source.

Claims (1)

[Claims] 1 Based on image information having weight information output at predetermined time intervals, ink droplets of corresponding weight are ejected from an on-demand type ink jet head,
An ink droplet charging method for an inkjet recording device, comprising means for charging the ink droplet in proportion to the weight using a charging electrode disposed in front of the nozzle of the inkjet head, and accelerating the charged ink droplet by an electric field. In this method, an on-demand type ink jet head is used in which the weight of the ink droplets ejected is variable according to the shape of the drive waveform, and the jetting speed is constant within the range of the weight of the ink droplet to be used from the drive waveform and each desired one is selected in advance. A driving waveform for ejecting ink droplets of a certain weight is selected and secured, and a driving waveform corresponding to the weight information is selected from among the secured driving waveforms and applied to the ink jet head, and all of the secured ink droplets are When an ink droplet is ejected using a drive waveform, the relationship between the time from when the drive waveform is applied until the ink droplet is cut off from the nozzle and the weight of the ink droplet formed at that time is determined, and a similar relationship between this time and the weight of the ink droplet is determined. 1. An ink droplet charging method for an inkjet recording device, characterized in that a charging waveform is created, and the charging waveform is repeatedly applied to a charging electrode in synchronization with the leading edge of the driving waveform.