JPH0771850B2 - Inkjet recording device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ink jet recording apparatus for ejecting ink liquid by electrostatic force and air flow force to record characters, figures, images, etc. on a recording object. .

2. Description of the Related Art An inkjet recording apparatus utilizing electrostatic force and air flow force is known, for example, as disclosed in JP-A-62-39249. Hereinafter, a conventional inkjet recording apparatus will be described with reference to FIG.

In FIG. 4, 13 is a body member. A plurality of air discharge ports 1 are perforated in the insulating air nozzle plate 2,
An insulating ink nozzle plate 14 is arranged in parallel with the air nozzle plate 2, and a plurality of ink ejection ports 4 are formed in the ink nozzle plate 14 so as to face the air ejection port 1.

Around the ink ejection port 4, a convex portion 17 extending in the direction of the air ejection port 1 is provided. Between the adjacent convex portions 17,
A protrusion 5 is provided to stabilize the air flow. An air flow from the air supply source 3 flows into the air supply path 8, is made uniform in the air chamber 9 having an annular structure, and flows from around the air layer 7 generated by the air nozzle plate 2 and the ink nozzle plate 14, It is flowing out from the air outlet 1. Since this air flow changes rapidly near the air outlet 1,
A rapid change in the pressure gradient occurs in the space from the ink ejection port 4 to the air ejection port 1. On the other hand, the ink chamber 10 adjacent to the ink ejection port 4 communicates with the ink reservoir 11 via the ink supply path 6, and the ink in the ink reservoir 11 is adjusted by the air pressure from the air supply source 3 to adjust the pressure. The constant pressure adjusted by 16 is applied. This is because when the ink jet recording apparatus is not driven, the air pressure in the vicinity of the ink ejection port 4 and the ink pressure in the ink ejection port 4 or the ink chamber 10 are substantially equal and the meniscus of the ink in the vicinity of the ink ejection port 4 is kept stationary. To adjust so.

The bias power source 24 is connected to the common electrode 12 provided around the air ejection port 1, and the plural signal sources 22 are connected to the control electrode 15 provided around the ink chamber 10 of each ink ejection port 4. Since the ink is conductive, a potential difference of the sum of the bias voltage and the signal voltage is generated between the common electrode 12 and the ink held near the ink ejection port 4.
Due to the electrostatic force due to this potential difference, the meniscus of the ink generated near the ink ejection port 4 is extended toward the air ejection port 1. Furthermore, from the ink ejection port 4 to the air ejection port 1
Since a drastic change in the pressure gradient occurs in the space up to, when the meniscus of the ink generated in the vicinity of the ink ejection port 4 is stretched for a certain length or more, the ink meniscus is accelerated by the change in the pressure gradient to fly from the air ejection port 1. To do.

Problems to be Solved by the Invention With the conventional configuration as described above, the relative humidity is about 25 ° C at room temperature.
If the air is 60% or more, there is a problem that the ink ejection amount is reduced. The cause of the decrease in the ink ejection amount will be described. FIG. 5A shows how an electric field is generated when ink is ejected normally. The air nozzle plate 2 is made of photosensitive glass and has a dielectric constant of 6.54. On the other hand, since the permittivity of air is about 1, the strength of the electric field is greater in air. The electric field, which has a large electric field strength and particularly contributes to the extension of the ink meniscus 21, is represented by an electric line of force 18, and is located between the common electrode 12 and the ink meniscus 21 in the air ejection port 1. Occurs to pass through. Since the lines of electric force 18 and the ink ejection direction are substantially the same, an electric field is generated so that the ink meniscus 21 can be efficiently extended. FIG. 5B shows how an electric field is generated when the ink ejection amount is reduced. When the relative humidity is 60% or more, the water 20 is adsorbed on the wall surface of the air outlet 1. Since the specific resistance of water is 2.5 × 10 ⁷ Ωcm and is conductive, electricity is transmitted from the common electrode 12 and the water 20 has almost the same potential as the common electrode 12. The place where the electric field strength is large is represented by the line of electric force 19, and occurs between the ink meniscus 21 and the water 20 closer to the ink meniscus 21. In this case, since the ink ejection direction and the electric force line 19 do not coincide with each other and the force of the electric field is not concentrated, the meniscus 21 of the ink cannot be efficiently stretched, so that the ink ejection amount is reduced.

The reason why the water 20 is adsorbed is considered to be as follows. Considering the vicinity of the air ejection port 1 when air is flowing out, the pressure at the air layer 7 distant from the ink ejection port 4
When air 0.12 kg / cm ² is opened toward the atmosphere (0 kg / cm ² and set), the air reduces the pressure in the air discharge port 1,
The volume also expands at the same time. When the volume of air expands,
Since the heat of the wall surface of the air outlet 1 is absorbed, the air outlet 1
The temperature of the wall surface of the Since the temperature of the wall surface of the air discharge port 1 is lower than or equal to that of the flowing air, it can be said that the wall surface of the air discharge port 1 is in a state of easily adsorbing moisture in the air. The amount of water 20 to be adsorbed is greatly influenced by the amount of water in the air. The greater the amount of water, the more water 20 is adsorbed, and the amount of ink ejected begins to affect the relative humidity. It is from about 60% (at room temperature 25 ° C). The present invention solves the above problems of the prior art, and an object thereof is to prevent the ink ejection amount from changing due to the influence of humidity.

Means for Solving the Problems The present invention relates to an ink supply source for supplying ink, an air flow supply source for supplying an air flow, a first orifice plate having a plurality of air discharge ports, and the first orifice plate. A plurality of ink discharge ports provided facing the one orifice plate and arranged so as to form ink meniscuses coaxially with the plurality of air discharge ports, respectively. A second orifice plate having the same, a temperature raising means for raising the temperature of the first orifice plate, and a gap portion corresponding to each of the plurality of ink ejection ports and each of the plurality of air ejection ports. An air flow is sent from the plurality of air discharge ports while causing a sharp bend, and a pressure gradient is changed so as to reduce the pressure of air in a direction from the plurality of ink discharge ports to the plurality of air discharge ports. Potential difference between the first means for forming a space, the common electrode formed on the front surface of the first orifice plate, and the ink in each of the plurality of ink ejection ports, according to a signal. A space for changing the pressure gradient by the first means by extending the meniscus of the ink generated in the plurality of ink ejection ports by the attractive force due to the potential difference of the second means. The above-mentioned object is achieved by providing an inkjet recording device that applies an accelerating force of an air flow generated in the above to eject the ink in the plurality of ink ejection ports to the outside through the corresponding plurality of air ejection ports. Is.

Effect The present invention increases the temperature of the air nozzle plate so that moisture in the air is less likely to be adsorbed in the vicinity of the air ejection port, stabilizes the way an electric field is generated, and ejects the amount of ink due to the influence of humidity in the air. Is designed so that it does not change.

EXAMPLES Examples of the present invention will be described in detail below with reference to the drawings.

1 (a) and 1 (b) are a plan view, a sectional view and an electric wiring diagram of an ink jet recording head in a first embodiment of the present invention. A heater / common electrode 23 made of a long-shaped resistor is formed on the front surface of the air nozzle plate 2 so as to surround the periphery of the plurality of air outlets 1 arranged in a straight line. One end of each end of the heater / common electrode 23 is connected to the positive electrodes of the bias power supply 24 and the heater power supply 25, and the other end is connected to the negative electrode of the heater power supply 25. Heater and common electrode 23
Has a dual role of a common electrode for applying a bias voltage and a heater. Heater and common electrode 23 and each power supply
The connection with the lead wires from 24 and 25 was made with silver paste 26. Other configurations are similar to those of the conventional example shown in FIG. The heater / common electrode 23 was formed by depositing Cr on the front surface of the air nozzle plate 2 by 1000 Å by electron beam evaporation. A resistance of 30Ω was obtained by using a vapor deposition mask to form a long shape with a width of 2 mm and a length of 19 mm. The heater / common electrode 23 generates heat when the voltage of the heater power supply 25 is applied to both ends. The heat raises the temperature of the air nozzle 2. Room temperature 25 as an example
It was sufficient to apply a voltage of 3.5 V in order to raise the temperature of the air nozzle plate 2 to 32 ° C. while flowing air at the temperature of ℃.

FIG. 2 is a graph illustrating the relationship between the temperature of the air nozzle plate 2 and the ink ejection amount. 65% relative humidity at room temperature 25 ° C
In the air, the ink jet recording head is in an unstable state in which the ink ejection amount decreases and fluctuates. Therefore, when the temperature of the air nozzle plate 2 was gradually increased, the ink discharge amount was gradually increased, and when the temperature was raised to 32 ° C. or higher, the same stable ink discharge amount as when the relative humidity was low was obtained. This is because the water adsorbed in the vicinity of the air discharge port 1 disappears as the temperature of the air nozzle plate 2 rises, so that a potential is applied to the adsorbed water and the electric field generation becomes unstable, This is because it has been solved that the meniscus of the ink cannot be efficiently stretched because the force of is not concentrated. If the voltage applied to the heater / common electrode 23 is higher than 3.5V, for example 5V, and the temperature of the air nozzle plate 2 is set high with a margin, it is stable even when the relative humidity is 65% or more. The amount of ejected ink can be obtained. Further, even when the room temperature changes, if a constant amount of heat is applied to the air nozzle plate 2 from the heater / common electrode 23, the temperature of the air nozzle plate 2 can be raised with reference to the room temperature, so that there is no problem and stable. The amount of ejected ink can be obtained.

According to this embodiment, since the heater / common electrode 23 is provided so as to be adjacent to the air discharge port 1, the vicinity of the air discharge port 1 can be efficiently heated. In addition, heater and common electrode
Although Cr has been described as the material of 23, other metals or compounds may be used and it is not necessary to limit to Cr. Further, the shape is not limited to the longitudinal shape, but may be another shape for considering resistance and temperature distribution.

FIG. 3 is a front view and a sectional view of an ink jet recording head and a warm air fan according to another embodiment of the present invention. Warm air heater
The fan 30 causes air to flow through the fan 30, and hot air 29 warmed by the heater 28 is blown out from the air outlet 31. A hot air blower 30 is arranged so that the hot air 29 hits the air nozzle plate 2 of the ink jet recording head. Other configurations are similar to those of the conventional example shown in FIG. When the amount of ink ejected is unstable because the relative humidity is high (the amount of water in the air is large), the temperature of the air nozzle plate 2 is raised by the warm air 29 so that it is adsorbed in the vicinity of the air ejection port 1. Since the water disappears, an electric field is generated so that the meniscus of the ink can be efficiently stretched, and a stable ink ejection amount can be obtained without being affected by the humidity in the air.

In the above description, as the means for raising the temperature of the air nozzle plate 2, the method using the heater / common electrode 23 formed on the front surface of the air nozzle plate 2 and the method using the air heater 30 have been described. A resistor dedicated to the heater is formed on the front surface of the plate 2, a ceramic heater, an infrared lamp,
Other methods using a planar heater or the like covered with an insulator may be used.

As described above, according to the present invention, the air discharge outlet and the ink discharge outlet are arranged so as to face each other, and the electrostatic force acting on the ink held in the vicinity of the ink discharge outlet and the acceleration due to the air flow are provided. By raising the temperature of the air nozzle plate 2 of the ink jet recording apparatus that ejects ink by force, a stable ink ejection amount can be obtained without being affected by humidity, and the effect is great.

[Brief description of drawings]

1 (a) and 1 (b) are a plan view and a sectional view of an ink jet recording head according to a first embodiment of the present invention, and FIG.
FIG. 3 is a graph illustrating the relationship between the temperature of the air nozzle plate and the amount of ink ejected in the present invention, and FIGS. 3A and 3B show the ink jet recording head and the warm air fan in another embodiment of the present invention. A front view and a sectional view, FIG. 4 is a sectional view showing an example of a conventional ink jet recording apparatus, FIG.
FIG. 6B is a partially enlarged sectional view of the ink jet recording head of FIG. 1 ... Air discharge port, 2 ... Air nozzle plate, 4 ... Ink discharge port, 23 ... Common electrode for heater, 25 ... Heater power supply,
30 ... warm air blower.

Claims (4)

[Claims] 1. An ink supply source for supplying ink, an air flow supply source for supplying an air flow, a first orifice plate having a plurality of air discharge ports, and a first orifice plate facing the first orifice plate. And a second orifice plate having a plurality of ink ejection ports arranged facing the plurality of air ejection ports so that ink meniscuses are formed coaxially with the plurality of air ejection ports, respectively. A temperature raising means for raising the temperature of the first orifice plate, and an abrupt bend in the corresponding gap portion between each of the plurality of ink ejection ports and each of the plurality of air ejection ports. An air flow is sent out from the plurality of air discharge ports to form a space in which the pressure gradient changes so that the pressure of the air decreases in the direction from the plurality of ink discharge ports to the plurality of air discharge ports. means , Second means for selectively generating a potential difference according to a signal between the common electrode formed on the front surface of the first orifice plate and the ink in each of the plurality of ink ejection ports. Then, the meniscus of the ink generated in the plurality of ink ejection ports is extended by the attraction force due to the potential difference of the second means, and the acceleration force of the air flow generated in the space where the pressure gradient changes is applied by the first means. An ink jet recording apparatus which ejects the ink in the plurality of ink ejection openings to the outside through the corresponding plurality of air ejection openings. 2. The ink jet recording apparatus according to claim 1, wherein the temperature raising means is a resistor provided on the entire surface of the first orifice plate. 3. The ink jet recording apparatus according to claim 2, wherein the resistor provided on the entire surface of the first orifice plate is a common electrode. 4. The ink jet recording apparatus according to claim 1, wherein the temperature raising means is a hot air blower.